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THE INNERITATIDN DF THE jFLERENAL SYSTEM,
[Sajous.]
Thyroid a, Pituitary 'hady containing adreno-thyrold canter, gland, supplied by nerves e, f, derived frcm the pituitary, c, Adrenal nerves h derived ircni pituitary body via the medulla, cervical cord d,
splne-sympathetio branches and splanchnic
g, g, S.
The Internal Secretions and the
Principles of Medicine BY
CHARLES
E.
de M. SAJOUS, M.D., LL.D.
TIIK COIaLEGK OF PHYSICIANS AND OF THE AMERICAN PHILOSOPHICAL. Society; Professor of Therapeutics in the Temple University OF Philadelphia Formerly Professor in the MedicoChirurgical College and Clinical Lecturer in Jefferson Medical College, etc.
FkLLOW of
;
VOLUME
FIRST
WITH FORTY-FIVE ILLUSTRATIONS
FIFTH
EDITION
PHILADELPHIA F. A.
DAVIS COMPANY, 1912
Publishers
E
COPYRIGHT. 1903 COPYRIGHT. September. 1908 COPYRIGHT. September. 1909 COPYRIGHT. July, 1911 COPYRIGHT. April. 1912 BY A.
F.
[Reei«ered
DAVIS
COMPANY
at Stationera’ Hall.
London. En*.]
Philadelphia. Pa.. U. S. A.
Preaa of
F.
A.
Davis
Company
WELLCOME INSTITU UBRARY
1914-16 Cherry Street
Coll
Col.
No.
s
WelMOmec
1
DEDICATED TO THE MEMORY OF
BROWN-SEQUARD
^^lIEN the
first
edition of this
work appeared (1903), the
author hardly expected that Ids views, submitted only with tlie intention of opening new fields of investigation, would, within comparatively few years, be granted an enviable position in the He can only ascribe the large patronage that practical field. the work has received from the general j^rofession to the admittedly better results obtained in practice by the adoption of the
newer principles
has introduced.
it
Besides taking into account
—
—
important organs the ductless glands in every morbid process treated, the author has tried to emphasize the value of close analysis in the treatment of disease and to
the
functions
of
which attends the present unquestionably because such an effort
cultivate a distaste for the empiricism
use of remedies.
It is
meets a corresponding desire in the profession at large that so encouraging a response has been vouchsafed.
compared to former the scope of the work in the practical field. About 400
The fourth editions,
pages of the
edition extended greatly, as
first
volume, devoted heretofore to a study of the
functions of the adrenals
and
tliyroid,
were deemed no longer
necessary to introduce the author’s views, and were replaced by
number
which questions of paramount importance to the practitioner were considered. The fifth served mainly to bring the various subjects to date, and to amplify some of them the chapter on Organotherapy for a corresponding
of pages in
—
example. 'Pile first
two chapters are devoted to the connection of the
adrenals with the lethal trend of tions.
It
is
many
infections and intoxica-
shown therein that many diseases prove
fatal
through
the fact that inhibition or destruction of the functions of the
adrenals as a cause of death diseases
include
at present overlooked.
is
As the
which unquestionably implicate so seriously these organs praetically
all
febrile
intoxications
and
infections,
especially those of childhood, the
whole can hardly be sufficiently
importance of the subject as a emphasized. (v)
*
PREFACE TO THE FOURTH AND FIFTH EDITIONS.
VI
'I’lio
m*.\t
lliive
clia])tc‘is,
matter, cover a similar
also
eoinposetl
field, in so far as
entirely
of
new
the thyroid and jiara-
thyroids are concerned, besides analyzing from a
new standpoint
the diseases due to these organs: myxeedeina, cretinism, infanti-
These prominent syndromes are rarely met with, howas compared with the less clearly identified manifestations
lism, etc. ever,
of thyroparathyroid insufficiency, treated in the present work under the caption of liypothyroidia. Many disorders grouped under the terms “rheumatism,” “neurasthenia,” “autointo.xications,” “gout,” which thwart the physieians’ efforts, are but
manifestations of this condition.
This applies also
to a large
proportion of mentally defeetive, obese, and imperfectly developed subjeets,
all
of
whom,
particularly
benefited M-hcn their true condition
is
children,
may
be greatly
recognized.
The twelfth chapter has been devoted to organotherapy. The author is not of the opinion that “internal secretions” are as numerous in the body as is generally believed ; an effort is made, therefore, to identify those which merit this designation, and also the active factor in each of the organic products that have been found of value in various diseases. This also has for its
purpose to counteract, as
much
as possible, the prevailing
empirical use of these agents, several of which, intelligently emploj-ed, are of great therapeutic efficiency.
The balance
,
of the
work has been carefully
revised,
and
where needed, as in the eleventh chapter, considerably amplified. This applies also to the second volume, but only in so far as needed corrections were concerned. The author may add that he has also received encouragement from the fact that his views are steadily gaining ground, even in the experimental
field, as will
be seen by a perusal of
the work. C. E.
2043 Wal.vut Streett, PlIILADEI.PHIA. Fourth Edition, July
1,
1911.
Fifth Edition, April
1,
1912.
DE M. Sajous.
PHEFACE TO THE SECOND AND
TIIJ
UD EDITIONS.
(Containing a snminary of the author’s newer conceptions up to 1907.)
volume was delivered to the publishers in 1902, the second volume was only finished As the latter embodied researches carried on during in 190'i'. the interval of five years between the two volumes, it became
While
manuscrijit for the
first
necessary to correct what errors the
first
tlie
contained in the light
This feature, coupled with the large patron-
of these researches.
age the medical profession has granted the work, has imposed That very few corrections have the need af new editions.
proven necessary, either by reason of these investigations or of wliat justified criticisms the work has received, is shown by the list
(see page
of additions to our loiowledge
x
et
of this
seq.
The second volume may thus be
said
only to amplify the newer functions I pointed out in the
first
preface)
it
introduces.
volume in 1902 and
The
the publication of a
a prominent ican
to illustrate their
importance in practice.
present status of Medicine precludes any apology for
member
]\fedical
work such
as this.
of the Council of
Association,
wrote,
as a science;
At present it
it
of the
Amer-
“A (1908) promising to develop
only recently
generation ago therapeutics was an art, into a science.
Professor Sollmann,
Pharmacy
:
cannot be classed as an
can only be classed as a confusion.”
Osier’s public declaration^ that of the action of
art,
nor
Indeed,
drugs “we knew
though we “put them into bodies the action of which we know less,” sustained by Llewellys F. Barker’s estimate publittle”
lished about the logical action
same time,- “that drugs
of
unhnoivn physio-
cannot conscientiously be set to act upon bodily
tissue in disease in
which we are ignorant of deviations from
the nornialf’ involves the conclusion that our ignorance applies to disease as well as to therapeutics
—
in a word, to all that which endows us with the right to accept, with any degree of selfrespect, the confidence which suffering humanity places in us. It is not
my
purpose to take issue with these frank ex-
Osier: N. Y. Sun. Jan. 27, 1901. -Llewellys F. Barker: Bull. Johns Hopkins Hosp., July-Aug.,
1
1900.
(vii)
Vlll
I’UEFACE TO THE SECOND AND THIRD EDITIONS.
2)i'6Ssions
of o|)iiuoii.
Iii
were
fact,
I
do
to
so,
would con-
I
ceal similar coneliisions reached nearly
twenty years ago, when, as editor of the “Annual of the Universal ^ledical Sciences,” it
became
many
my
lot
associates,
to
with the valued collaboration of
collate,
the multitude of
data,
and experi-
clinical
which were accumulating from year to year. Nor do they conflict with the prevailing estimate of the therapeu-
mental,
]\Iedicinc among the best-informed medical men Skoda’s dictum of several years’ standing, “that we can diagnose disease, describe it, and get a grasp of it, but we
worth of
tic
abroad.
dare not expect by any means to cure it,” has drifted along, on the ripples of time, until, hardly two years ago (1907), the president of a prominent British society. Dr. A.
found
II.
Brampton,®
opportune to declare that “if any daring member has
it
introduced a subject bearing on medical treatment,
it
has been
with an apologetic air and liumhle mien, well knowing that
remarks had any reference
his
to the utility of
if
drugs in the
treatment of disease they would be subjected to good-humored
and received by those ful with amused incredulity.” “Internal Secretions” was first banter,
me, at
least,
sitting in the seat of the scorn-
^ly aim now, as projected,
is
it
was when
to indicate
what
to
appears to be the main cause of the deplorable
state of practical Medicine,
and
if
possible to eliminate
it.
ago, I was brought face to face with material we term the “Medical heterogeneous of mass the Sciences,” and with the yearly crop of contradictory theories
When, twenty years
upon each disease, mode of treatment, etc., I soon realized that some gigantic flaw could alone account for so great a confusion. In the preface of the 1888 issue, I had stated that the “Annual” was intended “to become a helpmate to the jiractitioner in his efforts
to
correlating
relieve
suffering,
and
to
assist
the
investigator
by
thus enabling him the better to compare.” comparison was indulged in by others I can-
facts,
Whether much
not say, but the fact remains that, as far as my own position for in the matter was concerned, I began then and there to seek
must frankly confess that its identity was not difficult to find, namely: the invalidity of PhysiNever, when it came to tracing a pathological condition, ologv'.
the flaw referred
>
A. H.
Brampton:
to.
I
Lancet, Jan.
19,
1907.
PREFACE TO THE SECOND AND THIRD EDITIONS. tlic effect
of a remedy, the nature of a
many jihenomena which
of the
mount importance
ix
symptom, or any, in
fact,
to us jjractitioners are of para-
in diagnosis or therapeutics,
was
it
possible
to trace to its source the chain of events through which a normal function had more or less suddenly become abnormal.
Invariably
was.
found
it
altogether to
failed
that
the
either
physiologists
had
discern the nature of that function, or,
an attempt had been made by them to explain it, that it was laden with so many inconsistent and obviously mutually contradictory conclusions that although perhaps quite scientific if
—
—
their eyes it was more misleading than heljjful in the explanation of the morbid condition analyzed. To illustrate these statements, I will submit a few of the
in
more
salient deficiencies referred to.
The
process of respira-
which includes pulmonary respiration and oxj'genation of the blood and tissues, at once asserts itself as of capital importion,
tance, since process,
it
and
urged that
involves the functions of all organs, the vital
also every this
morbid
process.
In January, 1903, I
function as taught by physiologists failed to
satisfy our needs,
and suggested new paths for research.
years later. Professor Chas.
E.
Two
Barnes, of the botanical
de-
partment of the University of Chicago,* wrote: “I found it needful to examine the recent literature of respiration in animals, the aspect of the general subject rvith which I felt myself I found to my great surprise, that animal have eoncerned themselves very little with the essential problems of respiration.” Then, naming our bestknoivn text-books on physiology, he added: “I found no treatment whatever, indeed, no mention whatever, of the real problems of respiration, that is, of what is happening in the tissues,
least
familiar.
physiologists
tlie
The
process of which these external late Sir
phenomena
are the sign.”
Michael Foster® also closed a study on metabolism
in the last edition of his text-book with the statement that, after all, it “consists mostly of guesses and gaps.” Even the
apparently simple process through which the blood acquires its oxygen from the air in the pulmonary alveoli is at present
unlcnown to physiologists, their gasometric experiments being. '*
=
C. R.
Sir
Barnes: Science, Feb. 17. 1905. Michael Foster: cited by W. G. Little: Liverpool Med.-Chir. Jour., Jan.,
1905.
PUEFACK TO THE SECONIJ AND TIIIUO EDITIONS.
i
by Pembrey,® “very discordant” and inadequate to “the absorption of oxygen by the lungs.”
as stated ei-plaiii
If the full
their
appalling
meaning
of these dcliciencies is apprehended,
consequences will appear.
The pulmonary
the main barriers to infection; their surface is the seat of multiplication of the pneumococcus, while their walls afford a nidus for the tubercle bacillus. It is here, therefore, that the initial lesions of the two great destroyers of air-cells are
mankind, jmeumonia and tuberculosis, are formed. Now, adequate knowledge of the processes with which oxygen is concerned precisely in this location, would be a boon indeed: it would enable us probably to discern just how Nature defends the body against infection.
As
to the
morbid processes con-
nected with tissue respiration, I pointed out in the first volume,^ two years before Beard suggested its use as a remedial agent, that trypsin was the direct destructive agent in another dread disease, cancer. tissue-metabolism.
If
is now known to take part in we had something better than the
Trypsin
“guesses and gaps” referred to at our disposal to study this
next greatest foe of humanity, I venture to suggest that
would soon be conquered. Another great function
is
nutrition.
Our
first
interpret intelligently gastro-intestinal infections,
is
it
need to a
clear
understanding of ferments. A most aide physiologist, Benjamin Moore,® wrote recently: “Little is known regarding the chemical nature of enzymes, because all attempts to isolate them in a state of purity have hitherto failed.” Another au“The process through which thority, Halliburton,® also writes: the digested food-stuffs are absorbed from the alimentary canal is
quite as obscure.”
Thus, HowelB® writes:
that controls absorption resides
....
“The energy
in the wall of the intes-
presumably in the epithelial cells, and constitutes a speAccordcial form of imbibition wbicb is not yet understood.” ing to Bcddard,'^ “we know nothing of the path taken by the products of proteid and carbohydrate digestion.” HowelB* also
tine,
•
Pembrey
r
Sajous
8
» 10 11
1*
;
Cf,
:
Schafer’s “T. B. of Phy.siol.,’’ vol. vol. i., pp. 609 to 666 iiicl., i908.
i,
p. 776, 1898.
Moore : Hill’s “ Recent Advances in Phy.aiol., etc.,” p. 117, 1906. Halliburton ; “Biochemistry of Muscle and Nerve,” p. 30, 1904. Howell “T. B. of Physiol..” p. 713, 1905. Bcddard : Hill’s “Recent Advances in Physiol., etc.,” p. 043, 1906. 716, 1905. Howell: Loc. :
;
PREFACE TO THE SECOND AND THIRD EDITIONS. in which proteid
“The form
says:
is
XI
absorbed remains
....
a mystery.” Again, if, as text-books on physiology teach, the food-stufEs, duly prepared, were taken up at all by the blood, they should be found in the latter. But, as stated by Mendel, “Beyond the intestinal wall, in the blood and lymph-stream, the cleavage products seem, for the most part, to be missing.” Finally, once in the blood, the fluid proteids should be readily diffusible to penetrate freely to the tissue-cell. HowelP’* states:
“The
proteids of the blood, which are supposed to be so im-
portant for the nutrition of the tissues, are practically indiffusIt is difficult to explain their passage ible, so far as we know.
from the blood through the capillary walls into the lymph.” The problem of nutrition is evidently no more solved by physiologists than those of respiration and tissue metabolism.
The consequences
to
us are
quite
as
deplorable.
Asiatic
and kindred disorders are closely related with all intestinal functions, and in absorption How can we possibly lies the key-note to general infection. conception of all these dread diseases with such obtain a clear cholera, tyjihoid, infantile diarrhoea,
a foundation as physiology affords us?
The is
third great question
incited in an organ.
years ago, this
is
is
the
manner
in which function
As shown by Claude Bernard, over
fifty
due to dilation of the arteries of that organ
more blood passing through it, it functionates. Notwithstanding considerable work done upon the problem ever since, the manner in which this function is carried out is quite unknown. Naturally, to admit more blood into an organ, the nutrient arteries must be dilated. Now, in his summary of vasomotor actions,. Foster,^-''* for instance, says, referring to the
of dilator nerves in muscles:
“There
is
presence
no adequate evidence
that these vasodilator fibers serve as channels for tonic dilating
impulses or influences.”
While Landois,'® in the
last edition
of his text-book, holds that “although a center for vasodilator
or vessel-relaxing nerves has not yet been demonstrated, the existence of such a center in the medulla may nevertheless be suspected/’ J. G.
Curtis'’'^ states
that “it
is
not
known whether
13
Mendel; Med. News, May Howell: JjOC. cIC, 7 >. 88 fi.
’3
Foster: “T. B. of Physiol. sixth American edition, n. 229, 1805. I.andois ‘'T. B. of Physiol.,” tenth edition, ji. 771. 190.5. J. G. Curtis; “ Ainer. T. B. of hysiol.," vol i, p. 199, 1900
1“
”
20, 1905.
:
I
PREFACE TO THE SECOND AND THIRD EDITIONS.
All
a vasodilator center of the question
is
The
iiresent in the bulb.”
actual state
aptly suniiuarized hy H. C. Chapman,'®
when “Though numerous e.xplanations have been otlered of the manner in which the vasodilator nerves aet, it must be admitted that none of them are satisfactory, and that it is not yet understood how this stimulation causes dilatation of the is
he says:
blood-vessels.”
Now,
the bearing of this physiological process ujion patho-
genesis and therapeutics total
number
since all
may
be said to be limited only by the
of diseases to which the
human frame
disorders are functional or organic, and
diseases impair function at a given time.
suggests
A
all
organic
possible exception
namely, the nervous system.
itself,
exposed,
is
Ilut here, again,
the clcus ex machina of the function as a whole, the nerve-
impulse, has remained hidden.
As Landois"’
says, “the nature
of the physiological nerve-stimulus in the normal body
known.”
among
This
accounts
for
the
prevailing
is
not
discouragement
the devotees of a great specialty, neurology, as expressed
in the recent statement of a very diligent worker in that line,
Joseph
Collins,-® “that
we know very and the
etiology, pathogenesis,
of nervous diseases, organic
little
more concerning the
clinical display of the majority
and functional, than we did twenty
years ago.”
These are hut a few of the evident shortcomings of PhysiI ology; others will be referred to in the body of the work. wish to state, however, that their enumeration
by a spirit of criticism ciency
is
;
is
not inspired
they are mentioned because each
defi-
subjected to a searching inquiry in the second volume
with a view to
its
elimination
:
Indeed, any one
ined physiological loro as closely as
I
who has exam-
have, cannot but admire
the enormous and patient lalior that physiologists have devoted to the solution of the
tions of the
multitude of problems which the funcinvolve, including the many un-
human organism
must now, after writing the second volume, em])hasizo a feature which T merely sug-
solved ones to which
gested in the
many
first
1
refer.
volume,
viz.,
functions referred to
is
But
T
that their failure to ex]ilain the
due to the fact that they have
H. C. Chapman: ‘‘Human Physiology,” second edition, p. '•Landois: Lor. cit., p. fi.91. Joseph Collins: Monthly Cyclo. of Pract. Med., Feb., 1905.
G92, ,
1S99.
PREFACE TO THE SECOND AND THIRD EDITIONS.
Xlll
have overlooked the cardinal functions of the organs to which I pituitthe thyroid, the given special attention: the adrenals, ary body and the leucocytes. text will show, various branches of biology have been studied, but many of the facts which have served to
As the
from Professor Pawlow, of
elucidate function were obtained
great physiologist.
A
clinical medicine. St.
Petersburg, wrote
a few years ago,-^ after stating that physicians had pointed out the existence of gastric secretory nerves a question which,
—
I
may
add, has been greatly elucidated, thanks to his “Physiologists, on the other hand, had
labors:
own
fruitlessly en-
deavored for decades to arrive at definite results upon this question. This is a striking, hut by no means isolated, instance where the physician gives a more certain verdict concerning physiological processes than the physiologist himself;
nor
is it
phenomena is nothindeed strange. The ing hut an endless series of the most different and unusual combinations of physiological occurrences which never make world of pathological
their appearance in the of physiological
normal course
It
of life.
experiments which Nature and
is
a series
life institute,
often with such an interlinking of events as could never enter into the
mind
sources at our
and which could by means of the technical re-
of the present-day physiologist,
scarcely he called into existence
command.
Clinical observation will consequently
always remain a rich mine of physiological facts.”
There are precedents, therefore, upon which a legitimate belief may be based that the conclusions I have reached are sound. They afford,
moreover, a clear explanation of the inability of physi-
ologists to discern the functions
my
researches have led
they are partly hidden in a
discover:
field
me
could not legitimately be expected to scrutinize, owing to
In this connection,
vastness.
it
is
to
that physiologists its
mainly, therefore, as a
contribution of pathological biology to normal biology, of which physiology is a subdivision, that the two volumes of “Internal
Secretions” are offered.
Among the more important features which the views I advance therein appear to me to point out for the first time Pawlow
:
“The Work of tho Digeslive Glands,” Thompson’s
transl., p. 4G, 1902.
;;;
; ;
;
;
—
;
—
——
—
PREFACE TO THE SECOND AND THIRD EDITIONS.
XIV
(as far as the literature
and the experimental and
within niy reach have enabled
As bearing
direetly
me
clinical facts
to judge) are the following:
upon Biology:
The main function
of the adrenals, viz., to supply an internal secretion which absorbs the oxygen of the air to carry it to the tissues; and, as a result of this fact: 2. Pulmonary respiration, and 3. Tissue respiration; 4. The identity of the albuminous moiety of the litEmoglobin molecule, viz., the oxygenized adrenal secretion; 5. The identity of the oxidase of the blood, i.e., the oxygenized adrenal secretion referred to (after the thirteenth chapter) as “adren1.
oxidase” 6. The identity of the red corpuscles as storage-cells for adrenoxidase and as purveyors of this body to the tissues; 7. The general composition of ferments; 8. That the adrenal principle is the one ferment which endows all other body-ferments with their properties as such; 9. The identity of “secretin” as adrenoxidase; 10. The identity of “enterokinase” as adrenoxidase plus nucleo-
proteid 11. That the granulations of the leucocytes ser\-e to build our tissues and to nourish them 12. That the substances out of which the leucocytes form their granulations (anabolism) are the proteids and carbohydrates ingested by them in the intestinal canal, its epithelium and villi, and in the blood; And, in virtue of these facts; 13. The process of absorption, and 14. The process of general nutrition; 15. That it is the function of leueoc3'tes to convert the. constituents of the ingested proteids into living proteids; If). That the granulations thej’ supply to the tissue-cells are living substance 17. That the principle which endows the constituents of proteids with life in the leucocj'tes is the adrenal active principle; 18. That the adrenal principle is the d.vnamic element in the vital process 19. That the granulations of leucocj-tes once in the tissue-cells live temporarily therein and are, when worn, broken down by ferments (catabolism), and voided by the cellular vacuoles into the pericellular Ij-mph-spaces And, in virtue of the foregoing conclusions: 20. The process of metabolism 21. That all the ferments and carbohvdrates found in the tissues and other immobile cells are brought to them by leucocytes and are derived from the alimentary sj’stem, especially the pancreas (trypsin)
and
liver
(glj-cogen)
;
That a portion of the pancreatic ferments forms an internal secretion which passes to the splenic vein and thence into the portal 22.
system 23. That the splenic internal secretion (probably nucleo-proteid) also passes out into the splenic vein and thence into the portal sj'stem; 24. That on reaching the portal system from the alimentary canal, secrethe leucocytes absorb the pancreatic ferments and splenic infernal tissue-cells and tion (probably nucleo-proteid) which they supply to the with which they carry on their intrinsic functions;
;
;
;
;
— —— ——
;
PREFACE TO THE SECOND AND THIRD EDITIONS.
XV
tissues, is com25. That the nervous system, in keeping with other leucocyte-granulaby nourished and developed likewise posed of cells tions, and traversed by the oxygen-laden adrenoxidase the ground substance and Nissl granules of nerve-cell2(1.
That
bodies and the myelin of their axis-cylinders or nerves are to the nervecell what the cytoplasm is to other tissue-cells; • 27. That the neuro-fibrils, including those oi the axis-cylinders, are nerve-capillaries through which the nerve-cells are supplied with oxygenladen adreno.xidase 28. That these neuro-fibrils receive their adrenoxidase-laden plasma from the general circulation through the intermediary of the neuroglia fibers (also capillaries) and the neuroglia-cells which regulate the volume of plasma admitted into the neuroglia fibers; And, in virtue of the last four conclusions: 29. The circulation of the nervous system; 30. That the myelin of nerves is not a mere insulating material or sheath, but a compound rich in phosphorus which, when in contact with the oxygen-laden adrenoxidase circulating through them, generates
nerve-energy 31. That the ground-substance, the Nissl gi-anules and the myelin in the cell-bodies of neurons and their dendrites, are also phosphorusladen compounds which, when in contact with the adrenoxidase circu-
lating through them, generate nerve-energy And, in virtue of the last two conclusions: 32. The source and nature of the nerve-impulse; 33. That the pituitary body is the general and governing center of the spinal system, which includes the gray substance of the base of the brain, pons, bulb and spinal cord, and the nerves derived from any of these structures, cranial or spinal, though subsidiary centers are also present in the bulb and spinal cord; 34. That the pituitary body is the governing center of all vegetative functions, i.e., the somatic brain; And, in virtue of these two conclusions: 35. The identity of the pituitary body as the most important of all organs concerned with the vital functions of invertebrates and vertebrates, including man 36. That the brain (as differentiated from the somatic brain) is the organ of mental processes and not the governing organ of motor functions; though capable, through the voluntary impulses it transmits to the spinal system, of having its mandates carried out; And, in virtue of these two conclusions: 37. The identity of the brain (as differentiated from the somatic brain) as solely the organ of Mind. 38. That neither the anterior nor the posterior pituitary body is a secreting gland; 39. That the anterior pituitary body is a lymphoid organ which, through the intermediary of a center located in the posterior pituitary body and a nerve-path in the spinal system, the upper dorsal sj'mpathetic ganglia and the splanchnic nerves, governs the functional activity of the adrenals; And, in virtue of this conclusion: 40. That the anterior pituitary body governs, through the posterior pituitary body, all tbe oxidation processes of the body; 41. That the center in the posterior pituitary body through which the anterior pituitary body governs the adrenals also controls the functional activity of the thyroid gland, and thus constitutes the “adrenothyroid” center; 42. That the pituitary body, the adrenals and the thyroid gland (including the parathyroids) are thus functionally united, forming the ^
“adrenal system;”
;
—
—
;
PREFACE TO THE SECOND AND THIRD EDITIONS.
x\a
43. That the posterior pituitary body is the seat of the highly specialized centers wliich govern all tlie vegetative or somatic functions of the body, and of each organ individually; 44. That tlie posterior pituitary body receives all the sensory impressions belonging to the field of common sensibility: pain, touch, muscular sense, etc., initiated in any organ, including the mucous membranes, skin and brain 45. That owing to this fact, the posterior pituitary body is the
sensorium traumatic
commune upon which
—concussions,
functions being conditions;
tlie
etc.,
react,
—
emotions, shocks psycliical or the resulting impairment of its
all
cause of the morbid phenomena observed under such
46. That the sj'mpathetic system is also governed by a center, and 47. Tliat the sympathetic center is likewise located in the posterior pituitary body and constitutes one of the most sensitive of its
centers 48.
That
it
is
the function of the sjunpathetic center and of the
sympathetic system to govern the caliber of all arterioles, and to regulate. through the spiral muscular coat of these vessels, the volume of blood admitted into the capillaries of any organ, including those of the brain and nervous system; 49. That the vasomotor center governs the caliber of the larger vessels only, i.e., of all vessels that are larger than the arterioles; 50. That active vasodilation exercised through vasodilator nerves is limited to the arterioles; 51. That dilation of an arteriole is due to constriction by the terminal fibers of a cranial nerve (the vagus, for example) of the vasa
vasorum which supply its walls with adrenoxidase-laden plasma, thus causing ischaemia and relaxation of its muscular coat; 52. That while this process, “stricto-.dilation,” serves to admit an excess of blood into an organ when the functional activity of the latter is to be increased, the sympathetic fibers, when the organ’s functions are to cease, restore the arterioles to their normal caliber; And, in virtue of the facts embodied in the last seven conclusions: 53.
The mechanisms
As bearing
of vasodilation
directly
and function.
upon Immunity:
54. That the sensory organ in the partition between the two lobes pituitiiry body is morphologically the homologue of the “test-
of the
organ” or “osphradium” of mollusks and other Invertebrates, which has for its purpose to protect the animal against noxious materials that may be present in the water admitted into its organism; 55. That all \’ertebrates, including man, are protected, as are Invertebrates, against noxious materials that may be present in the blood (a chemical homologue of sea-water), their test-organ, a sensory structure, being sensitive to certain poisons as the olfactory area, which it resembles histologically, is to odors; 56. That the test-organ of Vertebrates, including man, reacts under the inlluence of any poison brought to it by the blood or its leucocytes (phagocytes) capable of exciting it, by increasing, through the adreno-thyroid center, which it governs, the functional activity of the
adrenals and of the thyroid and parathyroids; 57. That by increasing the functions of the adrenals it enhances the bacteriolytic and antitoxic powers of the blood and its phagocytes; 58. That by increasing the functional activity of the thyroid and parathyroids it increases, through their secretions, the sensitiveness of all cells, including bacteria, and their vulnerability to phagocytes, inasmuch as
—
—
;
PREFACE TO THE SECOND AND THIRD EDITIONS.
XVII
parathyroids jointly form 59. Tlie secretions of the tliyroid and opsonin and agglutinin of tlie blood; And, in virtue of the last six eonclusions:— pituitary body, the GO That the adreual system, composed of the immunizing mechanadrenals and the thyroid apparatus, constitutes the ism of the body; and, furthermore, , for its purpose to 61. That inasmuch as the adrenal system has functional activthe enhancing is by it disease, protect the body against disease; ity of the adrenal system that we can overcome in the blood C2. That the adrenal system causes the appearance, (qualitative) chema “auto-antitoxin,” of excess an of phagocj’tes, and ical honiologue of diphtheria antitoxin and other antitoxins; is G3. That this “auto-antitoxin” (as well as all other antitoxins) composed of the internal secretions of the adrenals (adrenoxidase: Eliriich’s amboceptor), of the pancreas (trypsin: Ehrlich’s complement), and of the thyroid and of the spleen and leucocytes (nucleo-proteid) parathyroids (thyroidase; Wright’s opsonins) 64. That it is to the excess of auto-antitoxin that the increased bacteriolytic arid antitoxic properties of the blood and pliagocytes (the true vis mcdicatrix naiurw) are due. tlie
,
,
;
As bearing
directly
upon Pharmacodynamics:
65. That rational Therapeutics, in so far as the cure of pathogenic processes based on toxemias is concerned, should include measures wliich promote the formation of auto-antitoxin in the blood and
phagocytes 66. Tliat we have drugs, of which thyroid extract, mercury, and iodine are types, which provoke energetically the formation of autoantitoxin 67. That the production of an excess of auto-antitoxin in the blood, under the inlluence of bacterial toxins or endotoxins, or of any poison capable of exciting the test-organ (and through it the adrenal system) sulliciently, is the phenomenon known as “fever,” and that the “thermogenic” or “heat” center is thus located in the pituitary body; And, in virtue of this conclusion: 68. The nature of fever and its mode of production; 69. That we can by means of agents which stimulate concomitantly the test-organ and the vasomotor and sympathetic centers or any two of these centers, enhance metabolism and nutrition and the production of auto-antitoxin, as cxemplilied by belladonna, stryebnine, coca, quinia and other drugs; 70. That we can supply the body with the constituents which its blood and tissues lack and that these agents are adjusted to the needs of each organ by the leucocytes, as exemplified by iron and phosphorus; 71. That all drugs are taken up by leucocytes in the intestinal canal and blood and transported by them to all parts of the body; 72. That the sympathetic center in the posterior pituitary body is the sleep center; 7.3. That the sympathetic center provokes sleep by lowering the functional activity of the anterior pituitary body and of the adrenal system, and causes thereby a general relaxation of all arteries, accumulation of blood in tbe splanchnic area, and ischasmia of the cerebrospinal system; ;
74. That drugs of which opium is the type, produce sleep by stimulating the .sympathetic center; 75. That drugs of the type of chloral, the bromides, etc., produce sleep by depre.ssing the vasoTuotor center and causing accumulation of blood in the splanchnic area and isehiemia of the cerebro-spinal
system
^
;
—
;
—
—
;
PREFACE TO THE SECOND AND THIRD EDITIONS.
XVI 11
And,
in \nrtue of the four last conclusions:
The manner in which sleep is provoked; 77. That anajsthetics of which chloroform and etlier are types, produce sleep and ana;sthesia by e.xciting powerfully the vasomotor center, causing thereby general vasoconstriction followed by hypenemia of all capillaries, including those of the ccrebro-spinal system, and ven76.
osity of their arterial blood; 78. That anajsthetics of which nitrous o.vide is a type, produce sleep and aniesthe.sia by replacing the o.xygen of the air and producing venosity of the blood in the capillaries of the cerebro-spinal system and
other organs; 79. That ])ain is due to hyperaimia of the sensory-nerve terminals, of the nervi nervorum, etc., and that any agent which indirectly or directly causes diminution of this hyperaimia counteracts pain; An.d, in virtue of this conclusion: 80. The nature and mode of production of pain 81. That analgesics of the type of opium counteract pain by stimulating the sympathetic center, and by thus causing the dilated arterioles which supply the painful area to resume their normal caliber; 82. That analgesics of the type of antipyrin, acetanilid, etc., counteract pain in the same way, but, being more violent in their action, are apt to cause hyperconstriction of the arterioles and cyanosis; 8;i. That drugs of the type of amyl nitrite, nitroglycerin, etc., produce dilation of the arterioles by inhibiting the functional activity of the sympathetic center; 84. That drugs of the type of veratrum viride, the bromides, etc., lower the vascular pressure by inhibiting the functional activity of tho vasomotor center; 85. That alcohol is a fictitious stimulant and in reality a depressant, owing to the fact that it deo.\idizes the plasmatic adreno.xidase; 86. That the mineral salts fulfill so important a role in the preservation of the osmotic properties of the body fluids and their alkalinity, that their replacement in all diseases in which they are actively reduced is an essential feature of the curative procecs; 87. That purgatives produce their beneficial elTects by causing either rellexly or by centric action, according to the purgative u.sed, an increase of bacteriolytic and antito.xie auto-antitoxin in the intestinal canal 88. That all emetics produce their elTccts by provoking irritation of the giistric mucosa: the local emetics (mustard, zinc sulphate, etc.) by irritating it directly; the general emetics (apomorphine, tartar emetic, etc.) by depressing markedly the vasomotor and sympathetic centers and thus cau.sing dilation of the arterioles and hyperajmia of the gastric glandular elements; 89. That dia])horetics act similarly, the sweat glands (as well as all other glands) being rendered hj'pera;mic and overactive.
Bearing directly upon Pathogenesis and Therapeutics
:
90. That the vulnerability of the organism to infection is inversely proportional to the efficiency of the adrenal system, the relative amount of auto-antitoxin in the pulmonary and intestinal secretions, and tho bacteriolj'tie activity of the phagocytes; 91. That the diseases which are most fatal to mankind: cancer, tuberculosis, pneumonia, Asiatic cholera, bubonic plagiie, etc., are due to agencies, endogenous or exogenous, which interfere with, or paralyze, the functions of tho test-organ and through it the adrenal system; 92. Tliat all these diseases can be treated successfully, when s(wn late, by means of remedies which excite with adequate activity too not
—
PREFACE TO THE SECOND AND THIRD EDITIONS.
XIX
the test-organ, and provoke through it an accumulation of auto-antito-xin and tliyroidase (opsonin) in the blood; tetany, tetanus, epilepsy, puer93. That the convulsive diseases: peral eclampsia and rabies, are all due to the accumulation of to.xic waste-products in the blood; 94. That all these convulsive diseases can be arrested by measures which prevent the accumulation of toxic wastes in the blood and which provided organic increase the proportion of auto-antitoxin in the latter, lesions in the cortex (gliosis) have not been given time to develop; 95. Tliat all the diseases grouped under “gouty diathesis:” gout, migraine, neuralgia, sciatica, etc., are due to hypoactivity of the testorgans and the adrenal system; And, in virtue of these six conclusions: 96. Tliat the most fatal and distressing diseases of mankind have not been mastered because the cardinal role of the adrenal system in their pathogenesis, prevention and cure, has been overlooked.
—
As previously
stated, this list includes only the
portant I’unetions that
my
researches
inves-
analysis
tigations in the laboratoiy, clinical observations,
of
fund of knowledge available in literature
the vast
brought to
more im-
—including personal and —have
Were
light.
enumerated, including those intro-
all
duced in the departments of “PharmacodjTiamies” and “Pathogenesis
and Therapeutics” (where they are designated by asterdrug and disease studied), they would aggregate
isks in each
several hundred.
This fact
trate the far-reaching
is
only referred to in order to
illus-
importance of the functions of -the internal
secretions in all processes, normal, morbid, or protective,
the large
The
number
of gaps they
and
fill.
—
which I have been led those submitted in the second volume are not offered as mere theories, but as solutions carefully worked out from the abundant matefinal conclusions to
—
my
disposal. My labors as editor of the “Annual of the Universal Medical Sciences” and the “Cyclopaedia of Practical rial at
having shown tliat it was to the habit of theorizing with a few facts as foundation into which investigators, and i\Iedicine”
particularly laboratory workers, have fallen, that the confusion
which characterizes the Medicine of our day was due, the lowing working plan was adopted The literature of each :
ject,
folsuli-
my own
collected,
ex]ierimental and clinical observations, etc., were sulidivided and filed. When a given subject was
taken up, each paper available was analyzed and the sound experimental or clinical facts or observations were noted and
arianged in
scries.
In physiological questions, the teachings of zoology and cytology were added. All
physiological botany,
— P1U5KACE TO TUB SECOND AND THIRD EDITIONS.
XX
data (amounting to several luindrcds in some instances)
tliese
—
were treated as factors in the search of a solution the solution submitted at the cud of each section, in italics in the first seventeen chapters, and thereafter in large type.
The
reached in each instance was submitted to a rigid viz.,
final solution test,
however,
absolute concordance with all other solutions in the ivorh
—
a process which brouglit to light any defect, not only in the solution itself, but likewise in all conclusions previously adduced.
The chances
framework was elaborated
solid
minimum,
of error were thus reduced to a
while a
for future discoveries by other
investigators.
These others
details are given not only with the object of aiding
who might wish
to Avork
on
parallel lines, but to illus-
my
trate another salient feature brought to light by
editorial
work upon the “AnnuaP and the “Cyclopajdia,” namely, that the present tinsatisfactor ij condition of Medicine
is
due
to the
fact that investigators do not avail themselves of the enormous
array of solid data available to ascertain the truth. Blinded by the fallacious idea that the Avorth of a contribution to our knoAvl-
edge should be gauged solely by the ncAV experiments and clinical observations
it
adds to those already
aA-ailable,
they lose sight of
tbe fact that such experiments and observations are but bricks and mortar out of Avbich a coherent and truly useful Medicine
—can be
one indeed Avorthy of ranking as a science
The
built.
conception of ]\Iedicine'presented in the second
—and foreshadowed in this direction.
in the first
—
is
volume
submitted only as an
effort
It aims to replace the empirical and hazardous
use of remedies Avhich has undermined increasingly the confidence of our best observers in them, by a system of therapeutics based on solidly established facts Avhich makes
it
possible to trace
the centers influenced every phase of their action to its source, many levers through so may thus be used by the physician as which he can regulate the defensive agencies of the organism
and the mechanisms Avhich
distribute .them, precisely as a gen-
eral can govern the defensi\'e field.
As
the
disease-causing
movements substances,
of an
army
toxins,
in
the
endotoxins,
through toxic wastes, etc., are also sboAvn to produce by our remedies, a morbid action upon the centers influenced their effects
they
may
antagotbus be met directly Avhere they strike and
nized before they can destroy
life.
PREFACE TO THE SECOND AND THIRD EDITIONS.
X,\l
The work introduces no elixir of life, no universal panacea, nor even a new serum, the weapons recommended are available to all, viz., the identical remedies
—
daily use
shows,
I
which for years have been in It
the forty or fifty that have stood the test of time.
believe, that it is
not because we have been lacking
agents capable of successfully coping with disease that confidence in remedies has been steadily decreasing, but because they
were used blindly and often, therefore, injudiciously.
There
is
now not the least ground for doubt as to the efficiency of our I shall be amply repaid if 1 have suctherapeutic rcasources. ceeded in proving this fact, and if “Internal Secretions” to any degree instils into
its
readers the
unbounded confidence
in the
power of our remedies to antagonize and even master disease tliat a broad survey of the scientific facts at our disposal and considerable practical experience have instilled into me.
The plan
of the second volume, as stated in the preface,
included only “Applied
Therapeutics,”
i.e.,
the
physiological
action of drugs in morbid processes, but thanks to the liberal-
my
ity of
publishers, the F. A. Davis
Company,
I wa's able to
add a department in which the pathogenesis and treatment of the most fatal and distressing diseases with which we have to contend are treated in
Hence the comparatively large
full.
size
of the second volume. It
is
with great pleasure that I acknowledge the encour-
agement and moral support
1 have received during the rather arduous task the preparation of this work imposed upon me,
from
my
friends,
Davis Company,
Mr. F. A. Davis, president of the F. A. publishers, and Dr. J. Madison Taylor, my
my
associate in the editorial
management
ptedia of Practical Medicine.”
“Monthly Cyclo-
of the
Several of the microphotographs
presented in this volume were prepared by
my
son. Dr. Louis T.
de M. Sajous, from slides.
owe
to the kindness of
Some
of these I
Professors George A. Piersol and D. J. l\IcCarthy, of the Medical
Department of the University of Pennsylvania, to express
my
to
whom
I
wish
thanks. C. E. UE
M. Sajous.
^ .
f >
•
V,
Uusslnn Arcliives of Pathology, Clinical Med., and Bact., March, 1898. Gottlieb: Archly fUr exp. Path., Bd. xxxvlil, 1896. De Cyon: PflOger's Archly filr Physiol., yol. 1x11, p. 370, 1898. Vellch: Wiener med. Blatter, Noy. 11, 1897.
Mankowsky
No.
“
—
3,
:
vol.
EFFECTS OF SECRETION ON THE HEART AND VESSELS.
13
and efferent impulses of which and the portion of the cord immediately below it
established a cycle of afferent
the medulla
the
represent
The
center.
of
effects
structures can easily be foretold.
destruction
of
these
As showm by Strieker nearly
and by other physiologists since, extirpation of the cervical and dorsal portions of the cord causes arrest AYhen to this is added destruction of of the heart’s action. the medulla, the certainty of immediate death is but enhanced. forty years ago
Again,
agents
certain
known
—
chloral
hydrate,
the functional activity
to abolish
for
instance
—are
of the cord and
to
vagus had been severed. Applying these classical data to the question in jioint, it becomes evident that, if the inhibitor or augmentor centers were directly or reflexly stimulated by suprarenal extract, the effects of extirpation of these centers or of the cord would affect the heart as if the
not be counteracted receive
b}'’
its
use since there would he no center to
and transmit impulses.
The
arrest of the heart’s action
would therefore be permanent. But experiments have shown that the injection of suprarenal extract at once causes this organ to resume its beat notwithstanding total extirpation of the entire cord. the medulla
cut
mammals; to
9
and,
oblongata
when
millimeters,
and removed the entire cord of
injected
suprarenal
ralized rabbits until the heart-beats
restored
slow.
An
Biedl'*'*
the blood-pressure had become reduced
injection
of
This at once
extract.
brought up the pressure to 160 millimeters. cessively
Thus,
Gottlieb'*'*
chlo-
became in’egular and
suprarenal
extract
at
ex-
once
and volume of the pulse. He tried the pulse was no longer registrable by the manometer; a similar result was obtained, and the heart almost immediately resumed its nonnal action. Isaac Otrt” the
regularity
the same experiment
etherized a
when
rabbit,
cut the cord above the atlas, severed all the cardiac nerves in the neck, and verified the section of the cord post mortem. Injections of suprarenal extract were then used repeatedly as soon as the pressure became greatly lowered. Tliey brought it up from 24 to 144 the first time, from 17 to “Biedl:
« «
Wiener
klin. Wochenschrift, Bd. ix, 189G. Archlv fUr exp. Path, und Phar.. Bd x.xxviU 1896 Isaac Ott: Experiment No. 11, Medical Bulletin, Jan., ’l898.
Gottlieb:
’
— THE PHYSIOLOGY OF THE ADRENALS.
14
134 the second, and from 24 to 124 the third time, the interval between the injections of extract and the highest-pressure marks ranging from fifteen to thirty seconds.
which others of a similar kind could They distinctly show that, conthe conclusions of Cybulski, Wallace and Jilogk, Man-
Tliese experiments, to
be added, speak for themselves. trary to
kowsky, Gottlieb, and other observers, the inhibitory centers are not directly stimulated by the suprarenal extract.
And, indeed,
tbeir
conclusion
removal of the medulla and cord
and with injections the
—would
left
is
—does
cardio-inhibitory
mental result on injecting heart
apparently justified,
an only guide.
—an
experi-
affirmative
mammals
into
—slowing
of the
—
always be obtained, while the crucial test
tion of the vagus
—would
In
suprarenal extract directly
centers? it
if
out of consideration,
of suprarenal extract as
other words, to the question affect
is
sec-
at once confirm the conclusions pre-
viously reached by causing great increase in the rapidity of
But
the heart’s action.
division of the cardiac nerves in the
neck, including the vagus, and of the cord in no
way preventing
the action of the extract, the only logical deduction that imposes itself is
that the suprarenal extract exercises a siimulating action
directly
upon the cardiac muscle
irrespective of
any action upon
the inhibitory centers.
The Adrenal Secretion Elements. question.
—The
as Constrictor of Muscular
last deduction implicates other jffiases of the
Prominent among these
is
the
effect
ascribed
to
suprarenal extract upon the vasomotor system by various physiologists and clinicians. which are but little, if at
in
respect to their
before reaching
Is there all,
any such action?
Veins
infiuenced by the cardiac impulse
rhythmical changes of caliber, the blood
them having
to penetrate the capillary system
—
This .may be clearly seen by are distinctly contractile. examining the great veins opening into the heart, and in those of bat’s wings. ‘Although,” to use Foster’s^'^ words, “similar rhythmical variations, also possibly due to rhythmical contractions,
but possibly also of an entirely passive nature, have been observed in the portal veins, very little is known of any nervous
arrangements Foster;
goveiming
“Text-book
the
veins.”
of Physiology,” 1895.
Granting
that
veins
;
EFFECTS OF SECRETION ON THE HEART AND VESSELS.
endowed
are not
witli
we
a vasomotor snpidy,
15
find that they
nevertheless contract under the influence of suprarenal extract. Szynionowicz'’'^ observed that the pressure rose and fell in the
external jugular vein, along with the pressure caused in the
hy injections of this substance. Auld'*® states that, when suprarenal e.xtract was injected into a vein “which had been clamped as high as practicable, on releasing the vein after a few minutes a marked diminution of pressure was recorded as compared with that produced by injection into the free vein.” This arteries
shows a direct action on the vein while the extract was held in situ by clamping. While it is difficult to account for the general increase of vascular pressure caused by the extract without in-
cluding vasomotor nerves in the process, a direct action upon the vascular muscles themselves might underlie the result attained
which can only be elucidated by stripping the vessels of all their nervous connections and then watching the effects of the extracts. This procedure has been resorted to by Oliver and Schafer,®® and these physiologists have shown that a vessel a question
Even a
will contract after all the nerves to it are cut.
excised vessel influence
—
—
one,
therefore,
obviously freed of
all
freshly
nervous
an aqueous
will respond to the contracting effects of
solution of suprarenal extract, and, if a large vessel be used for the experiment to render the change of caliber
more
appreeiable,
the diameter will be found reduced nearly one-sixth.
Further-
more, these investigators®^ have found that it acts directly on the muscles of the blood-vessels, and that this action occurs equally well after section of the cord.
As we have
seen, destruction of
the adrenals or annihilation of their functions
extreme muscular weakness; conclusion
that
this
is followed by normally led them to the
—
muscle
striated, non^the and the cardiac muscle (which histologically partakes of both kinds of muscular tissue) are stimulated by the exall
varieties
of
striated,
—
traet.
Observing also that the latter caused a rapid increase of blood-pressure, and that
Szymonowicz:
gave a steep rise to the kymograph-
Archiv fUr die gesam. Physiol., Bd. Ixiv, 189G. British Medical Journal, June 3, 1899. Oliver and Schiiter: Journal of Physiology, vol. xviii, p. 420.
*“AuId:
“
it
Ibid.,
p.
230.
THE PHYSIOLOGY OF THE ADRENALS.
16
curve, they concluded that there
had been a strong constriction of
small arteries: strong, in their sense, meaning the relative constriction as compared to that of other vessels. This is fully
tlie
accounted for by the greater relative supply of muscular tissue vessels. As is well known, arteries are endowed with a coat of muscular fibers, which assumes increased thickness and relatively greater mechanical power as
in
peripheral
these
the capillaries are approached; so that in the smaller arteries the muscular layer
is
Nor
relatively quite thick.
to emphasize, in view particularly of the
is it
necessary
work done
in recent
years, that the adrenal active principle enhances the tone of the blood-vessels.
That
all
organs are similarly affected owing to their vas-
cular supply was also
shown by Oliver and
Schiifer
by means
of the plethysmograph, not alone the limbs, but such organs as
the sjileen and the kidney being contracted from 20 to 25 per cent,
intravenous injections of the extract.
after
These ex-
periments also showed that great vascular constriction in the splanchnic area was caused.
Veins,
we have
seen, are likewise
by suprarenal extract; they also contain muscular Although the supply of muscular in their thinner walls.
constricted fibers
elements
is
important than in the
compensated by
degree, va.scular
it
specific
contains,
is
principle,
beyond
Can we conclude from is
arteries,
greater lumen.
tJie
system of the organism
suprarenal
which
less
is
this
is,
That the
to
a
entire
thus acted upon hy the
owing to the muscular
tissues
que.stion.
these data that the vasomotor center ? As will be shown and adrenal extractives
never influenced by the suprarenal extract
later on, the secretion of the adrenals
enhance metabolic activity in living elements.
Their action on vessels
is
cells,
including vascular
thus independent of any
uixni the vasomotor center except in so far as their influence
on general metabolism is concerned, in which case this center would merely participate in the exaltation common to all tissues.
Briefly, Schiifer’s statement that “the intravenous injection
of suprarenal extract produces a powerful physiological action
upon the muscular system
in general, hut especially
upon the
muscular walls of the blood-vessels, and the muscular wall of the
EFFECTS OF SECRETION ON THE HEART AND VESSELS. heart”
may
be accepted as the basis of
tlie
conclusion
tliat
17 supra-
and vascular contraction hy stimuthe muscular elements of the heart and vessels,
renal extract causes cardiac Iflting
directly
and not hy exciting directly the vasomotor center. Action of the Adrenal Secretion upon the. Heart. We liave seen that destruction of the medulla and cord and
—
section of the cardiac nerves in the neck does not prevent the
the vasomotor center being thus func-
rise of blood-pressure;
tionally eliminated, it
clear that constriction of the vessels
is
does not occur under these conditions, as a result of impulses
Such being the case, it becomes a question whether Oliver and Schafer’s e.xplauation in respect namely; that to slowing of the heart by supi'arenal extract
transmitted, through them.
—
it is
due to reflex inhibition of this organ through the constric-
tion of the arterioles induced
—
We
holds.
still
look, in this connection, tlie fact that the active
which the heart
is
must not
over-
agency through
slowed, according to their views,
is
not the
suprarenal extract, but the impulses from the center to which the reflex inhibition
attributed,
is
and
it
is
plain that in the
absence of this center “inhibition” cannot occur.
slowing of the heart takes place
removed,
it
must be
clue to
Suprarenal extract, secretion of
tlie
when
this
Hence, as
center has
been
some other cause.
if its
action is similar to that of the
adrenals, should,
it
seems to
us, be
regarded
and not be confounded with toxics which pervert normal conditions, nor with elements foreign to existing structures. Considered from this standpoint, the adas a physiological agency,
dition of a given proportion of glandular substance to the
sum-
contained in the organism, or the removal of some by any method, should involve a corresponding augmentation total of that
or a diminution of the
normal manifestations that represent
suprarenal functions, whatever these suprarenal
of
extract,
we have
may
be.
The
injection
and marked increase of blood-pressure by stimulating the cardiac and vascular muscles. When, therefore, we speak of stimulating seen,
produces a rapid
these structures we imply contraction of the muscular fibers and approximation of the vascular walls toward the center of
Where is the need of “reflex inhibition,” evidently an obscure phenomenon, for, as Langley says, “wo
the blood-stream.
—
— THK
18 are
still
far
from any
inhibition”
in
I'lIYSlOLOGY OP
—when
real
a
THE ADRENALS.
knowledge of the processes involved
familiar clinieal faetor, the inereased
resistance offered to the contractile effort of the heart by the
augmented blood-pressure, affords a logical explanation of the slowness and increased power of the cardiac contractions?' We need not go beyond this explanation, therefore, to conclude that the slowing of the heart by adrenal extract
is
due mainly
to the
resistance which the increased blood-pressure caused by the extract offers to the cardiac contractions.
Functional Eelationship Between Arteries and Their Capillaiues Under the Influence of the Adrenal Secretion. The very marked contractile power that supra-
—
renal extract also possesses over the muscular coat of vessels
plays an important indirect role in the organism which seems to
have been overlooked so far:
i.e.,
that, as capillaries are not
supplied with muscles, their walls consisting of endothelial plates, they are not contracted as are arteries and arterioles.
This embodies two kindred prominent features of pathology:
i.e.,
the fact that
when
vessels supplied tvilh a
muscular coat
contract their capillaries dilate owing to the increased pressure to
which the
arterial contraction gives rise within
when
while the opposite relative mechanism
the latter,
vessels supplied
with a muscular coat dilate their capillaries contract
owing
to the resiliency of the latter
recedes.
In other words, while, in the
crowded outwardly, in the second
The
it is
—
when the blood first case,
prevails
in
them
the blood
is
crowded inwardly.
physiological importance of these propositions will be
shown in subsequent chapters, l)ut their bearing and soundness seem sustained by the fact that they alone, of all solutions so far advanced, can
nomenon
—
a
true
satisfactorily
suprarenal
explain an experimental phe-
paradox
—encountered
by
Lan-
and Charrin in the course of their earlier laboratory work.''" These observers, in order to study the action of suprarenal substance upon toxic agents and toxins, injected equal doses of virulent cultures into two groups of gujnea-pigs, the glois
animals constituting one of the groups having each been deprived of one suprarenal gland, d’he group of normal animals
“ 1890.
Lnnglols and Charrin:
Comptes-Rendus de
la Socl£>t6
de Biologie, July
10,
;
VARIATIONS IN ADRENAL FUNCTIONAL ACTIVITY. altogether
lived
138 hours;
mutilated animals
of
that
19
150
Several e.xperiments of the same kind were iicrformed
hours.
from which one gland
invariably did they find that the animals
had been e.xtirpated lived longer than those left in their normal condition. The differential contractility of vessels and capillaries referred to render this phenomenon a normal con-
The
sequence under the circumstances:
caliber of the
muscular
having and become enlarged and their walls relaxed by the loss of suprarenal stimulus, engorgement of the larger trunks occurred, and vessels,
arteries
veins,
the mutilated animals
of
caused depletion of the remote capillaries, including those of the central nervous system.
main primary
The
virulent toxins injected producing
upon the latter, and, the quantity them in a given time being smaller than in a normal animal, the longevity of the latter was protheir
effects
of toxic blood transported to
longed in proportion. I
frequently
shall
relative
behavior of
vessels
We
secretion or extract.
in
refer
subsequent chapters to this
under the
effects
will see also that it is
of
suprarenal
an important
feature, not only of the physiological action of certain drugs,
but also of various toxins, that of the pneumonia bacillus, for example. The conclusion, therefore, that vessels supplied with
muscular
a
tion
and
and
coat
dilation
capillaries are
antagonistic in
contrac-
only submitted as a postulate for the time
is
being.
AND DRUGS IN LARGE DOSES AS INHIBITORS OF ADRENAL FUNCTIONS.
TOXINS, POISONS, VENOMS,
Analogy suggests renal activity, there to
a certain extent,
proached. sufficient
normal standard of supramust be inadequate activity, physiological but pathological when extremes are apthat, besides the
Pending considerable testimony to
recall
that insufficiency
We
recognized as a clinical entity.
of
to this
the
effect it is
adrenals
is
now
have seen that hajinorrhage
into both adrenals can cause death,
and 'we shall see presently that various poisons likewise cause, mainly by variations of the blood-pressure, cessation of the adrenal functions. Is this result due to direct annihilation of the latter by the poison, or must 2
THE ADRENALS
20
IN DISEASE
AND POISONING.
be ascribed to some indirect factor, such as the variations of general blood-pressure, caused, as is well known, by many it
poisons, including certain toxins, affect the adrenals as well as other
and
wliicli
must
necessarily
organs?
This question may perhaps be elucidated by trying to account for the lupmorrhages that occur as a complication of local
These at
disease.
vast majority of
first
seem to afford a ready answer, since the
them are traceable
to organic lesions of the
glands that practically annul their efficiency by destroying the greater
part of their
organs and
substance.
Partial
destruction
the
of
corresponding loss of activity follow each other
any conclusion other than that,
so logically that
in accord with
the prevailing view, all poisons, toxins especially, act morbidly
upon the adrenal yet the
we have effect
tissues per se
would seem unwarranted.
And
in cerebral luemorrhage or “apoplexy” evidence to
that
adrenal
haunorrhage,
which Arnaud
termed
“adrenal apoplexy,” might also be due to high general bloodpressure, with rupture of the adrenal vessels, particularly
Again, poisons being carried to
these vessels are diseased.
parts of the organ
when
we should,
if
all
their action were direct, find
the lesion in the functional cellular elements throughout the entire organs.
Not only
is
this not the case, but the lesions
are essentially vascular.
While studying the pathological histology of suprarenal haemorrhage, Arnaud found that it was not in the medulla proper, as generally believed, that these haemorrhages occurred,
but in the tissues of the internal cortical zone. this
fact,
he states: “It
is
at
this
In emphasizing
point that the capillaries
When the tear under the influence of a powerful congestion. haemorrhage is important, it is due to rupture of one of the branches of the capsular vein at any point of its walls, and occurs into the medullary substance or into the central conThe medulla proper maj’^ be rejunctivo-vascular sheath.”
some probalily weakened part of the intrinsic portion of the vein hy the local disease constituting the yielding structure. Furthermore, Nature seems to protect the last vestiges of the medspected to the last, either a capillary peripheral to
—
it,
or
—
ullary substance even after a localized haemorrhage.
suggested by the fact that Arnaud found
in
This
such areas
is
evi-
THE ADRENALS
AND POISONING.
IN DISEASE
21
dent signs of organization, at times indicating a local inter-
inflammatory process, at others a retrogressive meta-
stitial
morphosis
observed
that
recalling
Iniematomata.
in
Briefly,
“The normal anatomical elements of the suprarenal gland may he found in a more or less perfect state
using his words:
of integrit}', either in the peri 2ihery of the growth or at one of its extremities.”
Toxins would hardly be so
Further analysis of this question
symptoms which characterize the
elicits
selective.
the fact that the
primary or-
jirogress of the
ganic disease of the adrenals differ totally from those attending Wliile the former
the liaBinorrhage proper.
may
suffering or be totally obscured by the signs of
disorder present, the
hardly cause
any concomitant
symptoms attending hiemorrhage are par-
and sudden, the patient abruptly screaming from excruciatingly intense pain in the abdomen, or dropping ticularly violent
coma from which he never rallies. more vivid picture of the hmmorrhage. Yet luemorrhagic foci
at once into apoplectifonn
Cerebral apoplexy does not furpish a
overwhelming
effects
of
found
in various stages of organization are
at autopsies.
Thus,
one of Arnaud’s cases suddenly fell into apoplectiform coma, and died in 48 hours; the only organs found diseased after death were the adrenals, which contained old hamiatomata, and various more or less organized hffi,morrhagic foci which showed that local hiemorrhages into them had repeatedly occurred.
The suprarenal substance was
entirely destroyed
ex-
cepting a narrow zone toward the inferior edge of the right
The
organ.
urine, during life,
and the kidneys, after death,
were
found normal.
Obviously we
acute
symptoms
primary organic
to the
cannot
well
lesion, since
ascribe
the
they appear
suddenly, practically without warning, and' promptly lead to a fatal issue.
Excessive,
i.e.,
disruptive congestion again suggests
itself.
Confirmatory evidence
is
also
afforded by the facts that,
irrespective of infectious diseases, adrenal hcemorrhage
may be caused by cardiac and renal disorders in which high blood-jiressure results from purely mechanical causes, and that, as is often the ease, fatal adrenal haimorrhage may occur irrespective of anv evidence of local disea.se or the presence of any bacteria. is
well
shown
This
in Andrewe’s case, referred to on page G, in wliich
THE ADRENALS
22
IN DISEASE
AND POISONING.
neither cultures nor stains showed the presence of pathogenic
organisms.
There
good ground for the belief, therefore, that the prevailing view that poisons act directly upon the adrenal tissues is
does not always apply,
i.e.,
that, besides the insufficiency of the
caused by disease of these organs, there
adrenals
brought on by the general blood-pressure when this
is
a form
is sufficiently
elevated (as in the course of to cause
mtense congestion
some mfections and intoxications) of the adrenals and rupture of some,
of their blood-vessels.
The morbid likely to
influence of high blood-pressure
manifest
itself
when part
—
been destroyed by local disease
the more
of the adrenals liave already
since the disruptive pressure
—
concentrated upon a smaller number of vessels
or
when
is
lesions
atheroma, for instance, have diminished their
of the vessels,
power to
is all
centrifugal pressure.
resist
nection, however,
Important in this con-
the fact that, contrary also to the prevailing
is
ground for the belief that hypertrophy of the adrenal secretory tissues, which has been observed by Langlois, Charrin, Petit, Stilling, and others in animals (see page 36) under the influence of injected poisons, does not appear to exert any compensative influence when local disease has destroyed
opinion, there
is
any part of the
medullar}'' zone of the gland.
As shown by Langlois, Gourfein, and tinue to live, when all but one-eleventh
—
been extirpated
add
—
mammals
con-
of their adrenals
had
others,
or destroyed by cautery or disease
we might
some compensative action or some accessory organ be present, death occurs when this limit of normal adthat, unless
renal substance
the medulla
is
reached.
itself
It seems logical, therefore, that, were
capable of assuming compensatory activity,
so large a
supply for emergencies (the nature of which will be
described
later
on)
would
hardly
have
been
provided.
If
analogy be again accepted as guide, other organs do not compensate for what insufficiency organic disease may produce in them by overtaxing remaining normal structures; collateral chromaffin tissues, supernumerary or accessory organs, vicarious functions,
and hypertrophy being
all
added elements, thus con-
stituting either auxiliary resources per se or auxiliary resources j)lus compensative growth. Even in the case of the organs
THE ADRENALS
IN DISEASE
23
AND POISONING.
of special sense, wlierc the loss of one organ imposes all the physiological labor upon the other, the existing tissues are not
overtaxed; they are brought to their highest proficiency by the increase of nutrition which the additional functional use in-
Whatever evidence we have, therefore, tends to show that the remaining normal structures of a diseased adrenal are not replaced by new adrenal tissue, and that they are increasingly exposed to disruptive congestion as the local morbid process volves.
advances. It
is
because of this that adrenal hiemorrhage
is
observed
Moreover, Laba-
with relative frequency in Addison’s disease.
found experimentally that lesions of the adrenals showed
zine®®
that these organs possessed very little regenerative power. large
portions, of
When
the glands were excised no restoration of
parenchyma occurred. Toxics which Produce Congestion or Venous Stasis IN THE Adrenals. The list of disorders to which adrenal hiemorrhage has been attributed is steadily increasing. Pneu-
—
monia,
thrush,
diphtheria,
meningitis,
cancer,
scarlatina,
variola,
sejiticiemia,
(toxic wastes), burns (toxic wastes
purpura,
tuberculosis,
uraemia,
asphyxia
and detritus), typhoid, jaun-
and eclampsia seem, however, to stand out most prominently all of which present as militant agent either a toxin or some toxic intermediate waste. The effect of burns is illustrated by Amaud’s case, in which sudden death followed a burn of the arm. Andrewes’s case, in which death occurred 36 hours after the first symptoms of an acute disease which he thought bore some points of resemblance to haemorrhagic smalldice
—
po.x,
also
illustrates
this
class.
In
fact,
instances
such
as
Andrewes’s have so often been noticed by clinicians that StilP'* has proposed a distinct category of cases in which “after an acute illness lasting only two or three days, usually with
a
purpuric or bullous eruption,” death occurs, “and the suprarenal lesion appears to he a part of the fatal issue.”
That general intoxication can thus act as an original cause shown experimentally. Thus, Eoger'^'’’
of haimorrhage has been Labazine:
Arch,
des
Sciences
Blologlques
de
St.
vol. xl, 1905.
“Still:
“Roger:
Lancet, May 7, 1898. Berliner kiln. Wochenschrlft, Jan.
21,
1894.
Petersbourg,
n.
249.
21
ADltKNALS IN DlSliASE AND POISONING.
Tllli
loimd that inoculation of
guinea-i)ig with a culture of the pnouiiiohacillus of Frietllaiuler was followed by i)i-ofuse haanorrhage into both capsules, the blood actually bursting througli tlio
the great capsular vein, or causing necrosis of the surrounding
elements by mechanical compression. strated
that suprarenal hiv.morrhage
the bacillus pyocyaneus.
Langlois®“
reached
the
demon-
could be brought on by
Charrin” found
hemorrhagic
by injecting which in some was not alone
that,
— —
diphtheria, toxins into guinea-pigs, congestion
instances
also
stage
caused, but he also observed that small doses used repeatedly
and during prolonged periods caused hypertrophy of the gans. fishes
Petit®'*
in
also
or-
noted, after introducing Loftier bacilli in
which the suprarenal structure
is
clearly glandular,
that all the phases of excessive reaction could be brought on.
Ilamiorrhagic foci were found by Wybauw®” in the adrenals of a child
which had died
of
broncho-pneumonia the
result of a
Kiesmann found the staphylococcus and Hamill and Dudgeon the pneumococcus.
tracheotomy for croup. aureus and albus,
That the functions
of the adrenals are actually inhibited
these various pathogenic agencies has been
shown
in
by
various
Mott and Halliburton, for example, found that after death from exhausting diseases the proportion of active princijile present in the adrenals was either absent or greatly reduced. ways.
By
ascertaining the relative proportion of chromaffin granules
in the adrenals of
50 adults who had died of various diseases.
Bainbridge and Parkinson**® were able to note the absence of the agent in the medulla of the organs of cases which had died of infectious diseases, peritonitis, shock, or whei’e a low blood-pres-
sure had existed.
Luksch*'®® ascertained
tlie
degree of functional
disturbance caused in the adrenals by disease, by ascertaining the relative
pressure-raising power
of
their
.material
While show any
extracts.
certain conditions, starvation, simple fever, did not
change in this direction, various infectious diseases;
uraemia and phosphorus poisoning, caused the extracts not to display the normal pressure-raising property.
“
Le Bulletin Medical, Feb. 7, 1894. Mddicale, June 3, 1896. La Semaine Mddicale, June 3, 1895.
nanglois:
”Charrln;
“ Petit: “ Wybauw:
La Semaine
Annales de la Socifetd Royale des Sciences M6d. et Nat. de Nos. 2 and 3. 1897. Bainbridge and Parkinson: British Med. .Tour., May 11, 190(. Luksch: Wiener kiinische Wochenschrift, B. xvli. No. 14, April 6, l» 0 a.
Bruxelles, vol.
vi,
Of
course, a certain proportion of these cases
uted to exhaustion of the glands
That the morbid
disease.
tlie
by the location of
blood-vessels,
veins, the proximity of the inferior
be attrib-
mainly due to excessive
variations of the blood-pressure is suggested its
may
during the course of
effects are
the organs, the richness of
25
AND POISONING.
TIIH ADKISNALS IN DISEASE
especially of its
vena cava, which receives the
blood almost directly from the gland on the right side.
Pressure
during labor upon the inferior vena cava and the suprarenal
and the
gland, located, as they are, between the liver anteriorly vertebral
column
posteriorly,
may
also give rise to congestion of
the vessels of the glands and result in Inemorrhage.
may
Various drugs
bring on hyperasmia, congestion, and
haemorrhage of the suprarenal glands, as shown by
Pilliet,®”'^
who
observed these phenomena after the use of nitrate of uranium.
Essence of cloves has also been found capable of stimulating tliem to such a degree as to bring
on macroscopically
visible
lesions.
On
the whole, the conclusion seems warranted that so
many
common
effect
toxic substances' cause adrenal hcemorrhage that
of all
these poisons
on
a
the general blood-pressure, sufficient to
cause active or passive congestion or venous stasis in the adrenals, is
necessary to explain the genesis of this class of cases.
Increased Functional Activity of the Adrenals as A Predisposing Cause op Adrenal Hemorrhage. The view
—
that the
adrenal
specific
principle
itself
possesses
powers has suggested to those who have accepted
it
antitoxic
the con-
clusion that a high degree of toxaemia, by overtaxing the organs,
caused congestion, and,
if
this reached
beyond certain
limits,
This conception was mainly based on the view of Brown-Sequard, who was led, by the toxic effects of blood taken from decapsulated animals upon normal ones, to ascribe lueniorrhage.
to the glands themselves a direct antitoxic '
function.
It
met
with further support in the fact that violent toxamiia invariably follows the removal of both organs, and was therefore accepted
by many investigators. It was also .maintained by Dubois,®^ v'“Hare:- Therapeutic Gazette, No. 519, 1887. Simonin: Centralblatt fUr Chlrurgle, 234, ’>*Falck: Deutsche Klinlk, vol. xl, 1859. Angelesco: La Seniaine M6dlcale, Dec. 14,
1877.
1891.
63
the adrenals in disease and poisoning.
Mercury was found by Kuperwasser^-* to be differentiated. lower the temperature 2° C., in some instances, when admin-
Opium and
istered in injudicious doses.
its
alkaloids are re-
ferred to as causing the skin to become cold
Oxalic acid in poisonous doses also gives
given in toxic doses. to livid surface
rise
when
tended,
and moist when
and cold
Phosphorus
skin.
ingested in toxic doses, with
often at-
is
what Wood terms
in the temperature,” the lowest point re-
“a remarkable corded some hours before death being 31.2° C. (88.2° Physostigma brought the temperature of a strong man fall
to
96.6°
F.
Santonin poisoning
coldness of the surface.
is
also
P.).
down
attended with great
Silver salts have likewise been found
to lower the temperature of animals.
Strychnine
another agent which tends also to show the
is
correctness of the contention that a low peripheral temperature
means an increased
central temperature.
observations of Ivionka,
who showed
Wood
refers to the
that “the primary eleva-
which occurs in strychnine poisoning, both in man and the lower animals, is in animals followed by a pronounced fall, which takes place even if the convulsions persist,” and to the affirmations of Mosso,^^® that, “even in curarized dogs a very pronounced rise of rectal temperature may be produced by strychnine.” Very suggestive in this connection
tion of temperature
is
the
denial
credited
to
Delezenne,^^®
'Vho
states
curarized animals the exhibition of strychnine
is
that
always
in fol-
lowed by an abatement of the central temperature, which is often, but not always, followed by an increase of the temperature of the surface.”
This increase Delezenne explains by “the
supposition that the drug has the power of dilating the peripheral
vessels.”
It
now becomes evident
that the only discrepancy
between the observations of Mosso and Delezenne latter
is
that the
used smaller doses of strychnine than the former, thus
producing central contraction and peripheral dilation, instead
and peidpheral contraction. trum, and zinc show corresponding effects, list of agents whose temperature variations of central dilation
Kuperwasser: 6,
Archives des Sciences Biologiques de
1898.
’’“Mosso: Archives italiennes de Biologie, 1886. Delezenne: Bulletin Mfidlcal du Nord, xxxiv,
1895.
Tobacco, vera-
and are St.
close
the
considered
Pdtersbourg, No.
— THE ADRENALS
54
along with
other
toxic
IN DISEASE effects.
AND POISONING.
All
present
a reduction of peripheral temperature as a sign of advanced poisoning; none
show simultaneous central and peripheral hyiiothermia several incidentally show that, when peripheral hypothermia is ;
present, there
is
simultaneous internal hyperthermia.
The personal view
that the adrenal secretion becomes con-
verted in the lungs into the oxidizing principle of the haemo-
globin
(see next chapter),
and thus sustains oxidation
in
all
accounts for the morbid effects of poisonous doses of
tissues,
drugs and venoms
on
temperature.
the
adrenals, active or passive,
is
Congestion
doses, of raising or depressing the blood-pressure.
gestion or engorgement
haemorrhage, adrenals,
may
it
is
of
the
caused by drugs capable, in full If this con-
excessive, or sufficient to cause adrenal
inhibit
or arrest
the
functions
of
the
and thus cause hypothermia.
A'enoms, which lower the teniperature mainly by dissolving the blood-cells, thus inhibiting the o.xygenizing power of the blood, also inhibit the functions of the adrenals by this process;
but they likewise do so by causing excessive variations of the blood-pressure as do other poisons, thus affording an additional cause of hypothermia.
SulIMAHY OF THE ^lOUBID EFFECTS OF DrUGS AND VENOMS ON THE Adrenals. In the light of the conclusions sub-
—
mitted in the foregoing sections (pages
3-i to
54) cnmcerning the
which the functions of the adrenals are compromised by variations of the general blood-pressure, on the one hand, and the morbid inlluence on the blood-pressure and through it on the adrenals of toxic doses of drugs, on the other, I submit
manner
in
the following conclusions as important in the clinical field: 1.
Drugs, such as antipyrin, alcohol, belladonna, cocaine, mercury, opium, strychnine, quinine, etc., whose
digitalis, ether,
action in full doses asthenia, hypotonia
produce,
among
is
to raise the blood-pressure, cause
and hypothermia in toxic
other effects:
acute
marked
doses, because they
congestion
and perhaps
hiemorrhage of the adrenals, and thus inhibit or arrest the functions of these organs. 2.
Drugs, such as aconite, arsenic, antimony, chloral, hydrowhose action
cyanic acid, jdiysostigma, tobacco, veratrine, etc., in
full
doses
is
to
lower
the
hlood-pressiire,
cause
marked
;
THE ADRENALS asthenia, hypotonia prodiiee,
among
IN DISEASE
and hypothermia
other ctreets
and perhaps hannorrhage
:
AND POISONING. in toxic doses, because they
passive conejestion or venous stasis
of the adrenals,
and thus inhibit
or
arrest the functions of these organs.
The symptoms produced by the
arrest of adrenal functions are
in both groups of drugs, viz., weakness, lowering of the
same
blood-pressure and temperature; but these same also
symptoms
the most prominent ones in Addison’s disease
are
and after
removal of both adrenals.
We
have seen on page 38 that
to toxins 3.
—
Venoms.
Noe and
all this
applies equally well,
a subject treated at length in the next chaj^ter.
—The
labors of Delezenne, Flexner
others having
and others
rattlesnake,
shown that some venoms
—caused
(1)
and
—
ISToguchi,
cobra, viper,
haemolysis, thus depriving
oxidizing power, and (2) proteolysis, thus exposing various tissues to necrobiosis and the vessels to softening the blood of
its
the adrenals receive blood incapable of sustaining their functions though destructive to their vascular their secretory activity being
and secretory elements;
impaired or arrested, the asthenia,
hypotonia and hypothermia from this source intensify
symptoms due
to the effects of this disorganized
-the
same
blood upon other
tissues.
Destined to suggest new lines of thought, the present work
would have
to
be restricted to this chapter, in so far as the
adrenals are concerned, were the prevailing views as to their
functions
—
-that
they serve to sustain the tone of the cardiac
—
and vascular muscles taken as sole guide. But, as is now well known, I have held for several years that this role is but an
—an
incidental feature of their true functions fully to sustain in the next chapter.
assertion I hope
ClIAPTEli
II.
THE FUNCTIONS xVNiJ DISEASES OF THE ADKEXALS. UNEXPLAINED PROPERTIES OF THE ADRENAL SECRETION.
—
As we have
seen, adrenal preparations
extracts, tlie
pow-
dered gland, the active principles, epinephrin, supracapsulin, adrenalin, etc. cause a rise of the blood-pressure with slowing
—
of the heart-beat, a minute dose sufficing to produce a
But, as liowelP
effect.
“the effects produced
states,
extracts are quite temporary in character.
marked l)y
few minutes the blood-pressure returns to normal,
as also tbe
heart-beat, showing that the substance has been destroj'ed in
way is
in the body, although
not known.^
where and how
such
In the course of a
some
this deslruciion occurs
According to Schafer, the kidneys and the
adrenals are not responsible for this prompt elimination
or
Several observers have shown
destniction of the active substance.
marked
on
satisfactorily that the material
producing
the heart and blood-pressure
present in perceptible quantities
is
this
effect
in the blood of the adrenal vein, so that there can be but little
doubt that
The
first
it
is
a distinct internal secretion of the adrenal.”
question which imposes
itself,
What
therefore, is:
is
the fate of the adrenal secretion in the body beyond the adrenal
vein ?
Adrenal preparations are
all
endowed, as
first
observed by
Vulpian many years ago, with marked reducing activity, i.e., with a marked tendency to take up ox}"gen. Abel, who isolated the adrenal active principle he termed “epinephrin,” for instance, so marked that Takamine noted that the
proved
a source of incon-
found this tendency
it
venience.
colorless aqueous solution of
his “adrenalin” \vas easily oxidized
color
changing from pink
to
rod,
by contact with the and eventually
to
air, its
brown.
Cybulski also observed that the addition of potassium permanganate, a powerful oxidizing agent, destro)"ed the activity of '
Howell:
“
The
Lor.
Italics are
(5d)
rif.,
my
p.
842.
own.
UNEXPLAINED PROPERTIES OF THE ADRENAL SECRETION.
the relatioiisliip between this reducing
ailreiial e.xtract.
What
property and
blood-pressure raising power?
tlie
is
Various experinieiiters ]\Iorel,^
57
clinicians, including lleichert,^
and
and Lepine,“ have observed that even non-toxic doses of
Others, caused a rise of temperature. prografts could adrenal Courmont,“ for example, found that duce such a rise as to warrant the iihrase “formidable hyper-
adrenal preparations
Conversely
thermia.”
we know
Addison’s disease,
adrenals,
that destructive disorders of the
example, or removal of the
for
adrenals, cause a rajiid decline of the gests that the adrenal secretion
temperature.
This sug-
must be endowed with oxidizing
power, and yet we have seen that it is a reducing agent. How account for this anomaly and for the power of adrenal products
temperature?
to raise the
When nephroma
the adrenal tissue of children, there
The
tion of the subject.
is
excessive,
is
in the hyper-
as
excessive oxidation
and overnutri-
process of growth and development are
such in some cases as to cause a child to appear several times age
—
its
a child of 4 years, for example, being as large as one of 16.
How
account for this phenomenon as a result of an excessive
when
production of adrenal secretion, which presumably occurs the secreting elements are also in excess?
Xot
all
extractives.
vessels are influenced
A
by the adrenal secretion or
striking fact in this connection
exemption of the pulmonary tissues to the
is
the apparent
effects of the secretion.
Wallace and iMogk' found that, while adrenal extract caused a rise
of the
systemic blood-pressure due to the contraetion of
the arterioles, the pressure in the
pulmonary
are the others.
Dixon.®
ments
arteries
is
This observation was confirmed by Brodie and
Velich,® on the other hand, found, by a series of experiinstituted
existed for the
to
ascertain
pulmonary
whether
vasoconstrictor
vessels, that adrenal extract
to but a slight rise of pressure.
Wann
fibers
gave rise
adrenal extract, which,
“Reichert: Univ. of Penna. Med. Dull., April, 1901. * Morel: Le ProgrOs MOdlcal, Aug. 3, 1903. “Lepine: La Semaine medical e, Feb. 18, 1903. “ Courmont: CongrSs de MOdecine Interne, Montpellier, 1898. Transactions of the Physiological Society, 7 Wallace and Mogk: 28“30, 1898.
Brodie and Dixon: Journal of Physiol., vol. xxx, p. "Velich: Wiener med. Wochenschrift, No. 26, 1898. 8
not
being acted upon as
raised, these vessels, in their opinion, not
416,
1903.
Dec.
FUNCTIONS AND DISEASES OF TUB ADRENALS.
58 wlien
apj)lic'(l
to exercise
even to
was found liy him upon tlie surface of the lungs. This familiar fact upon u-hich Parhon and (Jolstein*®
no such
accounts for the
skin, causes pallor,
tlio
cll'ect
lay stress, that intravenous injections of adrenalin can produce afcute
pulmonary
cedenia,
owing doubtless to the marked
Why
blood-pressure in the rest of the organism.
rise of
this exception ?
Such were the questions which I attempted to answer edition of this work, which appeared eight years ago.
in the
first That some functional relationship with the respiratory process should have suggested itself as at least a working proposition seems selfevident when the avidity of the adrenal product for oxygen, its influence over general oxidation and nutrition, and the invulnerability of the lungs to its action, on the one hand, and tlie fact that both pulmonary and tissue respiration still belonged to the domain of conjecture, on the other, are taken into account. That this relationship actually exists, is also sustained by a large number of solid data, biological, histological and clinical, and by the fact that it explains not only the mooted points just
many
enumerated, but
others which the prevailing doctrine fails
to elucidate.
THE ADRENAL SECRETION AS THE OXIDIZING AGENT OF THE H.EMOGLOBIN. That the prevailing view on the physiology of respiration, based on the diffusion of gases, has not been, and is not now, “When,” endorsed by all physiologists is now well known. caused is animal “an writes Professor ]\lathias Duval," of Paris, to breathe in the smallest possible space its
lungs
—
it
uses
up
all
the oxygen
hamioglobin, in virtue of
oxygen as fast as latter,
this gas is
always despoiled,
is
its
—the
air
in the air.
chemical
dissolved
m
affinity,
the
imprisoned in
This
serum
never able to satisfy
is
takes ,
its
because
vp the
so that the
absorption
coefficient for o.xygen, however low be this coefficient, and however slight be the tension of the oxygen in the surrounding air. As to the exhalation of carbonic acid, it is not produced so simply as would a priori seem, by mere gaseous diffusion or by
'I
Parhon and Golstein; Lor. rit., p. 725. Mathias Duval: Cours de Physiologle,
“
All Italics are
'o
my
own.
1892.
59
THE ADRENAL SECRETION AS THE OXIDIZING AGENT.
-
the mere giving off of a gas in solution, because of of the
in tlie
giis
suiTounding atmosphere.
tlic
Indeed,
scarcity
tlie
air in
the pulmonary vesieles contains 8 per cent, of carbonic acid, hardly a favorable eondition for the escape of carbonic acid from
the blood, especially since a portion of this gas is not dissolved, but combined M'ith the serum salts. It is therefore probable that the pulmonary tissues are the seat of an action having for This action object to rapidly dislodge the carbonic acid.
its is
Whenever oxygen is probably of a chemical nature. during experiments, the vitro in. even venous blood, mixed with One is led to admit, carbonie acid is immediately given off. .
that
therefore,
the
.
combination of
.
oxygen with the blood-
corpuscles (oxyhaemoglobulin) plays a role analogous to that of
and involving the elimination of carbonic acid from venous blood.” He refers to Eobin and Verdeil’s view in respect to the existence of a hypothetic “pneumonic acid” and to the an
acid,
experiments of Garnier,^^
who observed
that ultramarine blue,
sprayed into the lungs of living guinea-pigs, lost
its
color:
phenomenon which could only occur through the presence
a
of a
strong acid, neither taurin nor carbonic acid being capable of
producing
“Chemical analysis of the lung has not disclosed
it.
a specific acid, however.” “It is, perhaps, wrong,” adds Professor Duval, himself a prominent physiologist, “for physiologists to continue to only
phenomena mere results of endosmosis of liquids and of diffusion of gases through an inert membrane.” As a clinician, I would urge that this theory is harmful in its far-
see in these
reaching consequences. ter,
upon which
and that
it
is
it is
I
have pointed out that the aerotonome-
mainly founded,
is a
defective instrument,
because of this that the results recorded by
various physiologists have been divergent to such a degree that,
some instances, the diffusion of oxygen should occur, to corits indication in the wrong direction, i.e., from the haemoglobin to the alveolar air, the tension of oxygen in the arterial blood being actually higher than the pressure of ox 'gen 3 in
respond with
in the air-cells. I characterize the prevailing theor}^ as “harmful” because the physiologist, engrossed in his own field, does not realize that
Gamier:
Comptes-Rendus de I’Acaddmie des Sciences, July
26,
1886.
— FUNCTIONS AND UISFASES OF THE AURENAXS.
(30
dealing witli the foundation of probably the most important i)roblem of our day in its influence over human life, viz.,
lie is
immunity not only
—
in the tissues at large, but at the very thresh-
pulmonary alveolar surface, and the alimenshown later. ximtENAL Secretion in Pulmonary Pespiratton.
old of infection
the
tary canal, as will be
The In the
work (lil03) 1 advanced the view, sustained by considerable evidence, that the adrenals took edition of the present
first
a leading part in the respiratory process
by supplying a secrewhich absorbed the oxygen of the air in the pulmonary alveoli, then became a part of the hannoglobin and of the bloodtion
plasma, •which in turn carried
it,
as oxidizing principle, to all
tissues.
Three years after this opinion was formulated, a noted English physiologist, Peinbrey, wrote''* in an impartial review of the recent advances in physiology and bio-chemistry:
“It
is
impossible to give a satisfactory account of the gaseous exchange
between the blood and the alveolar
air.”
.
.
.
“The body
of
evidence has been steadily increasing in favor of the secretory theory, especially as regards the absorption of oxygen.”
theory
is
This
that of Bohr, advanced in 1891, which attributes the
oxygen-absorbing power and the excretion of carbon dioxide to active secretory processes carried on by the lining
membrane
of
While the need of a secretion capable of absorbing the oxygen has been steadily growing in favor, however, the the air-cells.
secreting
This
my
from
membrane has not been found. is
explained Avhen the respiratory process
viewpoint:
reducing secretion below,
its
is
properties
It
is
is
considered
not hy a local membrane that the
As shown and itinerary are precisely those required produced, but by the adrenrds.
for the process, while its presence can be ti'aced at every step to
the haemoglobin
A
itself, of
which
it
fomis part.
succinct review of the experimental evidence which has
invalidated the diffusion doctrine, and of that upon which
conception
better than a prolonged analysis of the question (for which
reader
is
my
of the respiratory process is based, will perha]')S serve
referred
to
previous editions)
to
tlie
convey the actual
status of the question. Pembrey: p. 549, 1906.
Hill’s
"Recent Advances
In
Physiology and Bio-Chemlstry,”
61
THE ADRENAL SECRETION AS THE OXIDIZING AGENT. Paul
P>erl/'”' tliirty
years ago, .showed experimentally that the
absorption of oxygen by the pulmonary blood persisted, even when Muller also observed the pressure of this gas was almost nil. that a strangulated animal exhausted the air in its lungs of all its
oxygen, while Setschenow and Holmgren,^'' Zuntz,’’ and others
found but traces of oxygen in the arterial blood of asphyxiated This suggested that the diffusion doctrine was defecanimals. tive, and that the absorption of oxj^gen from the air was due to
some This conclusion was substance capable of taking up this gas. sustained by the researches of Bohr,^® Haldane and Lorrain Smith,^“ Vaughan Harley,-“ and Bohr and Henriciues,"^ the last-
the presence, in the blood circulating through the lungs, of
named
referring
investigators
to
as
it
a
substance
greater avidity for oxygen than the blood itself”
“having
and presumably
“a kind of internal secretion.” This view has been antagonized by some of the advocates of
(whose aerotonometric figures are sugges-
the diffusion theory
tively discordant), but as
we have
seen the “evidence has been
steadily increasing in favor of the secretory theory, especially as
regards the absorption of oxygen.”
Having repeatedly noted the powerful reducing properties of adrenal extractives,
adrenals might
the
it
occurred to
fulfill
various lower animals and in
this
me
role.
man, and
that the secretion of
Anatomical studies in a systematic research in
the literature of the subject, demonstrated that
it
met
all
the
conditions required to satisfy so important a function.
The The
first
deduction imposed by these researches was that
secretion
of
the adrenals has a
marlced affinity for
oxygen, and inevitably reaches the pulmonary
air-cells.
Vulpian,^- over fifty years ago, found that adrenal juice reduced iron perchloride and iodine. Cybulski-® recorded a similar action
on potassium permanganate; Langlois-* noted,
however, that adrenal extract lost
its
reducing properties in vitro
’^Paul Bert: C. r. de I’Acad. des sci., Oct. 28, 1878. Setschenow and Holmgren, cited by Ludwig: Wiener raed. Jahrb., 21st
year,
i,
p.
1865.
145,
"Zuntz:
Hermann’s “Handbuch.”
iv. part 2, p. 43, 1882, Skandin. Archly fUr Physiologie, p. 236, 1891. J^S^'^one and Lorrain Smith: Jour, of Physiol., xxii. No, 3, p. 231, ^Vaughan Harley: IhUI., xxv. No. 1, p. .33, 1899. "Bohr and Henriques: Arch, de physiol., ix, pp. 459 and 819, 1897. jrXulplan: C. r. de I’Acad. des sci., p. 663, Sept. 29, 1856. - Cybulski Gaze-ta Lekarska, 2d series, xv, pp. 299-308, 1895. Langlois: Arch, de physioi. norm, et pathol., x, p. 124, 1898,
Bohr:
:
1897.
FUNCTIONS ANU UISKASKS OF THE AUUENALS.
62
when
oxidizing compounds were added. As to the action of the atmosphenc oxygen, Battclli*® found that adrenalin did not lose its jirojicrties when contact with air was iirevcnted, while Ahel,-“ 'rakainine,-' and others refer to this property as a source of
trouble in laboratories, the latter chemist specifying, in fact, that
adrenalin becomes oxidized by contact with the
air.
That the adrenal secretion inevitably reaches the evas
made
clear
air-cells
by a study of the anatomical relations between
the adrenals and the lungs.
The
blood of the efferent vessels of
the adrenals, their veins, passes to the inferior vena cava, directly
on the right
and by way of the renal vein on the
side,
The
left.
actual presence of the adrenal secretion in the blood of the
adrenal veins
is
shown by many experimental
Gottschau,-*
facts.
for example, traced hyaline granules (found subsequently to be
from the interior of the adrenals to their veins. This observation was confirmed and amplified by Manassc,-“ Aulde,®“ and Stilling.®' Pfaundler®® traced the same granules from the interior of the organ along the adrenal veins to the vena cava itself. It is doubtless the adrenal secretion and no other which is carried by the blood of the vena cava, for, when blood originating from the adrenals on its evay to this great trunk was injected into animals by C}'bulski and Scynionowicz,®® it protheir secretion)
duced the characteristic were confirmed by
effects of
adrenal extract.
Riedl,®'* Langlois,®®
These results
and Dreyer.®*
Scymono-
wicz, Riedl, Dreyer, Salvioli, and Pizzolini®' found; moreover,
that such effects could not be obtained with venous blood obtained
from other parts of the body.
The next
On
fact to assert itself
reaching
the
air-cells,
was that the
adrenal secretion
absorbs
o.xygen and becomes a constituent of luemoglobm and of the red corpuscles.
®®Battelli: C. Bull.
“Abel:
r.
de
la Soc.
de
biol.,
Johns Hopkins Hosp.,
liv, p. 1435, 1902. p. 215, Sept. -Oct.,
1898.
Takaniine: Therapeutic Gazette, p. 221, April 15, 1901. “Gottschau: Arch. f. Anat. u. Physiol., Anat. Abth., p. 412, 1883. “ Manasse: Arch. f. Path. u. Physiol., cxxxv, p. 263, 1894. “Aulde: Brit. Med. Jour., May 4, 1804. Arch. f. path. Anat., cix, p. 324, 1897. Stiiling: »» Pfaundicr: Sitzungsber. d. k. Akad. d. Wissensch. Mathem., cl, p. “ Cyhulski and Scymonowlcz: Gazeta Lekarska, 2d scries, xv, pp. 1895: Archiv f. d. ges. Physiol., Ixiv, Nos. 3 and 4, p. 97, 1896. “Biedl; Archiv f. d. ges. Physiol., Ixvli, part 9-10, 1897. “Langlois: Arch, de physiol, norm, et pathol., ix, p. 152. 1897. “ Dreyer: American Journal of Physiology, 11, p. 203, 1899. ” Salvioli and Pizzollni: Gazetta degll osped.. Mar. 23, 1902.
3,
1892.
299-308,
THE ADRENAL SECRETION AS THE OXIDIZING AGENT.
63
While a reducing substance has been found necessary, we have seen, to account for the absorption of oxygen from the
happened that the greater part of the htenioglobin molecule was composed almost entirely of an albuminous substance which had remained unidentiiicd. Gangce,*'’® for instance, alveolar air, it
states
that “hamioglobin exists in the blood-corpuscles in the
form of a compound with a yet unknown constituent of the corThis body he defines as the “albuminous moiety of the puscles.” molecule”
liamioglobin
and,^”
as
representing
per
96
cent,
of this molecule, the remaining 4 per cent, being the iron-
laden haematin.
Now,
I
found that
of haemoglobin corresponded in
ether,
and
“unknown
constituent”
physicochemical properties
insoluble in absolute alcohol, chloroform, benzol,
is
all
this
Gamgee,'*" for example, states that
with the adrenal secretion. haemoglobin
its
organic solvents
:
Vulpian'*^
had already noted that, showed this
of all glandular produets, that of the adrenals alone peculiarity.
Gautier,'*- Moore,'***
and Takamine
also refer to
it.
Again, according to Moore and Purinton,'*'* adrenal extracts are rapidly destroyed by alkalies; this
haemoglobin.
This pigment likewise
resists
point; this applies also, according to others to adrenal extract.
a characteristic of
also
is
heat up to the boiling Moore,'*®
C}'bulski,'***
and
Finally, Mulon'*' found that the red
corpuscles gave the histochemical reactions of the active principle of the adrenals, thus showing that these blood-cells actually coutain this principle.
Since then the adrenal reaction has been
obtained from blood-elements wherever sought, including that of the placenta.
In confirmation of this conclusion
The oxygen-laden adrenal
is
secretion
the fact that is
a constituent of the
albuminous hcemoglobin in the blood-plasma. BattellP® isolated from the blood a product the chemical properties of adrenalin. is
That
endowed with
this adrenal principle
a constituent of the albuminous portion of liamioglobin voided
“Gamgee: Gamgee: Gamgee; ‘’Vulplan: *=
«
Gautier:
Schafer’s “Text-book of Physiology,” Ibid., p. 207, 1898. Ibid., p, 206, 1898. C. r. de I’Acad. des scl.
Chimie biologique,
p.
355,
i.
de Paris, Sept.
p.
29.
189,
1898.
1856.
1892.
Moore;
Journal of Physiology, xvii, p. xlv, 1894-95. “Moore and Purlnton: American Journal of Physiology, “Cybulskl: Gazeta Lekarska, Mar. 23, 1895. “ Moore: Loc. cit. “Mulon; Personal Commun'eat'on. “Battelll: C. r. de la Soo. de biol., liv, p. 1179. 1902.
iii,
p.
15,
1900.
FUNCTIONS ANO DISEASES OF THE ADRENALS.
()4
by red corpuscles herg,^“
slioAved that
plasma suggested
in the
when Scluniede-
itself
Ahelous and Biarues/’*
Jaquet,"®
and other chemists
hlood-plasma contains an o.xidizing substance, sub-
Kot only was
sequently knoM’n as oxidase. at least uj) to the boiling point
and
found to
it
resist
heat
to possess otlier chemical char-
acteristics of the adrenal principle, hut the actual presence of the
latter is confirmed
by other
facts.
Thus, in 1853, Traube had
concluded that htemoglohin could not functions ascribed to
fulfill
the physicoehemical
without the aid of a catalyzer.
it
showed that the adrenal principle was a
PoehP-
catalyzer, while Jolles''*
pointed out that the activity of a given volume of blood as a catalyzer corresponded with the
number
of red corpuscles
It is because of this that Oliver
tained.
it
con-
and Schafer found that
oxidation of the adrenal principle does not occur in the blood; acting as a catalyzer
monary
simply transfers oxygen from the pul-
it
air to the tissues
without being
modified by the
itself
Indeed, Miller®'* found that the blood of a rabbit which
contact.
a dose of adrenalin caused a typical rise of blood-
had received pressure
when
injected into the blood of another rabbit, although
the effects of the adrenal principle upon the
first
animal had
Additional evidence to this effect and an explanation of
ceased.
the role of the red corpuscles were afforded by the next conclusion
reached
:
That corpuscles, after absorbing the oxygenized adrenal
The red
secretion {the albuminous constituent of their h(Emoglobin) yield it to the blood-plasma in the form of droplets, the so-called “blood-platelets.”
under the influence of various chemical agents, “undergoes a decomposition of which the chief products are, an albuminous substance or substances, and a coloring matter which contains the whole of tlie iron”; Init,
As Gamgee®®
teaches, luemoglobin,
as he also says, “the coloring matter of the red corpuscles is not This does not, however, extracted from them by the plasma.”
apply to their albuminous substance.
That they discharge the
Schmiedeberg: Archiv f. exper. Path. u. Pharm., v p. 23.'?, ISiG. “Jaquet, cited by Salkowski: Archiv f. path. Anat., Jan. 4. 1897. series, Ahelous and Blarn6s: Arch, de physiol, norm, et pathol., .Gth
«
,
pp. 195, 239, 1895.
Poehl: “Jolles:
May
Indian Lancet,
22,
1904.
MQnch. nied. W'och.,.p. 2083. Nov. “ Miller: Jour. Amer. Mod. Assoc., May 18,
“Gamgee:
Loc.
cil.,
1,
p.
189,
1898.
1904. 1907.
22.
vii,
THE ADRENAL SECRETION AS THE OXIDIZING AGENT. latter in the
plasma
is
rendered evident by various
()5
Louis
facts.
Elsberg/® thirty years ago, observed “a projection of a pediculated granule or knob” from tlie periphery of red corpuscles. Hirschfeld®^ traced these granules from the interior of tliese
up
cells,
through one or more minute apertures which closed the surrounding plasma. Brockbank’’'’® gave recently a beautiful microphotograph of “platelets in, or being extruded from, red cells.”
again, to
Again, Detemann'^® noted that the buds on the surface first are attached to the cell by protoplasmic
of the red cells “at
processes and contain
hemoglobin”; but
become separated from the
that, “later, the
buds This
losing their hemoglobin.”
cell,
does not militate against Gamgee’s statement that the coloring
matter remains in the corpuscles, but
albuminous constituent
is
it
indicates
that
the
voided into the plasma.
These albuminous droplets (which, in 1903,®“ I identified as absorbed o.xygen in the lungs,
the familiar hlood-iP.atelets)
should, in the light of preceding deductions
and owing
to the
catalyzing property of their adrenal principle, be able to sur-
render their oxj'gen to any agent in the blood or tissues possessed
power to appropriate it. That this applies shown by the reaction to certain stains. Litten®^ and others found, for example, that blood-platelets derived from of sufficient reducing to the droplets is
the red corpuscles are best stained Avith methylene-blue; Stengel,
White, and Pepper®®
state, in fact, that
the only positive results.” certainly rieh in oxygen
—
as
their identity as the oxygenized
—
adrenal seeretion would suggest the
conditions
“essential
“methylene-blue gave
This indicates that the droplets are
to
for, as
the
Ehrlieh teaches, one of
methylene-blue
reaction”
is
“oxygen saturation.”®®
A
study of the melanins then showed that
The alhuminous constituent laden adrenal secretion^
is
of the hcemoglohin, or oxygen-
distributed by the red corpuscles to all
parts of the body as an oxidizing agent.
“
Louis Elsberg: Annals of the N. Y. Acad, of Sci., i, 1879. Hirschfeld: Virchow’s Archiv, clxvi, part 2, p. 195, 1901. Brockhank: Med. Chronicle, Mar., 1908. Determann: Deut. Archiv f. klin. Med., Ixi, part 4, p. 365, 1898. ““ Sajous: The present work, 1st ed., vol. i, p. 715, 1903. “'Litten: Deut. nied. Woch., No. 44, Nov. 2, 1899. ““Stengel, White, and Pepper: Amer. .lour. Med. Sci., May 9, 1902. “ Quoted hy L. P. Darker: New York Medical Journal, May 15 et scg., 1897
“
to 1898.
— FUNCTIONS AND DISEASES OP THE ADRENALS.
(i()
Leonard
most
Hill/'*
llirschfeld,
Chittenden and
Albro,”'' and upon melanins, the brown and black certain forms of sarcoma, in the tissues, the
classic writers look
pigments found in
blood, the urine, etc., in various morbid states, as ha.mioglobin
While Mbnier, Hrandl, and L. Pfeiffer"® found that contained iron, and accept this origin, l^encki and Berdez"^ do not, because they failed to find this metal in the pigment isolated derivatives. it
from a melanotic sarcoma. These discordant opinions are harmonized, hoM’6ver, by the newer conception I submit: The first-
named authors
dealt with whole luemoglobin, containing, there-
fore, its iron; while
Xencki and Berdez dealt quite as surely its albuminous constituent.
with luemoglobin, but only with
Having traced
to the adrenals the origin of the active agent
of this albuminous hamioglobin and this substance being melanin,
the presence of the adrenal
shown.
In the
first
principle
in
melanins should be
place these pigments were found by Walter
Jones"" insoluble in alcohol, ether, benzol, chloroform,
etc., i.e..
precisely as Vulpian, Moore,
and others had found
with the adrenal principle.
This applies as well to the action of
alkalies, to
which Jones,
and
Aliel
to be the case
and Davis"® found melanins very
In the second place direct evidence was afforded by Boinet,'® who found chemically that the bronze pigment of Addison’s disease was identical to melanin, and also sensitive,
to other tests.
by ]\Iuhlmann,'‘ who discovered independently that the Addison ian pigment was a product of the adrenals.
-
Finally, as the connection of the adrenal product with res-
piration and o.xygcnation I urge, suggests:
An
excess of adrenal secretion causes a nse of temperature. This action was first observed by Oliver and Schafer.'®
Keichert’" recorded a rise of 1° C. in the dog, having reached this
temperature “in
mental animals
it
less
than forty minutes.”
In three experi-
“continued hypernonnal for over two hours.”
•“Leonard Hill: “Text-book of Chemistry.” p. 374, 1903. ““Chittenden and Albro: Amer. Jour, of Physiol., 11, p. 291, »“ Morner, Brandi, and L. Pfeiffer, cited by Haramarsten: Physiological Chemistry," 5th American Ed., p. 688, 1908. Nenckl and Berdez: Ibid. Walter Jones: Amer. Jour, of Physiol., il, p. 380. 1899. ““ Abel and Davis: Jour, of Exper. Med., I, p. 381, 1879.
™
Boinet:
Marseille mOd., April
15,
1896.
Milhlmann: Deut. med. Woeh., No. 26, p. 409, 1896. Oliver and Sehilfer: Jour, of Physiol., xvlii, p. 2.30, ” Reichert: Unlv. of Penna. Med. Bull., April, 1901.
1895.
1899.
“Text-book of
THE!
ADRENAL SECRETION AS THE OXIDIZING AGENT.
MorcF* noted
67
a rise of 0.5° to 1° C. (0.9° to 1.8° F.) in guinea-
Lepine^® states that the increase of blood-pressure caused
pigs.
by adrenal extract This
is
is
always followed by a rise of temperature.
controlled by the familiar fact, first observed by
Sequard, that removal of the adrenals
is
Brown-
followed by a steady
decline of temperature and by the hypothermia which attends
Addison’s disease. Additional evidence on this particular feature of the gen-
problem will be found in Volume II. I studied, for example, the evolution of the red corpuscles throughout the animal scale'’“
eral
and learned that they were tardy additions to the blood
when the Inemoglobin
cells
many
invertebrates
as storage
diffused in the plasma, as
is
in
and in certain low vertebrates, failed
to
satisfy the needs of the vital process.
the conclusion that, contrary to what
it
Having been brought to now taught, it is the
is
plasmatic Inemoglobin which carries oxygen to the tissues and not the red cells (though these act as storage cells for it as a constituent of their albuminous Inemoglobin),
stance in
various tissues and organs,
I traced this
sub-
including the nervous
system, the guaiac and methylene-blue tests being those most frequently employed. reactions
term to
of
the
Again,
I
found that the oxidases gave the
oxygen-laden adrenal
secretion.
Hence the
I applied to the latter: adrenoxidaseJ'^
On the whole, this evidence, considered collectivelj^, seems me to afford a solid foundation for the conclusion that It is the adrenal secretion which, after dhsorhing
from
the 'pulmonary air
and heing taken up hy the red
oxygen
corpuscles,
supplies the whole organism, including the hlood, with its oxygen. It
is,
as such, the oxidizing constituent of the hcemoglohin, which,
in turn, sustains tissue oxidation
and metaholism. This latter function is treated in detail in the second volume. “That the suprarenals are related in some way to metabolic changes in the tissues and organs,” says Schafer,'^® “there can be but little doubt. This is indicated by the symptoms of Addison’s disease.”
Additional evidence in favor of this conception of the role ’‘Morel: Le Progrfis medical, Aug. 3, 1903. ” LOpine: La Semaine mOdicale, Peb. 18, 1903. Sajous: The present work, p. 828.
”
™
Sajous: Ihid., p. 822. Schafer: British Med. Jour., June n
G,
1908.
FUNCTIONS AND DISEASES OF THE ADRENALS.
()S
of the adrenal secretion
is
all'orded
by the fact that
it
accounts,
shown by a few examples, for the properties of the adrenal secretion and preparations that the prevailing restricted as will he
view
fails to explain.
Increased oxidation clearly accounts, for instance, for the observations of Reichert, Morel, Lepine and others, referred to above, that even non-toxic doses of adrenal extractives produce a rise of temperature, or those of Israel'® which showed the great frequency of fever in tumors of the adrenals, or those of Courinont"® in which adrenal grafts produced without the least
evidence of infection what he characterized as a “formidable hyperthermia.” In the latter cases it persisted until death oc-
Xor
curred.
with the
rise
is
an ephemeral phenomenon,
it
blood-pressure,
of
in
the
as
is
adrenal preparations, for, as Reichert observed in
ments, the high temperature persisted as
the case
experimental use of
much
as
liis
experi-
two hours in
some of the animals. Again, adrenal preparations are familiarly known to raise the blood-pressure; but, obviously this
but not how they do adrenal secretion
as
it.
tells
This becomes
us only what they do,
clear,
the active constituent
however, when the of hiemoglobin
is
regarded as the oxidizing agent of the tissues, and, as such, an active factor in metabolism.
The muscular elements
of the arter-
being themselves the seat of increased metabolic activity, they
ies
are
caused to contract, thus raising the blood-pressure.
shown by Oliver and Schafer, however, there is action on the arterioles, and by Meltzer®^ a similar
also a
As
direct
action on the
capillaries. This local effect is due also to enhanced metabolic activity of the adrenal product, its identity as catalyzer enabling it to activate oxidation in any
endothelium of the the
tissue with
The
which
it
comes into contact.
hypernephroma the inordinate oxidation, due
excessive growth of children caused by
also finds its
normal explanation
in
to the overproduction of adrenal secretion.
The
resulting surplus
activity, with alinormnl appetite and thirst as accompaniment, clearly accounts for the excess of nutriwhich the jihenomenal overgrowth is due.
of metabolic logical
tion to
cUtd by Moffltt: Boston Med. and Surg. Jour., Oct. S. Courmont: Congrfis de M^declne Interne, Montpellier, 1898. Meltzer; Amer. Jour. -Med. Sel., Jan., 190:".
^•Israel,
1908.
69
THE ADRENAL SECRETION AS THE OXIDIZING AGENT. 111
its
relations
general diseases,
to
tlie
adrenals as
of
identity
the
accounts for
the eontrolling agents of oxidation
that ubiquitous syiuptoiii, fever, the inechanisin of which has also remained obscure. This gives these organs a prominent place in
Indeed,
pathology. certain limit
is
if
the
modern doctrine that
fever
up
to a
the outward expression of an auto-protective or
sound—and the bulk of evidence strongly become factors in —the adrenals,
immunizing process sustains this view
is
fever,
as direct
Their also direct factors in protecting the body against disease. role in the economy thus assumes noble proportions in the extreme, since by their influence on tissue oxidation the adrenals sustain
life,
defend
life.
while through their participation in immunity they
Addison’s disease
may
be due, as
is
well known, to tuber-
and other organic disorders of the changes in the solar plexus and semiadrenals, or to pathologic lunar ganglia. But how do these lesions cause the Addisonian Many theories have been sjmdrome iii all its complexity? culosis,
cancer,
cirrhosis,
vouchsafed, but, in truth, as Anders'*- puts
it,
“the pathologic
connection between the sj^mptomatic phenomena of Addison’s disease
and the anatomic
lesions has not
been made out.”
jSTow,
consider the disease with the adrenals as governing oxidation and
metabolism these
:
three
The
adrenals being the seat of destructive lesions,
conjoined
functions
deficient oxidation
;
show signs of and clamminess due to
increasingly
deterioration; hence the low temperature
the marked and progressive asthenia, with
great lassitude, due to inadequate metabolism in
all
muscles ; the
small and feeble pulse and weak heart action and steady lowering of the blood-pressure due also to inadequate
metabolism in the
cardiac and vascular muscles; the tendency to vertigo and the
mental torpor due to ischagmia of the cerebrum, the turn, of the general vasodilation
result, in
and of the resulting withdrawal
of blood into the deep vessels, and, finally, the bronzing,
due
like-
wise to vaso-relaxation and circulatory torpor, the latter entailing the deposition in the epidermis of what has been found chemically to be the oxidized adrenal product,
i.e.,
melanin.
The experimental production of glycosuria by injections of adrenalin reported by Blum, Croftan, TTerter, and others is nowAnders:
“Practice of Medicine,”
p.
489,
OtU cd., 1909.
FUNCTIONS AND DISEASES OP THE ADRENALS.
70
familiar to every one.
The
labors of rollak'‘“ have
shown that, this form of glycosuria was due to some relationship between the adrenal product and the hepatic glycogen. But what is this relationship ? Here, again, the role had previously suggested,
as I
of the adrenals in oxidation tion
:
By
and metabolism supplies the explana-
raising the blood’s asset in o.xygen, the adrenal active
principle injected raises the rate of metabolic activity throughout
the entire organism, including, of course, the pancreas.
This organ being caused to secrete an excess of amylopsin, which in turn converts an excess of glycogen into sugar, the proportion of the latter in the blood soon exceeds the needs of the body, and the
surplus
is
The
eliminated in the urine.
adrenals themselves in the process
is
participation of the
controlled by various facts.
when the
Herter, for example, found that glycosuria was caused adrenals were compressed in such a
way
as to increase the outflow
of secretion, while, conversely, ligation of the adrenal veins which
transfer the secretion to the inferior vena cava caused the sugar to
diminish rapidly, both in the blood and in
our resources in the treatment of diabetes are
That enhanced by due
tlie
urine.
consideration of the part played by the adrenals in one of
forms
its
soon shown by therapeutic results obtained.
is
Many
other disorders the pathogenesis of which
and the treatment of which
is
obscured
is
unsatisfactory, mainly
owing to
the fact that the adrenals are overlooked in their pathogenesis, are described in detail in the second volume.
mitted in the foregoing pages will that the
function now
suffice,
The
facts sub-
however, to suggest
attributed to the adrenals,
i.e.,
that of
sustaining the tone of the vascular system, is hut an epiphenomenon of its true function: that of sustaining pulmonary and tissue respiration.
ntE GOVERNING CENTER OF THE ADRENALS. THE PITUIT.ARO-ADRENAL NERVE. such important duties in the organism as the above should be governed by some nerve-center almost
That organs
imposes tively
itself
fulfilling
when we
minor importance
"•’Poliak:
Arch.
f.
consider that
—
many
functions of rela-
color vision, coughing, sweating, ear
exper. Path. u. Pharm., Bd.
1x1,
S.
1-19.
— THE GOVERNING CENTER OF THE ADRENALS. movements, connection
etc.
—are supplied with showed that
first
The governing
one.
71
My
researches in this
is
neither located in
:
center of the adrenals
the cerehrum nor in the medulla oblongata, hut in
some organ
at the base of the brain.
Eemoval of both hemispheres does not influence temperaGorin and ture, as shown by Fredericq,®^ Goltz, and others. van Beneden*® found in fact that, in decerebrated pigeons, the oxygen intake and the carbonic acid output did not differ from Pembrey®” states moreover that “the that of normal pigeons. rapid rise in temperature which occurs when a hibernating mannot awakens is not prevented by removal of the cerebral This applies as well to so high a
hemispheres.”
dog, in which, as
shown by
Goltz,®'^
mammal
as the
removal of the hemispheres,
including a part of the optic thalami and corpora striata (whose
by removal of the cortex, the impulses of which they transform and transmit), did' not interfere with any purely vegetative fimction. Evidently, therefore, functions
are
also
annulled
although the hemispheres and the basal ganglia can,
when
the
seat of lesions, cause a rise of temperature, the heat center is not
located in these organs.
The
base of the brain, however, asserts itself as a pathway
thermogenic
for
Schreiber,®®
impulses.
While
Tschetschichin,
in
1866,
and Eeichert®® located a thermoaugmentor center in
the pontobulbar region, Ott,®“ Tangl,®^ and Sakowitsch®- obtained
a marked rise of temperature by jiroducing lesions higher up, i.e.,
in the floor of the third ventricle
and the tuber cinereum.
But, as Eichet has long held, and as Schiifer®® states, examination of such experiments shows that “the results are
closely
dependent upon the establishment of an irritative lesion in parts which are either directly in or in close proximity to the path taken by motor impulses.” On the whole, the thermogenic lesions in the basal tissues
must have
irritated nerve-paths
some structure beneath the hemispheres. Fr6d«ricq: Arch, de biol., ill, p. 747, 4882. Gorin and van Beneden: Ibid., vil, p. 265, 1889. Schafer’s “Text-book of Physiology,” Goltz: Arch. f. d. ges. Physiol., li, p. 670, 1892.
“Pembrey:
“Schrelber: Ibid., viii, p. 576. “Reichert: Jour. Amer. Med. Assoc., January 18, “ Ott: Therap. Gaz., June 15, 1903. '^Tangl, cited by Ott: Ibid. “Sakowitsch: Neurol. Centralbl., xvl, p. 520, 1897.
“
Schafer;
Loc.
cit.,
il,
p.
717.
i,
p.
1902.
864,
1898.
from
— FUNCTIONS AND DISEASES OF THE ADRENALS.
72
Further study of the question then showed 'that The pituitary body se7ids nerve-fibers upward to the tuber cinereum and the walls of the third ventricle, and thence to the :
pontobulbar region and spinal cord.
As
just shown, the heat center can only be located beneath
the brain and basal ganglia.
Now,
anterior to the optic tlialami,
the corpora striata, and the scat of the thermogenic lesions pro-
duced by Ott and others, there
no organ capable of generating nerve impulses by way of the tuber cinereum other than the pituitary body.
exists
Tlie labors of
many
investigators in recent
years have overthrown the view that any part of
man
body of
is
vestigial.
histological grounds, “it is
tlie
As Herring®^ concluded
pituitary
recently on
an organ of physiological importance.”
The
various kinds of nerve-cells, neuroglia-cells, and ependyma-
cells
described by Berkley in the posterior lobe are of as great
physiological importance, from
my
viewpoint, as any in the body
at large.
Cushing"® recently confirmed by a large number of experiments the fact previously emphasized by many investigators, that complete removal of the pituitary invariably pro-
duced death. Sappey, Luschka, Muller, and others of the older anatomists refer to the presence of nerve-fibers passing from the pitui-
up to the third ventricle. But it was the Golgi method had been introduced that this fact
tary body along
only after
its
pedicle,
could be placed on a solid basis. that the fibers passed
thalami.
Joris"^ also
upward
Bamon y
Cajal"“ then found
to a large nucleus
behind the optic
found histologically that “numerous
descend in parallel lines along the pedicle of the
fibers
])ituitary.
They do not all come from the retro-optic nucleus,” he writes; “some come from regions posterior to the infundibulum”. .
.
Bearing directly upon the production of thermogenic impulses is the discovery by Gentes"" of fibers which pass from the pituitary to the tuber cinereum.
Andriezen"" had also traced, in the
white mouse, fibers from the pituitary to the pons.
We
thus have a direct nerve path from the pituitary to
tlie
“
Herring: Quarterly Jour, of Exp. Physiol., I, No. 2, 1908. “‘Cushing: Jour. Amer. Med. Assoc., p. 249, 1909. “> Ramon y Cajal: Anales dc la Soc. espaflola de hist, nat., 2a Scrla, p.
214,
1894.
« Joris: Mgm.
Couron. de I’Acad. Roy de Belgique, xlx, part “Gentfis: C. r. de la Soc. de blol., Iv, p. 1500, 1903. Audriezen: British Medical Journal, January 13, 1891.
10,
1908.
xxlll,
THE GOVERNING CENTER pontobulbar region
—
points, the lesions
tlie
OF.
73
THE ADRENALS.
identical tract along which, at various
produced by Ott, Tangl, Sakowitsch, and
Eeichert provoked a marked rise of temperature. We will see presently that this path is continued down the cord, and that it eventually reaches the adrenals.
determined was a striking functional Schafer and correlation between the pituitary and the adrenals. Ilerring'®” recently emphasized this parallelism not only as to their function, but also as to their development and structure.
The next
feature
I asceidained, for example, that
tion
The pituitary, like the adrenals, influenced general oxidaand the temperature, and also general metabolism and
nutrition.
Although removal of the hemispheres does not influence the temperature, as we have seen, removal of tlie pituitary deeply Marinesco'”^ and Yassale and Sacchi“affects this process. observed that it was followed by increasing hypothermia. This cannot be ascribed to operative shock, for Masay^"‘‘
trephined
first
the sella turcica to expose the pituitary, and allowed the animal to recover after
The
this—the most violent step of the experiment. was the same. Andriezen^"*
result of subsequent removal
and other authors
also refer to a steady decline of temperature.
Paulesco^“° noted that this decline was progressive until death
occurred.
ture.”
main symptoms are referand respiratory systems and the tempera-
Pirrone^®® states that the
able to the "vascular
The
relationship with the respiratory process
is
further
shown by the .marked disturbances of this class, dyspnoea, polypnoea, etc., noted by Cyon, Andriezen, Masay, and other experimenters.
The impairment of general metabolism through deficient oxygenation must necessarily inhibit nutrition. Practically all investigators refer to rapid emaciation
and cachexia as prominent
symptoms.
In a dog which survived si.xteen days’ removal of the organ, Thaon’®^ observed “a progressive emaciation, followed Herring: in..
Philos. Transactions, cxcix, p.
Sacchi: Arch. Iniy/®®®'® Masay: “I** Arch, de la Soc. part 3, p. 1, 1903.
Andriezen
:
1906.
29,
biol., p. 509, June 4, 1892. de biol., xxil, p. 123, 189,5. roy. de sci. mOd. et nat. do
ital.
Lor. elf. Jour, de physiol, et de path. g6n., No.
loopirronc: Riforma medlca, February ^‘‘^Thaon: L’Hypophyse, p. 90, 1907.
25,
1903.
3,
p.
Bru.xellcs,
441,
1907.
xil,
— FUNCTIONS AND DISEASES OF THE ADRENALS.
74
by death in extreme cachexia.”
Masay“®
Pirroiied"® and phenomenon. Fuehs'“ and many though obscure relationship be-
also allude to this
Caselli/®®
—
other authors urge the close
—
tween the pituitary and bodily metabolism.
Striking evidence
of the influence of the pituitary on .metabolism and nutrition
is
afforded by its role in gigantism and acromegaly, the excessive growth during the period of hyperplasia of the organ, and the
steady decline from the time degeneration of
A
begins.
relationship with the adrenals
is
its
anterior lobe
suggested, moreover,
by a familiar symptom of the cachectic stage of acromegaly, of which Harlow Brooks^*- saj-s: “A general brownish pigmentation
present in the average case, which at times strongly
is
resembles that found in Addison’s disease.”
Another feature attesting to the parallelism between the pituitary and the adrenals is that
The
pituitary,
adrenals,
the
like
influences
the
blood-
pressure.
Cyon^'® and subsequently Masay“^ found that excitation of
marked
the exposed pituitary caused a
from 81
to
200
mm. Hg.
rise of blood-pressure
Masay
in one instance.
attributed this
action to the presence in the organ of a secretion which the
and accompanying pressure forced into the circulation. While no one can assert today that such a secretion is not produced by the pituitary body, the actual existence of such a excitation
secretion or its functions has not so far been demonstrated.
The
substance considered as such
globin,
and
is
rich in albuminous basmo-
the adrenal principle
it is
it
contains which, in
my
opinion, causes the rise of blood-pressure obtained by injections
of the extract.
When
the pressure
is
marked, the kidneys, being
passively congested, dilate, and diuresis
is
caused.
Tbe
effects
observed experimentally are tbus accounted for without the need of a secretion to do so. several
so-called
This applies
“internal
orchitic extract, for instance,
108
Casein;
Studl anat.
also,
from
secretions.”
e sperim.
is
my
viewpoint, to
Testicular
juice
an oxidizing ferment and cata-
sulla flsio-pat.
della glandula pltuitaria,
1900. log pii-j-one:
no Masay: 1*1 Fuchs: 1*8
11*
Loc. cit. tor. rlt.
Wiener med. Woch., February 8, 1903. Harlow Brooks; Archives of Neurol, and Psychol.,
ii*Cyon:
Masay:
Arch, de physiol., Loc,
cit.
x,
p.
or
618,
1898.
I.
p.
435,
1898.
— 75
THE GOVERNING CENTER OF THE ADRENALS. lyzer; it is
male;
found in
all tissues,
in the female as well as in the
gives crystals of luBmin with Florence’s test, etc.,
it
and
other reactions peculiar to the adrenal and thyroid principles
both of which are also found in all tissues. A close examination of Masay’s report, moreover, does not sustain his opinion that the rise of blood-pressure
is
to be ascribed to a secretion
produced
The rise of pressure was instantaneous and which points either to vasoconstriction through nerves or to the action of some intensely active and evanescent Both these factors are available. Not only is the principle.
by the
pituitary.
general
—a
pituitary
fact
known
to be related
with the sympathetic system, but
Langley^^® has called attention to the remarkable fact that “the
produced by adrenalin ujion any tissue are such as follow excitation of the sympathetic nerve which supplies the tissue,” effects
a conclusion confirmed
fact
is
clearly explained
in the hasmoglobin.
by the presence of the adrenal principle
When Cyon and Masay
therefore, they merely caused
excited the pituitary,
sympathetic constriction of
arterioles, including their offshoots the vasa
of
vessels
all
(adrenoxidase)
This paradoxical
by several observers.
receiving an
excess
of
all
vasorum; the walls
albuminous haemoglobin
they contracted, thus causing a rise of blood-
pressure.
Again, as
is
well Imown, the adrenals ara intimately con-
nected with the abdominal ganglia and
sympathetic structures.
are,
embryologically,
Their vessels being likewise influenced,
a sudden excess of secretion furnished a second cause for the
ephemeral
rise of blood-pressure
observed by Masay.
of the adrenal secretion to cause such a rise nized.
effects
generally recog-
Schafer^^® characterizes as “astounding” the minuteness
the dose of adrenal
of
is
The power
;
extract that will excite physiological
5.7 millionths of a
gramme
of Abel’s epinephrin sulphate
body weight was found by Eeid Hunt“^ to cause a rise of blood-pressure of 66 ,mm. Hg. As to the action on the heart, Oliver and Schiifer^^® found, as is well known, that adrenal
to each kilo of
products not only acted directly on the muscular walls of bloodvessels, causing them to contract (which accounts for the rise of Langley: !
Hill s Recent Advances in Physiology, Textbook of Physiology, I, p. 957, 1898. Amer. Jour, of Physiol., v, p. 7, 1901. Oliver and Schafer: Jour, of Physiol., xvi, p. 1,
p.
58-1,
1906.
Reid Hunt:
1894;
xvii, p. 9, 1896.
FUNCTIONS AND DISEASES OF THE ADRENALS.
7(5
blood-pressure), but also
upon the muscular wall of the
Finally, the rise of pressure
adrenalin extract
itself,
heart.
undoubtedly produced by the for Strehl and Weiss”" found that is
clamping of the adrenal veins lowered the blood-pressure, while release of these vessels restored
Another suggestive parallelism
The
is
it
to its previous level.
fact attesting to the pituitaro-adrenal
that
pituitary, in beeping with the adrenals, gives rise to
glycosuria.
Adrenal extractives,
as
observed by Blum,”"
Metzger,^-- Herter, and others, cause glycosuria. secretion evidently provokes the
phenomenon
Croftan,^"^
The adrenal
also,
for Herter
and AVakeman^"® found that compression of the adrenals, by increasing the outflow of secretion into the adrenal veins, caused glycosuria, while, conversely, adrenalectomy
marked diminution
was followed by a
of the sugar in the blood.
Again, we have
seen that the adrenal secretion passes from the adrenal veins into
the inferior vena cava vessel
Kauffmann'-'* found that Avhen this great was ligated the sugar diminished rapidly, both in the blood
and in the
Now,
;
urine.
the influence of the pituitary over glycosuria
as marked.
]\1.
is
quite
Loeb”“ urged, over twenty years ago, that the
glycosuria which accompanies so often tumors of the pituitary
should not be ascribed to mere coincidence.
had
five
with this disease, 71 of
organ.
whom had
years earlier,”^ he ascribes this
of the pituitary,
In
Ifi
and
its
it
in
Borchardt”" tabulated
over one-half of his cases of acromegaly. 17() patients
Slarie observed
glycosuria; as I
symptom
to overactivity
cessation to final degeneration of this
reported cases studied by Launois and Boy'"® each
That the glvTcosuria is not due to pressure of the enlarged organ upon the basal or bulbar tissues is shown by the fact that it can be produced in a normal organ. Thus, F. W. Pavy”" found that, subject presented at the autojisy a
tumor
of the pituitary.
strehl and Weiss: PHUger’s Archly, Ixxxvl, p. 107, 1901. Dcut. Archly f. Med., Ixxl, Nos. 2 u. 3, p. 146, 1901. Croftan: American Medicine, January 18, 1902. Metzger: Miinch. med. Woch., xllx, p. 478, 1902. ’^Herter and IVakeman: Araer. Jour. Med. Sci., January, 1903.
’“Dlutn:
'2* Kauffmann: Arch, de physiol., yiil, p. 150, 1896. ’“Loeb: Centralbl. f. inn. Med., September 3, 1898.
Borchardt: Zeit. Sajous: Lor. pit.,
f.
Launois and Roy: '-“Payy: Proc. Royal
Med., Ixyi, No.
4, 1908. 1st edition, 1903. C. r. de la Soc. de blol., ly, p. 382, 1903. Soc. of London, x, p. 27, 1859.
1.
klin. p.
366,
THE GOVERNING CENTER OF THE ADRENALS. ‘'of all
77
the operations on the sympathetic of the dog that have
yet been performed, removal of the superior cervical ganglion tlie
This enig-
most rapidly and strongly produces diabetes.”
matic result finds
known,
explanation in the light of the conclusions I
its
The
have submitted:
superior
cervical
filaments
vasoconstrictor
supplies
ganglion,
as
pituitary;
the
to
removal of this ganglion by causing relaxation of
well-
is
its
arteries
causes the organ to
become hyperaemic and therefore overactive,
with glycosuria as a
result.
by the fact the
Control of this conclusion
is
afforded
that, as in all exacerbations of activity thus induced,
symptom was
shown by Pavy’s statement that
fleeting, as
the glycosuria was “only of a temporary nature.”
Having now ascertained
1,
that the pituitary could alone
be the source of impulses to the adrenals; 2, that this organ projected fibers toward the bulb, and, 3, that the pituitary and rise to similar experimental and clinical became a question 'whether a nerve-path actually united these organs. Study of this question showed that
the
adrenals
phenomena,
gave
it
The phenomena
pi'ovolied
hy both the p-ituitary and the
adrenals can he traced Uy irritation or sections along a continuous
path leading from the pituitary to the adrenals. The tuber cinereum, which, we have seen, receives
from the
fibers
backward toward the bulb. Puncand others not only raised the temperature and quickened the respiration, but a section below the same region by Sawadowsky’^® and Ott and ScotP®^ rendered impossible the production of fever by pituitary, extends
tures along the upper part of this path by Ott, Tangl,
agents
known
to produce
iri’itation of tlie
same
Caselli,*®-
it.
tissues
moreover, found that
produced glycosuria.
The nerve-path continuing downward, we meet
in
the
pontobulbar region the thermogenic center of Tscheschichin, Schreiber, and Eeichert.
Suggestive in this connection
is
the
Bruck and ,Gunther‘®® found that simple puncture with a probe between the pons and medulla not only caused a marked
fact that
rise of
temperature, but that this rise was general.
tory center
is
Sawadowski: Centralbl. f. d. med. Wissen., xxvi, pp. U5, Ott and Scott; Jour, of Exper. Med., November. 1907. Caselli
:
The
a familiar classic feature of the medulla
Lof.
161,
;
1888.
cit.
Bruck and GUnthcr:
Arch.
f.
d.
ges.
Physiol., Hi,
p.
578,
respira-
we have
1870.
FUNCTIONS AND DISEASES OF THE ADRENALS.
78
how
seen
all
the
phcuomeua evoked by
the adrenals are linked
M'ith the res 2 )iratory jirocess.
All this applies as well to Claude Bernard’s jnmcture in the same region as a cause of glycosuria,
and due in the light of all this evidence from the pituitary to the adrenals. In
the
upper
Tscheschichin,^*^
portion
Bernard,^““
of
the
and
to irritation of the path
spinal
down
various animals sent the temperature
division
by
respectively,
in
cord,
rochoy,^®“
7° to 16° C. in
from
four to twenty-four hours, death following in Pochoy’s animals.
found that production of heat was diminished. That glycosuria is produced through efferent fibers passing downward in the upper cord is shown by the well-known fact, mentioned BiegeP^'^
by Stewart,^^* that puncture of the bulb does not cause glycosuria if
“the spinal cord above the third or fourth dorsal vertebra be
cut before the puncture
This
level of the
is
made.”
cord
is
of special interest, since
Here
that the nerve-path to the adrenals leaves the spinal cord.
can be evoked a
due
to
rise of blood-pressure
vasomotor nerves.
occurring in excess of that
Thus, Frangois-Franck and Hallion^®*
obtained a rise of pressure by exciting the
and
also
here
it is
five
upper dorsal rami,
by stimulating the corresponding segment of the sympa-
thetic chain, although the vasoconstrictor nerves to the organ
studied, the liver,
was known to reach
lower ramus, the sixth
—a
organ through a
this
limit confirmed by Langley.^'*'*
But
they could not account for this phenomenon. Bulgak, Bunch,^*^ Jacobi,^"'- and others also obtained marked vasoconstrictor effects by e.xciting these upper rami, although the vasomotor nerves to the organs influenced were known to leave the cord- lower down.
In other words, a duplicate source of vasoconstriction, as it were, was present whose nature remained obscure. It was brought to light, however, by the fact that Jacobi*'*® found that excessive inhihitorij consirictwn of the intestinal vessels ceased, and was replaced by normal vasoconstriction
when he
Tscheschlchln: Arch. f. Anat., Physiol., Bernard: Lemons sur la chaleur animale, i5**Pochoy: Th^se de Paris, 1870.
IS*
5»TRiegel:
Archlv
f.
d.
severed the nerves
u. wissensch. p. 161, 1876.
Med.,
p.
Jacobi: Jacobi
I
Arch. Ibid.
f.
1866.
ges. Physiol., v. p. 629, 1872.
Manual of Physiology, p. -152, 1900. >»» Frangois-Franck and Hallion; Arch, de physiol., vlil. No. 5, ’"Langley; Sehafer's Textbook of Physiology. 11, p. 644, 1900. ’“Bunch: Jour, of Physiol., xxlv, p. 72, 1899. Stewart:
’*”
151,
exper.
Path. u. Pharmakol., xxix,
p.
lil,
p.
936, 1SJ6.
1892
— 79
THE GOVERNING CENTER OF THE ADRENALS.
The
to tlie adrenals.
blood-pressure
clearly
intense action ot their secretion on the
my
from
accounts,
the
for
viewpoint,
excessive constriction observed. Briefly, these facts indicate jointly that
The
pituitaro-adrenal path leaves the spinal cord through the
upper four or
five
rami, to enter the sympathetic chain, and
then the great splanchnic, which, through the intermediary of the
semilunar ganglia, supplies nerves to the adrenals.
That
this path is the true
Thus, Goltz and
one
is
shown by additional
spinal cord from the bulb do\vn could live a long time
even
—but
—years
that they showed a striking peculiarity, even after
their vessels cold.
data.
EwakV'*'* found that animals deprived of their
had resumed their normal
OtT'*“
dying of
caliber, that of
found, however, that the animals were able to
generate their usual heat fifth dorsal vertebra.
when the
This
is
section
was made
heloiv the
evidently because the pituitaro-
adrenal nerve-paths had left the cord above this level to pass over to the sympathetic chain and the splanchnic, for, although
had failed to increase the secretory activity of the adrenals by exciting electrically all the median and lower dorsal rami, both he and DreyeE^^ had succeeded in doing so by stimuBiedP'*”
lating the great splanchnic nerve.
Proof of this
is
aiforded
by the fact that the greater splanchnic also transmits the impula to the adrenals Avhich provokes glycosuria, for Laffont^'*® cause(
by stimulating
Moreover,
it is evidently through medulla that glycosuria is caused; for Eckhard, Kauffmann,^*® and others found that even the glycosurja caused by Bernard’s puncture ceased vdien the greater splanchnic. was severed. There can be no doubt that it is through the adrenals that the glycosuria is caused, for, besides
it
this nerve.
a nerve-path starting at least in the
the evidence I have already adduced to this effect, A. Mayer^®®
found that Bernard’s puncture failed to produce this symptom after removal of the adrenals.
On
the whole, all the evidence, of which the foregoing
part, seems to
me
to
have shown
is
:
Goltz and Ewald; Archiv f. d. ges. Physiol., 1x111, pp. Ott: Textbook of Physiology, p. 348, 1904. “"niedl: Arch. f. d. ges. Physiol., Ixvii, No. 9-10, p. 44.3, Dreyer: Amer. Jour, of Physiol., 11, p. 203, 1899. d'ted by Laulanld: Eldments de physiologic, 2d Kauffmann: C. r. de la Soc. de biol., p. 284, 1894. Mayer: Arch. gOn. de mCd., July 17, 1906.
362,
400,
1836.
1897. ed., p. 943, 1903.
a
80
FUNCTIONS AND DISEASES OF THE ADRENALS. 1 hal
1,
the
pilmUwy
direct nerve-paths ; 2, that
connected with the adrenals by
is it
thus yoverns, throuyh the adrenals,
general oxidation, inctaholism, and nutrition.
HYPOADRENIA. This designation
is
submitted as a more exact one than
now
the tenn “liypoadrenalism”
increasinglj’- used.
Uggesting to the uninitiated that the condition
ne of liabitual insufficiency of the adrenals the secretory activity of these organs
even where advanced lesions
and “adrenal
more acceptably the true condition
obviously cumbersome and as
ill
The
latter
describes
is
misleading, since
subject at all times,
is
The phrases
exist, to fluctuations.
“insufficiency of the adrenal”
tray
is
it
insufficiency” por-
present, but they are
calculated to designate this
condition from a scientific standpoint as would “deficiency of red corpuscles” for anemia.
While wo owe to Addison, a clinician, the first observations (1855) which indicated that the adrenals were of signal importance to the welfare of the organism,
it
was Brown-Sequard,
who (1856), we have seen, first demonstrated importance to life. The symptoms caused by a
a physiologist,
their
true
deficient
production of adrenal secretion Avere not, hou'ever,
erected to the rank of a special syndrome quite independent of,
and capable and as
disease,
of occurring Avithout tbe presence of, Addison’s a manifestation of other diseases, until Sergent
and Bernard*"' did so in 1899. YieAved from my standpoint, plex of this condition
is
hoAvever, the
symptom-com-
subject to quite a different interpreta-
tion than the prevailing one, all the labors anterior to
having taken
as
foundation only tAvo functions:
my
OAvn
that of sus-
taining the cardio-vascular tone (OlWer and Schafer), and that of producing an antitoxic substance capable of neutralizing toxic
products of muscular activity, and other undetermined poisons
(Abelous and Langlois). effects are
The
processes through AA’hich these
brought about having remained obscure, hoAvever, more
or less empirical conceptions have had to be employed to gaps.
Thus, the muscular asthenia in Addison’s disease
is
fill
the
attrib-
uted to the toxic effects of tbe muscular poisons that tbe adrenals Sergent and Bernard:
Archives
gfin.
do m^d., July,
1899.
81
HYPOADRENIA.
while, to explair. in their normal state should have destroyed, the bronzing, irritation of the sympathetic plexuses around
other
are indifferently attributed to the low blood-
symptoms
pressure or to the intoxication. tation
of
the
dyspnoea, and
The hypothermia,
adrenals has to be invoked.
If
we
ask, however, hoio irri-
sympathetic plexus produces bronzing, or why
after adrenalectomy the temperature, both rectal
and peripheral,
fathom to any depth the explanations that soon becomes apparent that some important
steadily declines, or
are furnished, it
factor
is
missing.
my
me
have supThey afford an explanation of all the symptoms brought plied. Being on by inadequate functional activity of the adrenals. submitted experimental data based primarily upon the array of
which
It is this factor
labors seem to
to
in the earlier portion of this chapter, they also
constitute a
foundation for a more exact conception of the various disorders of the adrenals than the prevailing teachings afford.
my
Another feature which
me
of the adrenals seems to a
special
chapter,
is
interpretation of the functions
to elucidate, as will be
shown in
the process through which these organs
carry on antitoxic functions other than those concerned with
muscular origin.
toxic wastes of
Albanese,^“-
who noted
frogs to neurine as
This property, observed by
a decreased resistance of decapsulated
compared
to
normal
frogs,
was
first
placed
on a solid footing by the researches of Abelous^’'^ and Langlois, which showed similar results with atropine in the frog, and strychnine and' curare in the rablnt, though less marked. Charrin
and
Langlois^®^
then
found
that
the
addition
of
adrenal extract to nicotine in vitro reduced the toxic activity of the latter,
when adrenal
and that injected nicotine was also extract was
added to
it.
less
poisonous
Oppenheim^^”^
then
obtained uncertain results with potassium arsenate and atropine, but
marked
results with phosphorus, guinea-pigs in
which
was followed by that of adrenal extract surviving from two to four times longer in some inthe injection
of
this
toxic
Albanese: Arch. Itallennes de Biol., pp. 49 and 338, 1892. Abelous; Rev. Gdndrale des Sciences, May 15, p. 273, 1893, and Bull, de la Soc. de Biol., April 2, 1898. Charrin and Langlois: Bull, de la Soc. de Biol., p. 708, 1896. Oppenheim: Bull, de la Soc. de Biol., March 22, 1901; also “Les Capsules Surrdnales. Leur fonction antltoxique,” Paris, 1902.
—
;
FUNCTIONS AND DISEASES OF TllE ADRENALS.
82
and altogether
Strychnine, Vgo whieh and four minutes, produced but few spasms and proved harmless as to life when its injection was followed a minute later by one of 2 e.c. of adrenal extract. A
staucos,
in others.
killed guinea-pigs in three
larger dose of strychnine
(V 48
grain)
proved
fatal,
however.
These and other experiments with various toxins led Oppen-
heim
conclude that “the adrenals, which normally destroy
to
poisons elaborated during muscular work, assume great impor-
tance during pathological states and must be classed
among
the
most useful of protective organs.”
On
the whole, in the light of the personal views submitted,
hypoadrenia or insufficiency of the adrenals means far more
than the
lowered blood-pressure and the adequate
of
effects
destruction of muscular wastes;
it
means
besides:
inadequate
oxidation and therefore imperfect tissue metabolism and nutri-
and
tion,
also
impairment of the auto-protective functions
of
the body at large.
The bearing
of this conclusion will be gradually developed
while analyzing the three clinical forms into which
—
divided hypoadrenia, essarj" to
a classification
whieh appears
to
I
have
me
nec-
enable us to apply prophylactic and remedial measures
These three forms are the following: Functional hypoadrenia, a form in which the adrenals,
judiciously. 1.
though not the
seat of organic lesions, are functionally deficient
because of tardy development, debilitating influences such as fatigue, starvation, etc., 2.
and old age;
Progressive hypoadrenia, or Addison’s disease, a form
in which the functions of the adrenals or of their secretory nerves are progressively impaired by organic lesions, tuberculosis,
cancer, fibrosis, etc. 3.
or less
Terminal hypoadrenia, a form which occurs as a more tardy complication of infectious diseases and toxemias,
owing to e.xhaustion of the secretory activity of the adrenals during the earlier and febrile stage of the causative disease.
FUNCTIONAL HYPOADRENIA. adrenals playing so important a role in the maintenance of the life process itself, it is obvious that, apart from any organic lesion in these organs, any marked depression of
The
83
FUNCTIONAL -HYPOADRENIA. their functional activity should manifest itself
To the name of
responding with this depression. this
have given the
condition I
by symptoms cor-
symptom-complex “functional
of
hypo-
from the forms due to destructive disorders of the adrenals, which constitute Addison’s disease, and offer, of course, a far graver prognosis. As a definition of tliis condition, I would submit that Functional hypoadrenia is the symptom-complex of deficient activity of the adrenals duo to inadequate development, adrenia” to distinguish
it
'
exhaustion hy fatigue, senile degeneration, or any other factor ivhich, without
nerve-paths,
provoking organic lesions in the organs or their
is
capable
of
reducing
their
secretory
activity.
Asthenia, sensitiveness to cold and cold extremities, hypoten-
weak cardiac action and pulse, anorexia, anannia, slow metabolism, constipation, and psychasthenia are the main symptoms of this condition. The field covered by functional hypoadrenia is necessarily a vast one, since it includes the asthenias so often met with in the four main stages of life: infancy, childhood, adult, and old age, usually attributed to “weakness” or “exhaustion,” and often “neurasthenia,” which have been traced to no tangible cause. All I can submit herein, therefore, is a cursory analysis
sion,
of the subject.
Functional Hypoadrenia of Infancy and Childhood.
—Although the adrenals third the
size
of
the
are relatively large in the infant (one-
kidney at birth), their functions are
limited to the carrying on of the vital process, at least during tlie first
year of
life,
the mother’s milk supplying the antitoxic
products capable of protecting
it
against the destructive action
of poisons of endogenous and exogenous origin. influence of maternal milk
is
This protective
clearly defined in the following
quotation from Prof. William Welch’s
Harvey Lecture: “It is an important function of the mother to transfer to the suckling, through her milk, immunizing bodies, and the infant’s stomach has the capacity, which ing these substances in active
is
state.
afterward
Tbe
lost,
of absorb-
relative richness of
suckling’s blood in protective antibodies as contrasted with the artificially fed infant explains the greater freedom of the tlie
former from infectious diseases.” 0
Striking proof of this
is
FUNCTIONS AND DISEASES OF THE ADRENALS.
84 afforded
fact that during the siege of I’aris
l)y tlie
according to
-I.
1870-71,
in.
E. Winters,*”® “while the general mortality was
doubled, that of infants was lowered 40
jDer
owing to
eent.
mothers being driven to suckle their infants.”
The
predilection of children to certain infectious diseases
obviously indicates that
it is
not only in infancy that vulner-
ability to these disorders e.xists;
exposes life during the
it
decade, and more, of the child’s existence.
If,
first
then, in the
infant the maternal milk, as Welch says, protects the suckling
we must
against such diseases, at least to a c-onsiderable extent,
conclude that the same underlying cause of ^^llne^ability persists several j'ears, i.e., until it
How
this
we have
occurs
we
other organs,
has in some
The
seen.
shall see, the
power
way been overcome.
adrenals acquire, with
to supplant the
mother in
contributing antitoxic bodies to the blood; they supply internal
which fulfill this role. These facts point to the adrenals as at least prominent organs among those whose inadequate development explain the
secretions
special
\mlnerability
of
children
certain
to
the
infections,
It becomes a question now whether there are degrees of this hypoadrenia which render the child more
“children’s diseases.”
or less liable to infection.
That degrees
of hypoadrenia exist in children
a familiar fact to every physician
when
is
in reality
the signs of this con-
dition are placed before him. The ruddy, warm, hard-muscled, heavy, out-of-door, romping child with keen appetite and normal functions, is one in, whom the adrenals are as active as the
development commensurate with
its
age will permit.
ruddy and warm because oxidation and
He
is
metabolism are perfeet
and' the blood-pressure sufficiently high to keep the peripheral tissues well filled
with blood
;
his muscles, skeletal, cardiac,
and
vascular, are strong because, in addition to being well nour-
they are exercised and well supplied with the adrenalsecretion, which, as shown by Oliver and Schafer, sustains musished,
cular tone.
As normal outcome
of this state,
we have
constant
The stimulation of the functional activity of the adrenals. muscular exercise and maximum food intake involve a demand for
increased Winters:
metabolism
and
oxidation,
"Practical Infant Feeding,”
p.
6.
and the resulting
— 85
FUNCTIONAL HYPOADRENIA.
pargreater output of -wastes imposes upon the adrenals, as greater ticipants in the oxidation and auto-protective processes,
work, more active growth and development, with increase of defensive efficiency as normal result.. The pale, emaciated, or pasty child with cold hands feet, flabby
the
muscles, whose appetite
pampered house-plant
so
is
often
and
capricious or deficient
met among the
rich
rejiresents the converse of the healthful child described, just as The does the ill-fed, perhaps overworked child of the slums.
the cold extremities,
emaciation,
deficient
indicate
oxidation,
metabolism and nutrition owing to the torpor of the adrenal functions; the pallor is mainly due to a deficiency of the adrenal principle in the blood and to the resulting low bloodpressure,
which
This child
face.
is
not
ill,
abnormally low, and all
it is
adrenals,
its
is
conditions which in the adult tend to produce
self-evident.
FunctioNxIl Hypox\.deenia in the Adult.
circulation
show other signs of hypoadrenia.
As
I have witnessed suggestive
a rule, however, the development
—
an accomplished fact
of the adrenals in adults
is
of their coworkers in the
immunizing
we
oxidation
—
As in the do Such subjects may hypotbyroidia, show signs of myxoedema; but their and heart action are feeble, they tend to adiposis, and
bronze spots in such cases.
pituitaiy,
same
be inherently weak.
child, the adrenals
not, as in
is
TOlnerable to infection.
functional hypoadrenia affect the child at least to the extent
sur-
but the h}'poadrenia which prevails
normally, owing to the undeveloped state of
That
from the
entails retrocession of the blood
shall see.
The
as also that
process, the thyroid
and
adrenals, fully capable of sustaining
and metabolism, are able to defend tbe organism
adequately; indeed, they do more: by sustaining oxidation and
metabolism up to
its
highest standard in
all
organs, they also
preserve the efficiency of all other defensive resources, including phagocytosis, with which the body level.
On
is
endowed to
their highest
the whole, the normal adult whose adrenals func-
tionate normally is relatively resistant to infection. The infrequency with which the physician is infected, notwithstanding
daily exposure in his professional work, attests to this fact.
Functional hypoadrenia appears, however, when, irrespective
FUNCTIONS AND DISEASE'S OF THE ADRENALS.
8 () of
disease,
ail}'
the
ence,
ami
as a result of tlie vicissitudes of our exist-
adrenals
are
exhausted by the excessive
Fatigue
is
a
prominent factor in
ergograph shows clearly the functional If by
means of
this
secretory
upon them.
activity that exaggerated labor or exercise imposes
Mosso’s
this connection.
efficiency of the forearm.
instrument we compare the muscular power
of a case of Addison’s disease with that of any other kind of sufferer
whose muscles are organically normal,
ference will be noticed
;
muscular impotence asserts tuberculosis,
for
striking dif-
itself
and
where an advanced case of able to show appreciable
example, will be
Intense asthenia
strength.
a
signs of fatigue appear very soon,
symptom
in fact, a
is,
of Addison’s
disease almost as characteristic as the bronze spots.
It is as
pre-eminent after experimental removal of both adrenals.
harmonizes with Oliver and
This
demonstration of the
Schafer’s
influence of the adrenal secretion over muscular tone.
other proofs could be adduced to show that there
is
Many a close
and the functions of the adrenals. The pale and drawn face of an exhausted man, the readiness with which he suffers from the effects of cold and exposure,
relationship between fatigue
especially in the intestines, are familiar features of daily
The unusual prevalence field is of
campaign
life.
soldiers in the
course partly due to the defective sanitation that a
—
entails; but fatigue
particularly that due to heavy
marching, carrying heavy accoutrements important predisposing cause, through
Not only
adrenals.
among
of disease
—
in
is,
its
my
opinion, an
influence
are these organs called
upon
upon the to
sustain
general oxidation and metabolism at a rate exceeding by far that which amply suffices for nonnal avocations, but the fact that, as
destroy
shown by Abelous and the
toxic
products
of
Langlois,’®'^ they also sen*e to
muscular activity
constitutes
another cause of drain upon their secretory resources. “Fatigue,” write Morat and Doyon,^®® referring to experimental fatigue in
animals deprived of their adrenals, “has an aggravating influence, as first indicated by Abelous and Langlois, and confirmed by Albanese and
all
authors.
Hultgrcn and Andersson have even
Abelous and Langlois; Loc. rit. iM Moral and Dovon: "Traite de Physlologle, p.
441,
1904.
’
Art.
Secretions Internes,
„
;
87
FUNCTIONAL HYPOADRENIA.
observed sudden death as a result of powerful movements of the body.” Debility from any source as efficiently renders the
starvation, loss of blood, etp.,
:
body vulnerable to disease:
“Combine
Prof. and antitoxin, and inject “no haim will follow. But weaken the animal by Charrin starvation or slight bleeding and administer the same injection death will follow with all the signs of poisoning by the toxin,
the mixture,”
toxin
with congested adrenals.”
.
.
.
“That
writes
relations
exist
be-
tween the adrenals and infection,” urges the same authority, “is It follows, therefore, that an incontrovertible fact.” hypoadrenia from any source should render the body vulnerable Deficient food, excessive work, that of the sweatto disease. shops for example, account for much of the predilection of our
today
slums’ inhabitants to disease, their filth nurturing the appropriate
germs.
Masturbation and excessive venery are important morbid factors in this connection.
The
and asthenia witnessed
pallor
in these cases, so far unexplained, can readily be accounted for if,
as I believe, the liquid portion of the
This
principle.
is
as does the adrenal principle.
absolute
alcohol,
is
hffimin tests.
;
The
same
and
acts precisely
an oxidizing body
in ether
Xow, speimin not only and produces
all
raises the blood-pressure,
other
peculiar to the adrenal principles, but
same ;
tests
latter is
temperatures up
it resists all
insoluble
slows the heart
rich in adrenal
to, and even, and practically insoluble in and gives the guaiac, Florence, and other
acting catalytically it
is
suggested by the fact that spermin, the purest
of testicular preparations, gives the
boiling;
semen
its
physiological
effects
solubilities are the
same tests it resists boiling. Moreover, it is regarded in Europe as a powerful “oxidizing tonic” and has been found equally useful in disorders in which adrenal preparations had given good results. The inference that spermin consists mainly of the adrenal product suggests that it should it
gives the
not be regarded
;
af?
specific to
the testes, but, instead, a con-
stituent of the l)lood at large; not only did this prove to be the case,
but
it
was found
in the blood of females as well as in that
of males. ic®Charrin:
“Les Defenses Naturelles de rOrganisme,”
p. 63, Paris, 1898.
FUNCTIONS AND DISEASES OF THE ADRENALS.
88
Functional Hypoadrenia of Old Age.
— Perpetual
life
would doubtless be ours were it not that all living organic matter is subjected, after more or less precarious periods of growth and adult existence, to one of decline and final disintegration.
This applies particularly to the adrenals,
if
their
functions are, as I hold, to sustain oxidation and metabolism,
fundamental processes of the living
the
senile state is
may
state.
Indeed, the
be said to be as evident in these organs as
it
in the features of the aged.
According to Landau,'*“* Ecker, Henie, and von Kblliker found that fat occurred in increasing quantities in the adrenal cortex as age advanced, while Hultgren and Andersson found fibrous tissue between the cortex and medulla in Very old animals. Minervini'"‘ found a similar condition in the medulla of aged individuals.
—
Dostojewski, moreover, observed a marked
occasionally very great
Landau studied the adrenals,
—reduction
in the size of the adrenals
Polleston*®- has also called attention to this fact.
in the aged.
influence
of
age on
the
vessels
of
the
adopting for the purpose a process introduced by
Pauber and applied by many others, including Bezold, Hyrtl, and Lieberkiihn, to the study of other organs, viz., injection of the vessels with some hardening substance, and the subsequent The use of a corrosion method to destroy the parenchyma. adrenals
receiving, their
blood
through
a
number
of
small
which contains no valves, was used The annexed plate shows the result. The for the injection. vessels, and therefore the adrenals, are w'ell developed and in arteries, the adrenal vein,
were, in the adrenals of the three young adults, while those of the aged are shrunken and correspondingly defia certain index of the lowered activity cient as blood-channels full
bloom, as
it
—
of the adrenal functions, and, through these, of the vital process
they sustain. asthenia of old age thus finds a normal explanation in precisely as it does defective supply of adrenal secretion
The
the
—
in Addison’s disease.
the glands in the ’“Landau: ’“Lorand:
fact, Polleston states that
young may produce
this disease.
atrophy of
Lorand,^®^ in
Pctcrsb. med. Woch., .lunp 14, 1908. Jour, d'annt. et de physiol., pp. 449 and 8u9, 1904. Lancet, Mar. 2,1, 1895. ‘‘Old Age Deferred," Am. cd., p. Ill, URI.
St
”” Mlncrvini; Rollcston:
In
THE ADRENAL RESSELS IN THE YDHNG- AND 1,
Man
S2 years
22 years
old,
4,
old,
2,
Woman
Man BU years
33 years
old.
S,
Woman
LLD,
3, Pregnant woman B2 years old, (Landau.)
old,
— 89
FUNCTIONAL HYPOADRBNIA. liis
recently published book
on old
age, urges in fact that
old
ductless glands, and t a caused by degeneration of the quite autointoxication in old age there exists a condition of power with a decline of the antitoxic in keeping, I may add, in others Ixirand, who has antedated shoMTi hy the adrenals. glands upon old age, has showincr the influence of the ductless Pineles, Sir Herman found his views confirmed by Campbell,-relationship between old Weber and also—tbough he denies a a succeedWe shall see age and myxcedema— Metchnikoff. a close connection between ing chapter, however, that there exists genesis of old age, in the the adrenals and the thyroid in the acre is
m
form
of a functional relationship.
remarks on the causation of old age, Loranc considerations that all remarks; “It is evident from the above any kind of excess, hygienic errors, be they errors of diet or and that premature old will bring about tbeir own punishment, In fact it is mainly life, will be the result.
In
his closing
age, or a shortened
and die before our fault if we become senile at 60 or 70, page: 90 or 100.” Hence the motto of his title
“Man He
does not die,
kills himself.”
—Seneca.
however, it is In the light of the data I have submitted, subjected during clear that the lesions to which the adrenals are
and autointoxication, from birth to the last day of fimctional area of life, do greatly to shorten it by limiting the It is quite the organs through the local fibrosis they entail. probable, in fact, that centenarians owe their prolonged longevity
infections
mainly to integrity of their adrenals. Hygiene, and particularly those of directly itself as
its divisions
which bear
upon the prevention of infectious diseases, thus asserts direcone of the most useful of our sciences in another
organism against those diseases which, seemingly benign because they are recovered from, measles for example, in the end shorten our existence by compromising
tion, viz., that of preserving of
the integrity of the organs which sustain the vital process itself. PnoPTiTLAxiR AND TREATMENT. Though we are dealing
—
with depraved states of a physiological condition, we cannot JO*
Campbell:
Lancet, July, 1905,
FUNCTIONS AND DISEASES OF THE ADRENALS.
90
but regard them as abnormal in the sense that we deem adynamia abnormal and, therefore, susceptible to remedial measures. Indeed, there is mueh that can be done in each of the three
forms of functional hypoadrenia described. In
infants,
or
infection
adrenals and
we should by every
intoxication
to
other auto-protective
whole situation
lies in
possible
preserve
the
means prevent
integrity
of
The key
organs.
the
the fact that, as Ruhriih states, “nearly
the cases and nearly
all
all
the deaths are in bottle-fed babies.”
Physicians are, as a rule, entirely too ready to yield
demands
their
of
to‘ the'
of social and other claims put forth by mothers
who
do not wish to nurse their offsprings.
The responsibility assumed by both mother and physician under these circumstances is
I cannot but hope that if this continues,
overlooked.
sacrifice of countless infants proceeds, laws
may
and the
be enacted to
by imposing upon the physician the duty of submitting
prevent
it
to the
State authorities a certificate in M'hich sound reasons
from Nature’s Lewis Smith states
shall alone account for his consent to a departure
methods Avhich
entails deaths untold.
that the death rate
among foundlings
J.
in
New York
City reached
almost 100 per cent, until wet-nurses were provided. ]\Ien such as Jacobi, Winters, and many French authorities have written
upon
forcibly
this subject,
but seemingly to no
avail.
The
holo-
caust continues.
Experimental research in the same direction has only served to emphasize the all-importent prophylactic value of maternal
milk.
As
L. T. de
M.
Sajous^®® states
:
“That milk
is
capable
of conveying antitoxic substances after these have been injected into the
mother has been known for
a
number
of years.
In
1892 Ehrlich and Brieger demonstrated this fact in their experiments on mice. The offspring of non-iiumune mice were suckled
by other mice which had been immunized against the actions of certain poisons. It was found that the young were thereby rendered immune to the poisons employed, viz., ricin, abrin, and Tins im.munity steadily increased during the period of lactation, persisted for some time after, and then Ehrlich thus showed that a passive gradually disappeared. immunity was created in the young hy the absorption of milk tetanus toxin.
1“L.
T. da M. Sajous:
Univ. of Peuua. Med. Bull., June,
1909.
FUNCTIONAL HYPOADRENIA.
91
from an immune adult^ and even went so far as to assert that all so-called hereditary immunity was in reality of the passive variet}"^, being transmitted during lactation and not inherent in the offspring
itself.
“This transmitted immunity has been shown to occur in Thus, in 1893, Popoff showed that various other animals.
immunity against cholera could be transmitted through cows’ milk.
He
injected bouillon cultures into the peritoneal cavity
from 2 to 10 c.c. The guinea-pigs became immime against of the cow’s milk. The same observer noted also that when the milk cholera. was boiled before injecting it no immunity was produced. Kraus showed that the milk of goats immunized by injections of “t}'phus-coli bacilli” and cholera organisms had protective and agglutinating properties. He also ascertained that the relative proportion of agglutinating substance present in milk of a
cow and
later injected into guinea-pigs
Taking to that contained in tlie serum was as 1 is to 10. up the subject from the standpoint of tuberculosis, Figari showed in 1905 that the agglutinins and antitoxins of this disease appeared in the milk of cows and goats that had been actively immunized against it. In another series of experiments he fed the milk of immune cows to a number of rabbits, and in others injected it subcutaneously. In both cases these animals, thus passively immunized, were found to transmit to their young, by their milk, the agglutinins and antitoxins of tuberculosis.
“Evidence
is
not lacking of the transmission of antitoxic
substances through
human
milk.
It
has long been
known
that infants below one year of age were but slightly susceptible
and in particular scarlet fever, diphtheria, measles, and mumps. In fact, it was in an attempt to throw some light on this subject that Ehrlich performed his classic experiments on mice in 1893. Four years later Schmid and Pflanz performed some interesting experiments on guinea-pigs. Into some of the animals they injected bloodserum derived from human blood which was taken, at the to certain infectious diseases,
time of delivery of her child, from a woman to whom had been administered dipbtheria antitoxin. Into other guinea-pigs thej'’ injected milk from the same woman. The animals were then
FUNCTIONS AND DISEASES OF THE ADRENALS.
92
given injections of the
From
toxin.
ordinarily
fatal -dose
diphtheria
of
the results obtained the investigators concluded
that antitoxic substances found in the blood of parturient
(1)
women
milk; (2) that the quantity of antitoxic substances excreted with the milk is much less than that found exist also in the
Similarly, in 1905, la Torre injected diphtheria
in the blood.
antitoxin in several wet-nurses, and noted the antitoxic power resulting in the blood of the nurslings by injecting measured
amounts of pigs.
He
this blood Avas
mixed with diphtheria toxin
able to satisfy himself
antibodies occurred
in small
into guinea-
that a passage of the
amounts into the blood
the
of
infants.
“These experiments show, then, that antibodies injected This being into the mother are transmitted to the offspring. protective of the the case, it is but reasonable to expect that some substances ordinarily present in the normal mother’s blood should likewise reach the child through tlie milk. Experiments have shoAvn this also to occur. ]\toro found that the bactericidal power of the blood-serum in breast-fed cbildren Avas distinctly greater than in those artificially fed. Further confirmation Avas afforded by the fact that this difference rapidly disappeared
Avhen the bottle-fed infants Avere put back to the breast.” The prevention of disease in the infant is raised to
its
Tlie organisms of its highest standard by maternal lactation. gastrointestinal canal are kept under control ; the barriers to
infection that the respiratory tract and
are
AA^ell
armed
Avith antitoxic bodies; the
pulmonary blood
ive to pathogenic organisms, and the infant
against those diseases Avhich, CA'en seen, leaA'e enfeebling lesions, fatty
those organs upon
AAdiich his
if
alveoli offer
itself is destructis
thus protected
recoA'ered from, Ave
and
have
fibrous degeneration, in
health in after years and the dura-
tion of his life depend. is In the child beyond the nursling period the problem more difficult. Tlie fatal “second summer” recalls the sins of
and of the vessels in enough which the milk is transported and kept— amply long virulent the bacillus, to favor the groAvth of the oft-present Shiga the milkman, the
bacillus
c-oli,
filth
of the cowshed,
and even at times the streptococcus.
rection of these
and many
The
cor-
other factors replete Avith danger
93
FUNCTIONAL HYPOADRBNIA. to
and which surround
the child,
on
it
offers
sides,
all
the
children s only resources to diminish not only the mortality of health diseases, but also their occurrence, besides safeguard. ng
and longevity in after years. profession in this direction
is
already done by our
The good
incalculable.
Briefly, public,
home,
school hygiene, in the light of the facts I have submitted,
and
not only serves to protect concerned, but
its
enhancing greatly It
life
for the
moment when
the child
is
entire career as a healthful individual, while its
chances for a long
life.
question whether our resources are such
now becomes a
where functional hypoadrenia
as to enable us to raise,
e.xists,
the
autoprotective resources of the child, sufficiently, perhaps, to
enable
The
infection successfully.
it to resist
influence of
many
toxins and drugs on the adrenals points clearly to overactivity under their influence. In the first edition of this book, I referred to mercury as occupying “a high position among the stimulants Now, C. R. Illingworth^'’^® and others of the adrenal system.”
have found the binioclide of mercury e.xtremely
efficient
in
aborting scarlatina, diphtheria, measles, variola, varicella, per-
and many other
tussis, parotitis,
of calomel
found
its
among
The
infections.
great vogue
the physicians of the past generation
raison d’Ure precisely in just such
have myself observed.
Arsenic
is
an action
may have
—which
I
a familiar agent in the abortive
treatment of malaria in Africa, and, as Surgeon-General Boudin states, in
many
The remarkable results of Petresco infusion of digitalis in pneumonia have explained. But if ive realize that division
other diseases.
with large doses of only been tentatively
of the path to the adrenals arrests digitalis, as
we
and prevents the effects of good ground for the
shall see elsewhere, there is
belief that the prevailing conception of the action of this is
erroneous, and that
acts, at least in part.
adrenals, therefore, in this infectious
drug by stimulating the adrenals that it In view of the immunizing action of the it is
we can
realize
how
and how
digitalis could be of use
might prove useful in aborting any pulmonary disorder due to pathogenic organisms. disease,
it
Tliese few examples are submitted merely to
show that there is ground for the elaboration of a system of immunizing medication.
Its use
has served
‘"“Illingworth; etc.,
London,
1888.
me
well.
“The Abortive Treatment
of
Specific
Febrile
Disorders,”
FUNCTIONS AND DISEASES OF THE ADRENALS.
94
‘
Very remarkable in this connection is tlie action of thyroid 1 grain (0.06 Gm.), adrenal gland 2 grains (0.12 Gin.), and Bland’s pill 1 grain (0.06 Gm.) in a capsule three times
gland
daily, previously referred to.
tated child of 10 or 12 years
machinery on a new
it
Given during meals to a debiliseems promptly to start the vital
lease of life
—where,
of hygiene are adequately met.
milk,
Meat
demands
of course, the
of value here, while
is
portion of which gives the test for oxidase, and
tile fluid
which, as shown in the second volume, depends upon the adrenal secretion for
its
ferment (adrenoxidase),
Digitalin or strychnine in small doses
weak
or to increase the oxygen intake.
also of great value.
is
added
is
if
the heart
is
All these agents tend, by
keeping up a slight hyperaemia of the adrenals (and of the other organs acting in conjunction with it), to augment the efficiency of the child’s defensive resources.
may
In the adult functional hypoadrenia
from childhood.
persisted
hax'e
Here the measures just suggested for children
apply as well not only as preventives where infection threatens, or as abortive treatment, but also to raise the efficiency of the
adrenals and the general health of the individual to the normal plane.
It
is
probable that most tonics exert their beneficial
influence through the adrenals. t'.e.,
it
minute
is
That “tonic” doses of mercurv, known; we have seen that
doses, are efficient is well
a powerful adrenal stimulant.
observed by Molinie,’'’^
it
In toxic doses in
fact, as
causes intense congestion and even
luemorrhage of the adrenals. AVhile there is no doubt that meat in e.xcess is harmful, as we shall see under Functional Hyperadrenia, it is no doubt true that,
through lack of the
as Ixirand'®* states, undernutrition
necessar)^ proteids in the diet increases the liability to infection,
Lorand
as I urged several years ago in this work.
refers
to
personal cases of tuberculosis arising from a purely vegetarian diet.
On
the other
hand, Eichet and
remarkable effects from a diet of
Hcricourt'®* obtained
raw meat
in enabling
to resist tubercle infection by inoculation, and
become an impoi'tant factor
’“^Molinifi:
in
7,
1911.
raw meat has
the treatment of this disease.
Bulletin gfiifral de tU6rapeutlque. Apr.
‘•^Lorand: Lo(\ Hf., p. 313. Lancet, Jan. H6ricourt:
animals
8,
1906.
95
FUNCTIONAL HYPOADRENIA.
predisposed Grawitz'"® also found tlmt a purely vegetarian diet We have seen that tlie adrenals supply the blood its to anieinia.
an important Did we live where pathogenic bacteria do feature of anaemia. not flourish, we might safely undertake to adopt vegetarian principles; but a reasonable amount of meat, by keeping our albuminous haemoglobin, a
organs,
autoprotective
deficiency, of
which
is
and particularly the adrenals,
active,
serves a very useful purpose.
influence of excessive fatigue on the adrenals,
The
seen, is such as to
weaken
we have
greatly their functional activity and,
and immunizing functions of the feature in this connection is the harmful The main deficiency of rest, which means, from my viewpoint,
therefore, their oxygenizing
blood. relative
inadequate
opportunity
afforded
the
adrenals
to
recuperate.
amount
This, of course, should be proportionate to the
of strain
imposed upon these organs, and the resistance of which they are capable. It is probably owing to lack of this that apparently strong men are often the first to “give out” in forced marches.
The
upon the status (for we are now
physical examination being based mainly
preesens,
and the adrenals being necessarily
dealing with a
new
line of thought) overlooked as factors, there
marked inequality
men
to strain.
This
applies as well to the pathogenesis of chronic disorders.
In a
is
in the resistance of the
personal analysis of 40 cases of hay fever, for instance, the severity of the disease
corresponded to a considerable degree
with the number of children’s diseases the patient had had, the worst cases having had six of these diseases in comparatively quick succession.
This suggests the need of ascertaining the number and severity of children’s
and other
diseases to
which the recruit has
been subjected and to add this factor to others in deciding upon
arm to which he is to be The mounted man suflFers less from actual fatigue than the infantryman who must carry his accoutrements, arms, cartridges, etc., aggregating in some armies as much as 70 his admission to the service or the
assigned.
pounds.
When,
exposure,
etc.,
”“Grawitz:
impure water, and other frequent accompaniments of a campaign besides, defective or poor food,
Klinische Pathologie des Blutes, 3d
ed.,
1906.
FUNCTIONS AND DISEASES OP THE ADRENALS.
9 ()
are taken into account, one need not wonder that disease
is
a
far greater factor as a cause of debility and death than wounds.
owing to its inhibiting immunizing process in which
Briefly, fatigue should be considered,
influence on the adrenals and the
they take part, as an important predisposing cause of disease.
The
periods of
rest
should be so adjusted, therefore, as to
counteract this by far the most destructive factor of active war-
In
fare.
civil
here likewise
life,
much
such hardships are seldom endured, but
could be done to prevent infection
liy
means
calculated to insure the functional integrity of the adrenals.
To
when marked fatigue would of course only aggravate the hypoadrenia after The powdered perhaps a period of temporary betterment. adrenal substance should, on the other hand, judging from the stimulate the adrenal functions
prevails
effects
of
injections
of
adrenal
experimentally
in
e.xtracts
fatigued animals, serve a useful purpose.
In old age the ductless glands assume such importance, that a valuable work has been written by Lorand‘^‘ to indicate
how
the functional activity of these organs could be preserved
in order to retard the ravages of age beyond the fifth decade,
while prolonging Ijorand’s
The
life.
reader
is
therefore referred to Dr.
volume for a mass of information which cannot be
considered here.
The
adrenals, as
shown by the
plate opposite page 88, are
deficient in circulatory activity, and, therefore, unable to sustain
functional activity of
all
organs -up to
becomes a question whether, realizing artificial
means
fonner standard.
In the
first
life
It
we should by That activity.
this fact,
excite the adrenals to greater
such a step might shorten probable.
its
instead
of
prolonging
it
is
place, the frequent presence of arterio-
aged counsels prudence; in the second place, to activate the adrenals would only hasten their degeneration by imposing a greater wear and tear upon them. Drugs capable of
sclerosis in the
enhancing adrenal activity had, therefore, better be avoided in the aged.
Far better is it to compensate for the loss of efficiency of the adrenals by supplying to the blood, through a suitable diet, substances which contain the adrenal principle. If my opinion A. Lorand:
“Old Age Deferred,” F. A. Davis
Co.,
Phila., 1910.
97
ADDISON’S DISEASE. that spcriiiin owes is
its
virtues to
tlie
warranted we can understand why
adrenal principle
it
contains
Brown-Sequard rejuvenated
himself by means of testicular juice injections (I saw liim at the time and can testify to its wonderful effects upon him), since
he enriched his blood with the iMhulwn of oxidation, metabolism, and general nutrition, without impairing his adrenals. With
We
advanced knowledge we need not follow his example. seen that milk contains the adrenal principle, and that
owe
tissues
their,
functional activity to
buttermilk especially (since
presence.
its
almost pure plasma),
it is
a ready and inexpensive means to
have
animal
all
In milk, we have
compensate for deficient
adrenal activity.' If debility and other signs of functional hypoadrenia prevail, I advocate the daily addition to the plain,
though varied diet to wliich
elderly
should
people
restrict
themselves of the expressed juice (uncooked) of one pound of fresh beef daily taken in salted to taste.
This
is
soup,
if
distasteful
otherwise,
and
a powerful agent for good which
is
by the stomach, and which more than compensates for it rapidly restores strength and vigor provided, of course, harmful influences in other directions are avoided, and a hygienic mode of life, with reasonable out-of-
well borne
the weakened adrenals, since
—
door exercise, prevails.
In matters sexual, aged
men
should be extremely reserved,
since the waste of seminal fluid to
them means waste
of life
substance replaced with difficulty and never in abundance.
ADDISON’S DISEASE, OR CHRONIC PROGRESSIVE
HYPOADRENIA. That new
lines of thought concerning this disease are not suggested by Anders’s previously quoted statement in a recent edition of liis textbook that “the pathologic connection between the symptomatic phenomena ofAddison’s disease and the anatomic lesions has not been made out.”
untimely
is
Of major importance in this conneetioii are the facts that advanced lesions have been found in the adrenals post-mortem, though the subject had during life presented no signs of the Addison syndrome, and that, as Davis”states, “in the majority of eases the patients have compkined of asthenia for a considerDavis:
Sajous’s Cyclopaedia of Prac. Med., vol.
i,
p.
133.
3d ed., 1900.
FUNCTIONS AND DISEASES OP THE ADRENALS.
9y
—the
the right and left lymphatic ducts
thoracic duct, according to Pembrey®®
—
into the subclavian veins,
and by way of the superior vena cava to the heart. Here they become merged with the venous blood of the entire organism, forming a single secreiion, which is then inevitably carried to the heart, and thence to the lungs. As the venous blood carrying the adrenal secretion passes from below to these organs to be oxygenized, so
above to the
is
the thyroparathjToid secretion carried from
air-cells.
All these facts tend to controvert the current view that the
The
thyroid and parathyroids are not functionally related. is
that the prevailing opinion, referred to on p. 147,
on a broad view sustains
of the evidence in the case.
l\Iy
fact
not based
is
own conception
and completes that of Gley, which admits a functional
association in the sense that one set of organs seiwes to complete
the
work of the
observation of
other.
This intimate connection
Edmunds
that,
is
shown by the
while extirpation of the para-
thyroids causes histological changes in the thyroid, removal of the latter also causes degeneration of the parathyroids.
^lore-
and Generali®® found that after death from removal no colloid. Lusena®' noted the same fact, thus showing that the formation of the thyroid secretion depends in some way upon the functions of the paraEdmunds emphasized this fact by shoAving that thyroids. over, Vassale
of the latter the thyroid contained
hypertrophy of the thyroid followed parathyroidectomy, both embryonic tissue and vessels showing development. This survival kiln. Woch., Bd. xxv, S. 954, 1888. Virchow’s Archiv, Bd. cxxxvl, S. 170, 1894. “Vassale and de Brazza: Arch. ital. di blol., vol. xxiil, p. 292, 1895. “Welsh: Jour, of Anat. and Physiol., Apr., 1898. « Capobianco and Mazziato: Giorn. Int. de Scl., Nos. 8. 9, and 10, 1899. “Pembrey: Hill’s ’’Recent Advances In Physiology." p. 579. “Vassale and Generali: Riv. dl Patol. Nerv. et Ment., vol. 1, pp. 95 and
“Biondl:
Berl.
Zielinska:
Lusena:
Fislo-patologla
dcll’Appar.
Tlro-parat.
Florence.
1899.
— thyroparathyroid secretion as oxidation activator. suggests that removal of the parathyroids
is
159
not as fatal as
Indeed, Gley-'® had two dogs survive removal of the thyroid; the of all the parathyroids leaving only one lobe same operation in two other dogs and in a cat was followed
generally believed.
by disturbances which became fatal on removing tlie remaining In another dog parathyroidectomy caused only thyroid lobe. trophic disturbances and death in one month. The same thing was observed in rabbits when two parathyroids only were left. sinwivals in dogs after parathyroidec-
Edmunds-'’'' also
had two
tomy and deems
this operation less grave
opinion which
also Gley’s.
is
than thyroidectomy, an
Again, Halpenny,'“’ after a comprehensive series of experiments in the same direction, writes: ‘T have been unable to confirm the statement that complete parathyroidectomy invariaIn dogs 3 and 7, bly proves fatal, and that in a short time.
where
serial sections of the
thyroid removed post-mortem showed
no parathyroid, the animals lived 30 and 27 days, respectively, without symptoms and were killed. In dog 1, symptoms did not occur, and at the post-mortem no parathyroids were found, although serial sections were not cut.
In cats
1,
6,
and
8, in
which at the operation the thyroid lobe with the parathyroids on one side, and the parathyroids alone on the other side, were removed, the animals lived, without symptoms, 23 days, 25 days,
and 30 days, respectively, and were then killed. In all three cases a careful post-mortem search was made, and the remaining lobe of the thyroid was cut in serial sections, and no traces of parathyroid was found. exceptions
There
is
a tendency to disregard these
—MacCallum and Davidson,
Berkeley and Beebe^"
and explain them by supposing that parathyroids have remained behind unobserved.” This explanation is hardly tenable in view of the numerous examples presented. As to accessory glands, as Vincent'*'’ states,
“If accessory glands be so usually present, the
question as to the importance to life of these glands ceases to
have the value hitherto attached to
penny
it.”
Although
I believe
killed his animals too soon after the operation,
^Gley; Brit. Med. Jour., Sept. 21, 1901. Edmunds: Jour, of Pathol, and Bacteriol., Jan., 1896. ^•’Halpenny: Surgery, Gynecology, and Obstetrics, May, 1910. MacCallum and Davidson: Medical News, Apr. 8, 1905. ‘‘J;
Berkeley and Beebe: Journal of Medical Research, Peb., Lancet, Aug. 11 and 18, 1906.
« Vincent: London
1909.
Hal-
Parhon
THVROr'ARATIIYROin APPARATUS.
k;o
and
having observed postoperative death
Golstcin''*
witlioiit tetanic
phenomena)
as
thyroparatliyroideetoniy in the cat, to the data recorded
view
that
tlie
(though and OG days after the fact remains tliat added
much
as 30
by Gley his evidence tends
parathyroids
endowed
are
to Aveaken tlie
independent
Avith
functions. Finally,
and pointedly suggesting a combined function,
aa'C
have seen that a transplanted or grafted piece of thyroid tissue, free of all parathyroid tissue, assumes the functions of both sets of organ.s, arrests the convulsive disorders due to e.xtirpation of
the parathyroids alone, and prevents death.
All this clearly ])oints to a functional connection (probably a nci’A'ous one to co-ordinate the relative proportions of their secretions)
betAveen these tAvo sets of organs,
and thus insures
the ultimate formation in the lungs of a perfect,
i.e.,
jihysio-
logical, thyroparathyroidal product.
The purpose that, as stated
of this itinerary suggests itself AAdien Ave recall
by Xothnagel and
large quantities of iodine.
llossbach,"'"
It accounts
hasmoglobin can
fi.\
also for the fact that
and Bourcet found iodine in the red corpuscles. Being a component of the albAiminous hamioglobin of these cells Avith adrenoxidase, hoAA-eA’er, iodine should be found in all tissues. Gley^®
While Bourcet'" ascertained that such found
it
in
all
cellular nuclei,
so
the case, Justus'*®
Avas
rich as
Avell
is
knoA\-n
in
This simultaneous presence of iodine and phos-
])hosphorus.
])horus in the nuclei, coiqded Avith the presence of iodine in the
red cor])uscles, suggests the nature of process carried on in the cells
:
Auz.,
of the lupmogJohm enthe viilnerahitity of ferment, increasiny, as a oxidation hy hances the phosphorus, u'hicli all cells, particularly their nuclei, contain,
The iliyropamthyroid comtUuent
to oxidation
hy the adrenoxidase in the blood.
This action aetiA'e
is
strikingly shoAvn by the fact that iodine, the
constituent of the thyroid secretion, and
by ITenrijcan and “ Parhon and
Corin,'"’ ITandfield Jones,®®
Golstein:
its salts, as shoAAui
others, cause
and
"Sderdtions Internes," pp. 607 and
Nothnagel and Rossbach:
“Therapeutlque/’
p.
261,
609,
Paris, 1899.
1889.
La Seinaine ra^dlcale. May 25, 1898. lOAi is.a , Cited by Moral and Doyon: Traits de physiologic, i, p. 4
are resorted to
etc.,
This ultimately leads the
periodically.
patients to realize that semifluid or fluid food l)orne
by the
child,
which has
mouth
alimentary canal from condition as the fluids
—
skin
i.e.,
to be fed
is
alone well
with a spoon, the whole
much in the same much of its normal
anus being
to
deprived of
another source of constipation.
The
genital
organs, both the ovaries
and
remain
testes,
imperfectly developed, though not necessarily infantile. sionally the genital organs
are
instincts
Occa-
and the sexual
are hypertrophied
Their offspring tend to be feeble-
enhanced.
minded, however, and are liable to excessive mortality. struation often fails to
appear,
or
is
scanty;
and even hsemorrhagie, owing,
profuse,
deficiency of adrenoxidase in the blood
coagulating power this entails.
as
and
in to
Men-
may
be
myxcedema,
to
or it
the imperfect
Epistaxis and bleeding at the
gums are also commonly obseiwed. The urine shows but little change, though the urea excreted is below normal. In very marked cases, albumin and hyaline casts have been found periodically, doubtless owing to the
autointoxication
intestinal
seem
to
resulting
The
canal.
from retained excreta in the
thoracic and abdominal organs do not
be involved in the morbid process.
The mental the case.
state of the child
In some
it is
depends upon the severity of
not far removed from what Eoesch has
termed a ‘diuman plant,” even the intelligence common to the higher animals being wanting. The child fails to recognize its parents or any person about it, or even a person from an object, and nothing, even toys, interests it in the least. It neither weeps
n
THYROPAUATHYROID DISEASES.
196 nor laughs.
It
is
absolutely
manifesting any special wants.
apathetic,
sits
quietly
without
may, however, show signs of hunger or thirst, either by crying like an infant or by grunts or inarticulate sounds. In a higher grade, a few words may be spoken, there
is
It
recognition of parents and familiar faces and
even a show of affection for them, but beyond the limited vocabulary no progress can be made, even the alphabet being
beyond them. Still higher grades may speak fairly well, be free, though slow and deliberate, in their movements, etc., but fail to develop thereafter, even
if
they attain old age, which
is
not often
the case.
The classes
:
brothers Wenzel have divided these cases into three
the cretins,
who
are unable to speak, and lead a purely
vegetative life; the semi-cretins,
whose language
who
are simple-minded, but
limited and imperfect; and the cretinoids,
is
who
are endowed with some intelligence, but show the physical signs of cretinism.
There
is
another type, the mongolian, called thus
because of their slanting eyes, which closely resembles the cretin of a higher order, but this type shows
more intelligence and seldom
yields to the effects of thyroid preparations.
The
thyroid, in about two-thirds of the cases,
is
more
or less
atrophied, to such a degree in some that
it cannot be detected by In the remaining third, and usually in the endemic there exists a more or less developed (sometimes volumi-
palpation. cases,
nous) goiter. Etiot.ociv.
—
It liecomes necessary in this connection to dis-
tinguish between the two general classes, endemic and sporadic cretinism.
Endemic cretinism, often a family disease, and observed in number a of cases in special localities, is believed to be due to some chemical substance or micro-organism peculiar to the waters available in those regions.
This type has been connected with special proofs from various directions. in these regions,
Not only
is
by
localities
cretinism
common
but normal individuals may, on moving
to
them, have cretinic children therein, and normal children in healthy regions. Again, animals from the latter were found to develop goiters (the preliminary cause of endemic cretinism) in the contaminating districts
by drinking their water, while
this
197
•
CRETINISM.
water carried afar to healthy localities and given to dogs as sole Whether it is a beverage also caused goiter in these animals. mineral salt, a vegetable mold or some other pathogenic micro-
organism
is
not established, but for the time being the germ
theory seems to prevail.
The question
We
of heredity in these cases is a debated one.
have seen under “hypothyroidia” that syphilis and alcohol-
ism tend to leave their imprint upon the thyroids of descendants. Some oppose this view in respect to cretinism on the ground that the positive signs of cretinism only appear
weaned, and contaminating water obviously wrong:
given
is
when the child But this to it.
who
are thoroughly
familiar with the morbid effects of hypothyroidia.
condition in the mother
is
—a
alcoholism,
inherited,
knovm
also well
thyroidia in her offspring defect
is
Cretinism can readily be detected in a child
one month old and earlier by observers
maternal
is
fact
such
The
which brings ns back as
latter
to result in hypo-
hypothyroidia,
to
any
syphilis,
may
be present as the origin of the hypoIn other words, there is at present no sound foundation for antagonism to the prevailing view that endemic cretinism may be congenital in a certain jiroportion of etc.,
that
thyroidia in the child.
cases.
Sporadic cretinism,
has also been termed “cretinoid,” and “cretinoid pachydermia” occurs in any country, in localities that are entirely free from cretinism, and in healthy families. It is mainly due to some lesion of the thyroid caused by an acute febrile disease or some intoxication ivliich
or “myxadematotis, idiocy/^
capable of inhibiting or arresting
its
functions, either before or
after birth.
How
a general infection can produce such lesions in the
From my viewpoint, it finds its explanation in an autodigestive process similar to that which occum in the pancreas under certain conditions. As previouslj'^ thyroid
is
admittedly unknown.
stated,
I have attributed to the thyroid secretion properties similar to those of Wright’s opsonins, a view recently sustained
by Marbe and Stepanoff, at the Pasteur Institute. The antitoxic and antigeiTn constituents of the blood circulating in the thju’oid (and parathyroids, which may also he the seat of similar lesions), it is obvious that undue accumulation of thyroid secretion in the
—
THYROPARATHYROID DISEASES.
198 organ
own parenchyma
itself will oversensitize its
or its vascular
elements or both, and render them vulnerable to proteolysis along with any germ or toxin that
The
may
be present in the organ.
autodigested areas are replaced by fibrous tissue, and a
process of cirrhotic atrophy
which sooner or
started
is
later
annuls the functions of the organ.
The
which have shown themselves
diseases
most
to be the
frequent causes of sporadic cretinism are typhoid fever, scarla-
pneumonia,
tina,
and
pertussis
—the
identical
series
which
proves most prolific in the genesis of the infantile encephalopathies,
another source
of
idiocy,
but in which the cerebral
lesions are the direct pathogenic factors.
Pathology.
—The end
growth of
interstitial
enlargement of the gland ular tissue.
Some
remnant, however,
lesions are the
same in both forms.
a marked proliferation and overtissue or connective tissue, causing both
In the endemic form there
—
is
goiter
—and
obliteration of the gland-
glandular tissue usually persists; even this slioivs
evidences of degenerative change.
The symptomatology of both forms indicates clearly, we have seen, that deficient oxidation, metabolism, and nutrition This apunderlie the resulting general physical phenomena. plies as well to the
development
mental phenomena, symmetrical arrest of
affecting
more or
less
all
the
elements of the
There are occasionally found localized lesions of the nature of infantile cerehropathies, porencephaly, etc., but it is probable that these are concomitant changes rather than com-
brain.
])onents of the tyjiical jneture of cretinism per se.
Briefly,
we
of the brain
are dealing with arrested nutrition and development as a result of the absence of the secretion which sustains these
fundamental processes.
Treatjiext.
—Before
the introduction of thyroid gland in
the treatment of this distressing condition, there was practically nothing to he done. While its use must be continued, relapse
(excepting the body growth)
though, as a rule, with
much
that the changes produced
occurring invariably without less
it,
intensity, the fact remains
in the child, particularly in sporadic
early development of the disease childinhibits the mental development accordingly, the later in far in so treatment, of it appears, the better are the results cases, are truly marvelous.
hood
As
199
CRETINISM. as
tlie
intelligence
concerned.
is
The
jiliysical
restoration
not
is
materially iiiHuenced by the age at which the disease first apChildren grow with surprising rapidity in some peared. instances, over one inch per month in some cases, until the normal stature of the corresponding age is reached. The brain responds more slowly; but considerable intelligence is gained, though it does not reach, as a rule, that of normal children.
They learn slowly and develop only very gradually their vocabulary. They should be gently assisted in this direction.
When
the thyroid treatment
is
instituted the ease should be
carefully watched, as the tolerance varies greatly in different children.
They should be kept from any
Another important reason for
heart-failure occur. tion
is
violent e.xercise lest
the bones tend to soften, and, therefore, to yield tibia
this precau-
the fact that the growth of the skeleton is so rapid that
and
and bend.
to offset this
tendency
if it
shows
itself,
until the
normal height
of a child of a corresponding age has been attained.
calcium lactophosphate of the U. less,
The
fibula are especially exposed; braces should be apjfiied
according to the age,
This
this connection.
and Papinian^^ and
is
is
S.
P.,
Syrup of
one teaspoonful or
a useful adjuvant to thyroid gland in
accounted for in the opinion of Parhon
others, based
on
many
published facts, that
the thyroid gland plays an important role in the assimilation of
calcium.
Large doses are not only dangerous, but they inhibit the beneficial process. Again, it must be remembered that the thyroid cumulative in the sense that the organism will utilize a certain quantity ^which varies with each case and. that any excess may prove toxic. This stage may be reached active principle
is
—
—
early in one instance
and late in another. I have seen it produced in three weeks with 2-grain (0.132 Gm.) doses; conversely, in a case reported
grains (0.396
Gm.)
by Freund in a
girl of
14 years, 6
daily in divided doses caused a sudden rise
of temperature to 104° P., a pulse of 160, rapid breathing,
and
death the next day, though she had been taking the same agent nineteen months. The danger signals are rapid pulse, vertigo, general weakness, pains in the back and limbs, syncope, and,
Internes/ ’°p.
“edicala,
1904,
cited
in
if
“Secretions
200
THYROPARATHYROID DISEASES.
the intoxication be severe, nausea and vomiting, a
temperature, and collapse.
When
marked
any untoward
rise of
effect occurs,
remedy a few days suffices. They are more likely appear when the preparation used is old, a fact which suggests that it may have undergone putrefactive changes when cessation of the to
long kept.
An
infant can be given
grain
1/2
(0.033
Gm.)
dally of
desiccated thyroid, and a child of 2 years, twice daily, and older children thrice daily, or 1 grain (O.OGG Gm.) can be given at
dinner and another on retiring.
untoward
produce
effects,
the
have never seen such doses recumbent position after the I
second dose, as urged by Murray, preventing them. When it is necessary to increase the dose, the patient should be seen fre-
As much
Gm.) have been given three times daily with safety; but it must be remembered that the preparations now available are better and more efficacious. The preparation I now use is Burroughs, Wellcome & Co.’s standardquently.
as 5 grains (0.33
ized desiccated gland substance (in tabloids),
which contains 0.2
per cent, of iodine in organic combination.
stand larger doses than others.
A
Cretins usually
good guide in them
the
is
temperature, which tends to rise to normal; as a rule, the dose that will
When
do this
this is
suffices
to bring about the
to prevent recurrence.
But
it
desired
Gm.) on must not be neglected;
attained, 1 grain (O.OGG
results.
retiring suffices
otherwise,
the disease will certainly return.
The younger as a rule.
are
the patient, the
more marked the improvement,
In adult cretins, the results are meager
obtained.
The improvement
is
any at
all
much more marked
in
if
sporadic than in endemic cases, owing probably to the fact that
up
to the onset of the causative disease physical
growth had proceeded normally. thyroid treatment
is
and mental
In the Mongolian type, the
useless.
Grafting of thyroid tissue to render the constant use of thyroid
preparations
investigators.
unnecessary has
It is only in recent years,
been
tried
by various
however, that a promis-
ing method has been introduced by Cbristiani,'- of Geneva. conditions are that only normal and living tissues be used the grafts be small *-
Chrlstiani:
The ;
that
(about the size of a grain of wheat), but
Semalnc m^dicale, March
16,
1904.
1
Fiu.
Fiu.
1
THYRQin EXTRACT IN CRETINISM, Fig.
1.
E. MnDes.'}
Cretinic idiot 7 yoars old wtLBn thyroid treatment
begun. Fig. 2,
-
[J,
Had
Changes
ceased
after
to
develop
when
3 years
one year's treatment, G-rowth,
[Cleveland Medical Gazette.]
was
old.
inches,
]
J
201
MYXaSDBMATOUS INFANTILISM. very luuuerous
taneous
vascular subcuthat they he inserted in very
;
tissue,
cellular
employed.
and
only
that
human
thyroid
he
grafts from This makes it possible to obtain small to containing areas of normal tissue, and
a removed goiter
The
transplant tliem into the cretinous subject. saline kept alive an hour in physiological
tissue can be
solution.
grafts
A to
very avoid
the sharp instrument should be used to cut in sUu, where they introduced then crushing them. They are
parenchyma. gain a perfect foothold, becoming perfect thyroid obtained good results Jitore recently, Charrin and Christiani^ Six months after the operation, the with sheep’s thyroid.
myxoedema) became pregnant, and it with the was found that each graft became enlarged, in keeping proper physiological process which occurs normally in the gland patient (a case of operative
under similar circumstances. improvement in 60 per cent,
myxoedema, cretinism, dwarfism,
reported
Christiani^^ of
his
distinct
which included
cases,
remarkable results in 34
etc,,
The most
per cent., and no result in 6 per cent.
striking results
were in the various types of cretinism.
MYXCEDEMATOUS INPAOTILISM. This disorder,
first
attributed to the thyroid
resembles cretinism very closely, but class is
by Brissaud,
retention as a separate
warranted by the fact that the arrest of development
manifests of
its
itself
mainly by the persistence of the characteristics
childhood, physical and mental, without
true idiocy, and often without dwarfism. tus, either
the evidences of
The
thyroid, appara-
through inadequate development of congenital origin,
organic lesions, especially sclerosis, acquired in the course of acute infections during infancy, or from some other cause,
unable to supply enough of
its
is
secretion to subserve the needs
metabolism and growth (which involves an excess of metabolic activity), and the latter ceases, while normal metaboof both
lism,
enough
to sustain the vital process, continues.
Symptomatology and Pathogenesis. in
—The
worst cases,
which myxcedema predominates, are virtually instances of ’’Charrin and Christlanl; Le bulletin medical, July 11, Christlanl: Bull, de I’Acad. de mOd., vol. Iviil, 1907.
1906.
202
THYROPARATHYROID DISEASES.
cretinism of a mild type. obese,
Tlie patient
though child-like in shape, and
is
short, thick set,
may
and
look old for his age.
The face appears bloated, rounded, pale, and wa.x-like, a reddish patch being sometimes present below the cheek bones. The nose squatty and pugged, and the mouth large; the latter is usually open, a fact accounted for by the almost invariable presence of adenoids, hypertroi)hy, and infiltration of the nasal mucosa and tonsils. The tongue, as in the cretin, may be thickened and the lingual tonsil likewise, rendering speech thick and difficult. ihe hair may be profuse, though coarse and lusterless, but about the eighteenth year
begins to
it
fall
in
patches,
leading, in most instances, to alopecia.
In most cases hair fails grow on other parts of the body. The skin is tense, owing to infiltration, and is also dry, because of deficient action of the cutaneous glands, and it feels rough and scaly to the touch. to
Pruritus
often complained
is
of.
The teeth remain infantile, as a rule, and decay The abdomen is unusually prominent and hard in all
early. cases,
owing, mainly, to the stubborn constipation which causes retention of gas and fajces, the latter being only voided in some cases
by engorgement and to relaxation of the abdominal muscle. The constipation is also mainly due to' the loss of tone of the intestinal muscular fibers and the paucity of succus entcricus. Enuresis
is
commonly
Although the respiration
observed.
apparently nonnal there
is
deficient oxidation; the e.xtremities
is
are cold and are readily affected with chilblains in cold weather.
The
and extremities may even be cyanotic and the patient
face
complain of constantly feeling
common in this
phenomenon
is
well
Actual hypothermia
cold.
The
feature of these cases.
is
a
part played by the thyroid
shown by the
fact that Beebe'®
found
that “by the administration of thyroid to a cretin or patient
with myxoedema
oxygen from 20
The
it
is
possible
to
increase
the
absorption
of
to 75 per cent.”
between this form and true cretinism
diffei’cnee
as stated, in the fact that idiocy does not occur.
The
child
lies,
may
not be bright or oven nonnally intelligent, having been slow to
and shown deficiency at grammar, and arithmetic, but
talk
15
Beebe:
Loc.
clt.,
p.
659.
school, it
is,
particularly in spelling,
nevertheless, quite able to
203
MYXOiDEMATOUS INFANTILISM. hold
its
that for all ordinary needs; the face, in fact, unlike Yet the bears an expression of intelligence.
own
of the cretin, intellect retains the characteristics of childhood,
both as to ideas,
judgment, and emotions, a patient of twenty years, for example, preferring the company of children below ten to that of young
men
own
of his
lie, steal,
These patients
age.
start fires, etc., especially
may show
a proclivity to
when under the
evil influence
normal individuals. Any unlawful act they may commit is due, in most eases, more to lack of judgment and inability to resist suggestion and a desire to please others than of designing
an
to
proclivity
inherent
Others
crime.
to
excitable,
are
turbulent, and rough, and frequently break anything that again, the element of willful
all fragile; here,
harm
is at
absent,
is
muscular tremor and inability to prevent movements of the hands or fingers ^s in athetosis being the underlying cause
—
—
of the defect.
The heart
is
excitable, a slight
violent “palpitations”
is
This
and tachycardia.
a deficiency of adrenal secretion.
the same cause marked tendency
emotion sufficing to cause is
mainly due to
Dilatation of the heart from
often witnessed.
The
veins
also
to dilate, the veins of the extremities
hremorrhoidal veins particularly.
Varicocele
In a case seen through the kindness of Dr. a sprig of thick veins spread
upward over
may
show a and the
also
exist.
W. Egbert Eobertson, the mons veneris and
coincided with undeveloped testicles and total absence of hair
man
over the genitalia, in a young philia
is
frequently
hypothyroidia,
haemophilia
since
noted,
thyroid
an
Haemo-
twenty years.
indirect
gland
by increasing the
of
result
given
coagulation
also
of
the
orally
counteracts
time.
Epistaxis,
menorrhagia, and metrorrhagia are also ohseiwed in some cases, the two latter all,
which
is
phenomena where menstruation has developed
at
often not the case, coinciding with non-development
and pubic hair. The penis and testicles often remain rudimentary even when the male reaches full adult age, and his general shape and high-pitched voice recalling those of of the breasts
a
woman. In a
still
higher type of infantilism the signs of myxoedema
are hardly discernible.
the average individual.
The growth may even exceed that of Such cases are usually plump and even
204
THYROPARATHYROID DISEASES.
portly; as in the preceding form, the
abdomen tends to be large, but the limbs are well rounded, recalling those of a woman, with fair skin, a high-pitched, or infantile, voice to complete the
The
resemblance.
face, axillaa,
and pubis are free of hair;
tlie
penis and testicles small
and rudimentary. Mentally “he is simply an overgrown child,” wrote Meige,^'’ who gave us a close analysis
of
these
“These children, who should long
cases.
before have reached the reasoning period of their lives, play with
laugh at a childish prank, cry for practically nothing, become angry as readily, are subject to ridiculous frights, and toys,
call
their
mamma
In the average
under the influence of the
case,
emotion.”
least
— years—
however, this truly infantile type
the behavior of a child of but two or three
recalling better
is
exemplified by one of seven or eight years, though he be perhaps actually beyond his twentieth year.
The feminine
marked
attributes are sometimes very
in the
male, the breasts, thighs, and general conformation resembling closely those of the female, constituting the “feminine” type.
In the female, in
whom
infantilism occurs less frequently, the
body preserves the attributes of childhood, i.e., it fails to undergo the normal changes of puberty. Though tall, perhaps, the body shows no development on sexual lines: the breasts
remain small and
flat,
no hair grows in the
axillie or
over the
and the hips and nates flat. The uterus and its adnexa also fail to develop, and menstruation Some cases tend even toward the male sex, fails to appear.
pubis, the trunk remains cylindrical,
constituting
“masculinism,”
the
voice,
the
physical
assuming a masculine type. Diagnosis. From this type, which belongs
—
outline,
essentially to
the domain of the thyroparathyroid apparatus, must be distin-
guished several types
Lorain
Type
ivliich
of
do not.
Infantilism
.
— In
a
type
symmetrical in
Lorain, in 1870, tbc dwarfism is the ultimate products are symmetrical,
described tlie
miniature
form being practically always observed in the male.
by
sense that
men
No
—
this
myxoe-
dematous symptoms are present; the genitalia are usually normal, though the pubic and axillary hair is wanting, and notwithstanding their diminutive stature and their slender physique, «
Malge;
Revua
Intern,
de Mdd. et de Chlr., Mar.
25.
1896.
205
MYXaSDEMATOUS INFANTILISM. tlieir
facial
appearance and expression, and
are usually quite
from
They depart
to the average.
up
their fully developed fellow-inen, in
thyroid insufflcieney, but to anangioplasia,
ment
and premature
of the arteries
i.e.,
no way
in
except in the
fact,
this type is
As shown mainly by Meige,”
stature.
intelligence
tlieir
not due to
defective developIt is usually
ossification.
alcohoHsm, ascribed to parental hereditary syphilis, tuberculosis, Thyroid preparations in this other debilitating disorders.
and form are of no value. This type is characterized by Mongolian Infaniilism Mongolian features, and particularly the slanting eyes. These .
features occur at birth, culosis,
alcoholism,
prolonged deliveries
and are not traceable
account in some cases, at
^ivhich
—
the flat skull or bulging forehead
They
during pregnancy.
to syphilis, tuber-
as in the Lorain type, but rather to
etc.,
—
—
or to strong mental emotions
not morose
are
least, for
or
torpid like the
myxoedematous cases and are usually amiable and well behaved. Curiously! enough, all show a marked predilection for music and signs of unusual development of the musical sense. is
The tongue and
usually quite thick and heavy, and the hands square
the latter
flat,
accounting for the clumsiness which characterizes
these cases.
They usually
and are apt Their undeveloped
suffer
all
from some chronic respiratory some intercurrent infection. Mongolian facies, the bulging
to die early of
trouble,
size,
their
forehead, and their feeble-mindedness render the recognition of
Thyroid preparations are of no
these cases quite easy.
Achondroplasia,
or Foetal Riclcets
.
—
^This
avail.
typo of dwarf,
unlike the ni3'xoedematous type, does not show mental deficiency,
but
many
of the charaeteristics of cretinism
:
the relatively large
head, the saddle nose, the short and bowed limbs, the prominent
abdomen, and the marked
But the arms and legs are, show some degree of symmetry,
lordosis.
unlike the other types, which
all
entirely too short for the body, the finger-tips never reaching
the level of the hips.
and deformed.
The
Again, the long bones are usually bent skull is
unduly developed and
proportion with the face, which
The
eyes, lids,
eretin,
and tongue
but the hair
” Melge and
Allard;
is
may
is
then
made
to
is
out of
appear small.
resemble greatly those of the
normal and usually abundant, and the
Nouvelle^ Iconog.
de la Salp6tri6re,
No.
2,
1898.
206
TIIYROPARATHYROID DISKASES.
skin soft and well nourislied.
These characteristics, the fact
that the mental faculties are quite normal, and the inelTectivencss of thyroid treatment render the identification of achon-
droplasia quite easy.
Tkeatment.
—
filie
dematous infantilism
is
only measure of any value in myxoethe use of thyroid preparations.
'J’he
treatment recomniended for cretinism being as applicable here, the reader is referred to page 198. The younger the ])atient, the greater arc the chances of im])rovcmcnt. l)cen rcacheil, the results, in so far as the
After puberty has
mental status
is
con-
cerned, are seldom satisfactory.
THYROID HYPER.EMIA AND THYROIDITIS. This
a very important disorder mainly because of
is
its
upon the conditions just reviewed, e.g., hypoparathyroidia, myxoedema, and cretinism, and the whole gamut of morbid effects of deficient functional activity of the causative
influence
thyroparathyroid apparatus. acute"
when
form
the
It
is
generally recognized in
inflammatory
marked, but, unfortunately,
it is
phenomena
is
is
The
structure of the
and the quantity of blood circulating through it that a high blood-pressure, such as that which occurs
such,
so great,
during high interstitial
febrile processes, is sufficient to
produce areas of
interlobar
connective-tissue
haemorrhage
spaces, Avhich
form
done has been
as
in
many
the
sclerotic areas
sufficiently great.
of thyroid tissue over
limit the result
is
if
a
excess
and above the needs of the organism, how-
prove harmless, but
hypoparathyroidia
wherever the damage
As nature provides an
ever, inhibition of a proportion of the
may
very
not only in this class of cases
that lesions in the organ are provoked.
thyroid
are
its
if
more
gland below this limit
the sclerosis happens to e.xceed this or less marked hypothyroidia (or
the parathyroids are involved, which
is at
least sometimes the case) corresponding in severity with the Indeed, we have seen proportion of thyroid tissue sacrificed.
the disorders treated so far in the present chapter far sclerosis of the thyroid, with its resulting atrophy, was by
that in
all
the most prominent pathogenic lesion.
The graver paratively rare.
condition, acute thyroiditis,
is
fortunately com-
Moreover, while simple hypcraiinia, even vhen
—
207
THYROID HYPERyEMIA AND THYROIDITIS. attoruled
by
thyroiditis
interstitial haemoiTliagc, is
which make
seldom recognized, acute
attended by severe local and general phenomena,
is
it
possible to identify
early, to
it
meet
it
therapeu-
and avoid disastrous results. Acute inflammation of the thyroid apart from that due to the presence therein of goiter, is usually provoked by invading bacteria in the cancer, etc. tieally
—
—
notably
course of infeetion.s,
diphtheria, typhoid fever, scarla-
:
tina, measles, parotitis, tonsillitis,
rheumatic
dysenter}',
tussis,
orchitis,
and
influenza.
of poisons, constituting
It
pneumonia, per-
puerperal
fever
has also been attributed to the action
with other signs of iodism. the glandular tissues undergo
also
been known to cause
met with
area thus affected
become
sufficiently
is
along
it
In these inflammatory disorders
marked changes, including desqua-
mation and degeneration of the epithelium, besides the tial sclerosis
sepsis,
what has been termed “toxic thyroiditis”;
and the iodides have
iodine
erysipelas,
fever,
in the
form previously described.
large,
the
intersti-
If the
may
functions of the gland
impaired to constitute marked hypoth}'roidia,
which, we have seen, ma}q in children, arrest general develop-
ment
of
both
the
body and mind.
Shields^®
instance in which thyroiditis lasting one
week
witnessed
an
led to complete
atrophy of the organ and to typical cretinism.
In a case reported by Bonney^'*'^ the left lobe was converted into an abscess cavity. Symptojiatoi.ociy. Though capable of doing considerable injury to the gland, the acute hyperamiia attending infectious diseases gives rise to few tangible iihenomena,
i.e.,
slight swell-
ing of the neck, sensitiveness to pressure, and, perhaps, slight pain during deglutition. ITnless looked for, they will seldom bo discerned, as they do not cause sufficient discomfort to attract the attention of the patient.
fn acute thyroiditis the onset, usually ushered in by a chill, the most marked symptom is difficult}' in ; swallowing with, sometimes, neuralgic pain udiich radiates
is
generally sudden
Avidely in various directions, the ears
and occiput;
and neck, even
to the
arms
sometimes very severe, particularly during deglutition and on moving the head from side to side. If the whole gland is involved and the swelling, which is often the this is
size of a hen’s egg, is '“Shields:
marked, severe dyspnoea and even cyanosis
N. Y. Med. Jonr., Oet., 1898. Bonney: London Lancet, July Ifi, 1911.
208
THYROPARATHYROID DISEASES.
may
occur,
owing
to pressure of
tlie
inflamed organ upon the
may
Paralysis of the recurrent laryngeal
trachea.
produce
and
hoarseness
paro.xysms
of
occur and
but
sulfocation,
the
hoarseness and cough are more likely to be due to involvement of the
larynx in the inflammatory process.
glottis
may
occur,
also
as
in
(Edema
the
Lewis and
by
reported
cases
of
O’Neill.’®
The identity of the inflamed organ is readily established by causing the patient to swallow, when the tumor will rise, provided the head is not bent backward, which will immobilize Headache is often present and epistaxis occurs someowing to pressure of the enlarged thyroid upon the
the organ. times,
cervical veins
and the passive cerebral congestion
this produces.
The
Carotid pulsation has also been observed by Broca. of the organ
is
sometimes quite congested.
fever during the acute stage;
less
it
is
There
is
surface
more or
sometimes quite high
notwithstanding the absence of suppuration
—a
fact
which
cardia
independent of temperature
has
been
also
is
Tachy-
ascribable to the excessive production of thyroiodase.
noted by
As observed by Jeanselme, the coagulating power of blood is greatly increased. The morbid process lasts, as a
Parisot.®®
the
but a few days, the swelling subsiding completely in most (Occasionally a certain amount of enlargement may instances. rule,
persist. i.e.,
Forty per cent, of the cases terminate in resolution,
without suppuration.
OVhen an abscess
is
formed the course
of the
morbid process
more jirotracted. A single abscess rarely occurs, the glandular mass being studded with numerous purulent foci, which, if Each abscess tends close one to the other, tend to nin together. is
to break through the adjacent soft tissues, including the skin.
The trachea and oesophagus may therefore be invaded by a purulent stream when rupture occurs. iMctastatic abscesses may also appear in the cervical cellular tissue.
hen spontaneous
rupture occurs through the skin, or when the abscess cally evacuated, the inflammatory process recedes
When, however,
it
surrounding parts ’» 20
is
may
Lewis and O’Neill: Parlsot:
left to .itself, the
is
surgi-
rapidly.
purulent infiltration of
give rise to serious complications, by
.lour.
Presse MC’dicalc,
Amcr. Med. Assoc., Nov.
May
7,
1910.
12,
1910.
—
209
THYROID HYPER.15MIA AND THYROIDITIS.
referred to above, involving, besides the trachea and oesophagus, causing septic the mediastinum, the pleura, and the lungs propet,
pneumonia, and
also the large vessels of the
neck and chest and
Thyroid abscesses bleed readily and are
thus causing pyiemia.
sometimes the source of severe capillary haemorrhages. Chronic thyroiditis
may
follow the acute type, either through
perpetuation of the infection in some small portion of the gland or the formation of a sinus which fails to heal. In the majority of
instances,
however,
it
chronic
with
concomitantly
occurs
processes, such as syphilis, tuberculosis, echinococcus cysts, acti-
nomycosis,
etc.
in these cases is less favorable
The prognosis
than in the acute form, since more or less impairment of the functions of the organ follow the destructive action of the
owing mainly to the fibrous Both the induration it -entails in various parts of the organ. acute and chronic types are prominent causes of hypothyroidia with its long train of morbid results, ranging from cretinism abscess
through
upon the glandular
its
many
tissues
modalities to the milder types of
myxcedema
described.
—
In the acute form, the increased volume of the which sometimes becomes greatly enlarged in a few
Diagnosis. gland,
hours, the sensitiveness to pressure,
and the radiating pain,
all
located in the region of the thyroid, coupled with the fact that,
on swallowing, this organ,
i.e.,
the scat of
all
these acute
symp-
toms, moves up and down, render the diagnosis quite easy in
well-marked is
eases.
When,
as is often the ease, the
inflammation
unilateral, especially if oedema, of the tissues prevails,
it
may
resemble mastoiditis or parotitis and has, in fact, often been
taken up for the latter disease.
Its connection
with a mobile
structure on the other side of the neck, however, renders the differentiation possible.
times discernible.
If abscesses form, fluctuation
is
some-
CEsophageal abscess in the neighborhood of
the thyroid furnishes
much
the same symptoms, but the mobility
of the gland during deglutition
makes
it
possible to identify
it
as the seat of abscess.
Treatment. its
milder forms,
The prevention is
of acute thyroiditis, even in an important feature in this connection,
when wo consider its pernicious effects upon development of the child and upon the general welfare of the individual at all ages.
—
THYROPAnATHYROID DISEASES.
210
As previously
main cause
stated, the
of the lesions
is
the excess-
ive pi-oteolytic activity of the intrathyroidal plasma,
owing
to
the identity of the organ as the source of the substance which, as I have pointed out,
opsonin
i.e.,
the homologue at least of Wright’s
is
The
the thyroiodase.
thyroid brings to
it,
presence of bacteria in the
as elsewhere, all the defensive constituents
of the blood, both fluid
and
cellular.
The
excess of opsonius
increasing the vulnerability of the thyroidal tissues to the proteolytic activity of these antibodies, however, these tissues yield
readily to the destinctive action of the latter. fore,
The aim,
there-
should be to prevent this complication in the course of
febrile infections.
Two
measures of value are at our disposal in this connec-
The
tion.
these
first of
is
The
the local application of cold.
thyroid should be carefully watched for any complication, and if it
becomes sensitive or swollen, or the patient complains of
pain in the thyroidal area, cold compresses should be applied over
it.
The
effect of cold is to
reduce local temperature and
through this the activity of the proteolytic enzymes which the antibodies
of
the blood
In other words,
contain.
is
it
not
bacteria which do the damage, but the excessively active germicidal substances they invite into the gland,
and by reducing this
activity with the aid of cold the excess of digestive
tagonized.
That the bacteria
these conditions
is
obvious, but
power
is
an-
are less violently attacked under it is
far better to allow the blood-
stream to transfer the germs elsewhere in the body for destruction, i.e., to the general circulation, where their destruction can proceed
without compromising the integrity of any tissue so
vital to the welfare of the
The second measure solution,
either by
body as the thyroid. is
the free use of physiological saline
tbe mouth, rectum, or subcutaneously, to
reduce the viscidity of the blood.
Not only does
this counteract
excessive proteolytic activity of the antibodies which underlies
and other tissues and cells the underlying causes of liEEUiolysis and autolysis but it facilitates osmosis and therefore the circulation through the thyroid, which has been fittingly compared by Berard to a Another advantage of the sponge, so replete is it with blood. use of saline solution is that, as shown elsewhere (see page 13^7),
their destructive action on the thyroid
—
—
211
THYROID HYPER-^DMIA AND THYROIDITIS.
enhances the activity of the autoprotective process Avhile facilitating tlie renal elimination of toxins or the end-products. The treatment of acute thyroiditis likewise includes the it
use of the above measures besides the remedies the causative One feature of importance in this connection disease wamints. is
that a high blood-pressure
orders
;
a pernicious feature of the dis-
is
vascular depressants, such as chloral hydrate and veratrum
viride, preferably the former, therefore, are of considerable value.
Wilson has shown that chloral hydrate can be used advan-
J. C.
tageously to reduce the peripheral congestion and general distress in
As
scarlatina.
and other exanthemata are
this
frequent causes of acute thyroiditis,
it
may
safely be
relatively
employed
to counteract this condition.
Surgical measures often become necessary.
Kocher-^
:
“The presence
of pus is difficult to demonstrate
premature incision must be avoided. itself
should be exposed.
According to
and
If necessary, the gland
If incision of the abscess is not fol-
lowed by rapid recovery, the presence of multiple abscesses should be suspected.
Fistula points to extensive necrosis.
such a case the affected Pai-tial
tliyroidectomy
thyroiditis thyroiditis.”
that
have
of
lialf
may
also
become
In the chronic
the gland
be
chronic
eased paid removed surgically, especially Kocher;
Keen's “Surgery,”
and
vol.
14
iii,
p.
380,
in
in
excised.
cases
hy hypo-
and the actually if
dyspnoea
1908.
of
chemicotoxic
attended
tliyroiditis
thyroid ia, thyroid gland should be given,
=1
must be
considered
In
is
dis-
present.
CHAPTEK
Y.
DISEASES OF THE TIlYPOrAKATHYROID
APPAPATUS
{Continued).
DISORDERS DUE TO EXCESSIVE ACTIVITY OF THE THYROPARATHYROID APPARATUS. OvEiiACTiviTY of the thyroparatlij’Toid apparatus, in keeptlie opposite state, described in the preceding chapter,
ing with
has been identified by numerous terms, the most used of which pseudo-Graves’s
are
aberrant
disease,
or
larval
de Basedow, hyperthyroidism, and thyroidism. these were based
exophthalmic
Basedow’s disease, forme fruste de
goiter, incomplete
upon the fact that
all of
the
la
maladie
The first five of phenomena were
reproduced in exophthalmic goiter, of which the disorder truth,
The
mild type.
a
absence
the
of
erroneous
into
diagnoses
that the
in
major sjTuptoms:
exojihthalmus and goiter, however, so readily misleads the cian
is,
tendency of
clini-
modem
from true exophthalmic goiter, i.e., to regard it as an autonomous syndrome, in which the cardinal s3'inptoms mentioned above are not sugHence the terms “hyperthyroidism” and “thyroidism.” gested. As stated in the preceding chapters, however, the temiinal “ism”
observers
is
appears to
to distinguish this milder type
me
to suggest the presence of a habit rather than a
morbid process subject
to treatment.
I prefer the
tenn “hyper-
covering
this
feature,
harmonizes with the terminals previously used.
To
simplify
thyroid ia,”
the term,
it is
not
in hypothyroidia,
are
which,
therefore,
made it
besides
to include the parathyroids, though, as
must be understood that these glandules
deemed functionally
associated with the thyroid proper in the
process to be described.
IIYPERTHYROIDIA. “aberrant” or “laiTal” Exoplitlialmie Goiter; forme fruste Vou Schrbtter: MediziniscUe Klinlk, April S, 1908. "
—
THYKOPAKATIIYUOID DISEASES.
21G
Thus, Wasliburn," in a
superior.
test of iiiy contention tliat tlie
“Then we should
adrenals take part in the process, writes:
expect high blood-pressure during a considerable part of the clinical course, that
and he gives
during the period of adrenal
is,
overactivity,'’
170, 1(50, and 200 nun. Ilg observed by him in four cases as proof of the correctness of this postulate. While 1(50,
this is perfectly true, and, as observed
by SpietholV ^lorris and
Edmunds,** and others, there
is
rise of blood-pressure, the fact
remains that
cases, contrary to
marked
a tendency toward a moderate
what we should expect under the arteries of the entire
pulsation in the liver, spleen, capillaries, ?
advanced
influence of a
excess of adrenal secretion in the blood, there
markable dilatation of the occur
in severe or
As we
shall see presently, this
is
etc.
a re-
is
organism with
Why
due to the
should this
specific action
of the thyroid secretion, which, exaggerated, offsets that of the
adrenal secretion.
And
it is
between the two functions of these organs that the
symptomatology finds
its
elements.
The
activity of both organs being synchronous,
exaggerated, secretory
we have merely
a cor-
respondingly’ exaggerated expression of their normal functions.
Thus,
if
the thyroid functions exceed those of the adrenals,
have vasodilation and a more or blood-pressure, while
if
less
marked depression
the adrenals predominate there
of blood- pressure such as that observed by
Washburn
we
of the
a rise
is
—though
in
advanced cases the accumulation of intennediate wastes in the
may cause it by exciting the vasomotor center. The following definition summarizes my conception
blood
pathogenesis of the disease
of the
:
a constitutional disease due to excessive functional activity of the thyroparathgroid apparatus, and to the resulting dilatation of ail arteries which the excess
Exophthalmic goiter
is
phosof thgro parathyroid secretion causes by producing excessive intissues, all in as P^O-,) elimination phorus oxidation {and
cluding the vascular muscles, the nervous system, and the general vasodilator:
the depressor nerve.
1’atiiooexesis
AND SYMPTOMATOLOGY.
—While,
as stated
above, the disease was divided in the earlier editions of this “Washburn: Spiethoft:
Wisconsin Medical Journal. March, Zentralblalt
“Morris and Edmunds:
1907.
innere Med., Bd. xxili, S. 819, Medical News, vol. Ixxxvi, p. 62, f.
190.. 190».
work
—
— ;
217
EXOPHTHALMIC GOITER.
two clearly delhied periods, further development of the of (piestions has rendered it advantageous, from tlie standpoint into
therapeutics, to recognize three stages
:
1,
the sthenic or erethic
during whicli the overactive thyroparathyroid apparatus causes excessive sensitization of the phosphorus of all tissues to oxidation, and, therefore, abnonnally active cellular metabolism stage,
2,
the transitional stage, during which the overworked thyroid
is
beginning to be restrained by the gradual formation of sclerotic areas and atrophy and, 3, the asthenic or niyxoedematous stage,
during which progressive
and atrophy increasingly inhibit
fibrosis
the functions of the organ and finally cause the patient’s death.
The
general vasodilation, though an important feature of the
process,
is
and,
incidental,
as
previously
subject
stated,
to
fluctuations.
Under “hyperthyroidia” we
Sthekic on FinsT Stage.
have seen how clearly the excess of thyroiodase enhances cellular activities
— driving
the thyroid secretion
the cell to death, as
and extracts increase
it
were.
all
That
tissue oxidation is
generally recognized, but unlike the oxidation produced by an excess of adrenal secretion or extract there occurs,
under the
influence of the thyroid secretion, phosphoric acid metabolism
and excretion, upon which Chittenden® had
laid stress.
This
is
a feature of the action of thyroid products upon all phosphorus-
containing structures, which stand out even more prominently in the clinical history of
hvperthyroidia. rich, as well
exophthalmic goiter than in the milder
'The brain
known, in
and nervous system are especially
this element.
ive thyroid activity, therefore, is
restlessness
of sight
sthenic
The
influence of the excess-
shown by the greater
agitation,
(children being unusually irritable), hallucinations
and hearing, capriciousness or unusual gayety in the which not infrequently includes also pseudodelirium, and even mania. Nervous disorders are so
stage,
hysteria,
evident in the disease that the latter has been considered by manj'" excellent autborities, including
Putnam, as a neurosis. Tremors, upper extremities, but not infrequently involving even the muscles of the back and of tbe whole body felt, as indicated by Maude, by placing the hands on tbe patient’s especially
marked
in the
shoulders while he “Chittenden:
is
standing
—are
practically ubiquitous in
Trans. Cong. Amer. Phys. and Surg., vol.
Iv, p.
87, 1897.
218
THYROPARATHYUOID DISEASES.
Even
these eases.
tlie
voiee
Choreic movements (which
may become strident and may replace tremors in
tremulous. children),
muscular spasms, and even epileptic convulsions and by no means rare, symptoms of tlie disease. They
local cramiis,
are classic,
denote undue erethism in the cerebrospinal axis and the peripheral nerves, and explain the excessive excretion of P-.Oj. The
undue carbohydrate metabolism noted by Kraus, Ludwig, Chvostek, and others are but additional expressions of the same factor.
We cannot ascribe to tlie thyroid secretion per se any more than to the thyroid preparations in common use the powerful oxidizing power this denotes. It is here that “oxidizing ferment”
of the blood,
i.e.,
the adrenal secretion converted into
adrenoxidase, comes into play.
Indeed, concomitantly, we find
the evidences of increased oxidation. ture to 1UU° or 101°
an acute febrile
is
While
a rise of tempera-
the rule, some cases show a tendenc}' to
observed by Gilman Thompson in a 70 cases, the fever reaching 104° F. and continuing
series of
state, as
sometimes several weeks, and recurring every now and then. Few diseases, in fact, furnish examples of such temperatures. In a case observed by Eendu,^®
it
reached in the course of one
of these exacerbations 110° F., remaining two days between 107°
and 110° F. The patients often complain bitterly of a sensawarmth, of “burning flushes,” especially when pruritus and sweating, both due to excessive metabolism in the skin and sweat-glands, are present. The increased demand for food and fluids betokens the intense rate of metabolism to which the
tion of
tissues
subjected;
are
common.
indeed,
polydipsia
and
boulimia
Yet, emaciation proceeds; the thyroiodase,
are
by in-
creasing the vulnerability of the nucleus— also rich in phos-
phorus
—
of all fat cells to oxidation
consumes cell
all
by the adrenoxidase,
finally
reserve fats; then folloiv nitrogenous tissues, whose
nuclei are likewise rich in phosphorus.
The
vascular phenomena, referred to above, and others they
entail, are due, as stated in
my
definition, to this excessive oxida-
and breaking down of all organic phosphorus, including that of vascular and nerve cells, and particularly Ludwig and Cyon’s depressor nerve, which, as is well known, causes general vasodilation and a fall of the blood-pressure. Cyon found, nioreover.
tion
Rendu
:
Lyon radical, March
11,
1900.
yASCULilR SUPPLY DP THE THYRDIU ELRUU.
219
exophthalmic goiter.
nerve, an clTect wliicli that thyroid extracts excite the depressor phosphorus of all cells explains. tlic action of thyroid on the arteries of the The vascular dilatation may affect all the marked to cause pulsation of all the laige
body and be artei-ial
sufficiently
trunks, most
and transmitted explains many, now obscure, phenom-
marked It
to the capillary system.
ena that attend the disease.
at the carotids
The tendency
to hajmorrhages in
the fact that the mucous membranes and skin is doubtless due to in excess the dilated arterioles admit blood into the capillaries the Hence, of the volume the venules can readily carry off. memffushing of the skin, the hajmorrhagic areas in the mucous branes, the ejiistaxis, the coffee-ground emesis, the subcutaneous extravasations of blood which, as in Popoff’s case,^^ ™^y attain
huge dimensions, the
telangiectasis, and, indeed, the
To
occasionally witnessed.
the vasodilation
may
gangrene
also be ascribed
and legs, the fugitive the mdemas swellings of the face, neck, arms, and joints, none of which are, A disof course, beneficially influenced by thyroid treatment. vessels, as a large tinct “wilin’” may be heard in some cases over result of the unusual volume of blood circulating through them. The thyroid is, as a rule, only moderately enlarged, and its greatly dilated vessels likewise give rise to a distinct whirr under often observed in the eyelids
During the first under pressure.
auscultation, while palpation elicits a thrill.
stage the goiter
is relatively soft,
and
Exophthalmos, commonly the eral), belongs,
}delds
sign (sometimes unilat-
first
when not merely apparent,
of the eye-lids, to the
i.e., due to retraction same vasodilation of depressor origin, the
vessels behind the eye-ball, especially of the retro-bulbar
plexus, becoming greatly engorged. of the arterioles,
Here
we have
dilatation
which admits an excess of blood into the tissues
drained by this venous plexus.
At
fluctuates with the vascular dilatation, to
also
venous
first the exophthalmos and may even be caused
disappear temporarily by pushing gently on the eye-balls.
Later, no recession occurs
and connective
owing
to the local deposition of fat
tissue.
8tellwag’s sign (in reality Dalrymple’s,^"
twenty years
earlier),
retraction
who
described
it
of the lids, also finds its explanation in this vascular dilatation; the palpebral muscle "Popoft: Neurol. Centralblatt, April 15, 1900. Dairy tuple: London Lancet. May 26, 1849.
220
THYKOPAKATHYHOID DISEASES.
receiving un excess ol' arterial blood, it is unduly spastic, in keeping with other muscles oi the body. This applies also to Uraefe’s sign: lagging of the upper lid when the eye-ball moves
downward ; movements
its
muscle being
spastic,
it
cannot carry on
its
physiologically, that is to say, synchronously with
those of the eye-ball.
This spastic state may, in fact, be discerned by means of L. Napoleon Boston’s sign‘=> The head being firmly braced, the patient is directed to follow as high as :
possible with his eyes the operator’s hand, raised upward, start-
ing from the level of the patient’s chin about three from his face, then brought down again. The upper noticed to follow the pujjil
downward
feet
away
lid will
be
a short distance, then to
when what the author terms a “spasm” occurs before it resumes its downward course. The dependence of both Stellwag’s and von Graefe’s signs upon so fluctuating a factor as the circulation is shown by the fact that they may vary from day to stop,
day and that they are not constant.
The
tachycardia, one of the cardinal signs of the disease,
in the light of these facts,
but only in part, for practically nonnal.
it
an expression of
is
persists even
The erethism
when
tjie febrile
process,
the temperature
is
of the central nervous system
and of the nerves themselves, including the accelerator nerve, provoked by excessive oxidation in them, being taken into account, however, the abnormal pulse-rate finds its normal explanation even without the presence of a febrile state.
must itself
this be the case in view of the fact that the is
Especially
myocardium
rendered hyperexcitable by the blood overladen with
thyroiodase and adrenoxidase
it receives.
The
cardiac
symptoms
of the disease, extreme irritability, distressing violent palpitations,
with loud valvular sounds, especially marked at night, and
even endocarditis, betoken the presence of such a condition of the entire cardiac mechanism.
In children, in
whom
the disease
develops rapidly, as a rule, the cardiac signs are often the
first
to appear.
The
respiratory
phenomena
are closely allied to the cardiac,
in that the respiratory muscles, including the diaphragm, are also rendered supersensitive
b}'^
the excessive oxidation to which
they are subjected by the blood, and the irritability of the nerves: 13
Boston:
New York
Medical Journal, August
17,
1907.
;
221
EXOPHTHALMIC GOITBU. the plirenic, the respiratory nerve of Bell, the vagus,
The
receive.
restricted,
chest muscles being crampetl,
and the
air intake is
tlieir
tliey
etc.,
excursions are
correspondingly reduced.
That
the bronchial muscles are likewise contracted, abnormally reducing the caliber of the air channels, is probable. These two
sources of diminished respiratory capacity suffice, to
it
seems to me,
explain the sensations of suffocation or dyspnoea so often
As
observed in these cases.
is
the case with the tachycardia,
this dyspnoea is subject to crises,
during which the respirations
become extremely rapid, sixty a minute, sometimes, as observed in two cases by Sharp.^'* This observer noted that “opium had a marvelous action in slowing the respirations.” As shown in the second volume, page 1272 of this work, opium,
viewpoint, produces arterioles
which
—thus
its
effects
I ascribe the
process, congestion
by causing constriction of the
abnormal- effects.
and
is
morbidly influenced by the same
irritability of the gastric
muscular coat predisposing to emesis. is
hypercemia of
all
A
are
often
mucosa and
similar condition of
the underlying cause of diarrhoea.
and lymph-glands
spleen,
my
opposing precisely the muscular hyperasmia to
The alimentary canal
the intestine
from
found
The
liver,
enlarged.
The
organs moreover gives rise to a general malaise
or sensation of discomfort, the sensory terminals of all nerves
being rendered irritable.
Various
which
is
may
complications
occur,
most
distressing
of
ulceration of the cornea and loss of vision, through loss
of protection of the lids
and imperfect lachrymation and
lubrica-
tion of the ocular surface.
Some cases of exophthalmic goiter recover spontaneous!}^, though very gradually ; others suddenly enter into a rapid downward course, whieh W. G. Thompson has compared to malignant endocarditis, for
which disease it is frequently taken. A very and irregular heart action hyperpyrexia
rapid, tumultuous,
;
dyspnoea with labored breathing; vomiting; diarrhoea; haemorrhages and ecchymoses ; marked congestion and enlargement of the liver; delirium; stupor, the typical of
symptoms
and coma.
In most
cases, however,
of hyperthyroidia are replaced
by a period apparent quiescence—the transition stage— and then lapse
“Sharp:
London Lancet, June
27.
1903.
— 222
THYHOPAKATHYUOII) DISEASES.
into Hiosc of liypotliyroitlia, the
normal
toniiinal niorhicl jn-ocess
of projrressive exoplitlialinic goiter.
'TransUion Slaije
.
— Wliat
me
api)ears to
to be entitled to
this designation is a ])eriod in the course of the disease
there occurs apparently considerable improvement.
The
when skin
ceases to be abnormally moist, the heat flushes, the sensation of
heat and the fever disappear, and the skin loses pearance, and
may
its
suffused ap-
The tremors and nervous
even become pale.
and even the mental aberrations and emotionalism, arc replaced by a gratifying placidity; the tachycardia greatly lessens, though reawakened by exertion. The emaciation tends also to disappear, and the patient, though weak, may even show a tendency to corpulence. On the whole, he appears to his surroundings greatly improved and even on a fair way to recovery. If the goiter be examined with due care at this time, it will be found, at least in most insttinces, to have receded, and to have lost somewhat of its rounded shape. Its former softness still remains in some places, but in others nodular masses or bosses can readily be detected by passing a linger over the mass, and exerting slight pressure. The meaning of this is selfevident the goiter is undergoing atrophy owing to the sclerotic areas with which it is now studded, and the transition stage is that period of the process during which the normal tissues, i.e., what remains of them, are just able to sustain the metabolic equilibrium although the latter is further compromised by the irritability,
:
—
deficiency of cellular phosphonis following
The time
finally arrives
when
its
excessive oxidation.
the thyroid secretion produced
longer sufficient and the case then enters into the
is
no
:
—
Asthenic or 21 yxccdcmatoiis State In this stage, reached, as previously stated, if cure or death does not occur early in the course of the disease, we witness the results of exhaustion of both .
the thyroid and the adrenals with fihrosis of the former. recognition of this fact
is
The
important, for, while thyroid prepara-
tions are very harmful in the
first stage, a.s
many
reported cases
show, they may be useful when myxoedema has appeared. During the transition period the change is so rapid in some cases that certain symptoms of both exophthalmic goiter and myxoedema
may In
occur together, the case lapsing ultimately into myxoedema. its symptoms, unrecognized, are promiscuously
textbooks
—
:
223
EXOPHTHALMIC GOITER.
In a case M’itlabor, premature nessed by de Smet,^° the transition followed Tlie exophthe goiter alone remaining of the first disease.
merged in with those
thalmiis
may
of exophthalmic goiter.
also persist.
The myxocdeinatons phenomena include most of those reviewed under Myxoedema, thyroidia
and
symptoms
of impaired oxidation
tions
hypoadrenia,
They
entail.
are
the manifestations of hypo-
i.e.,
and,
the
shown,
previously
as
and metabolism these condihypothermia,
briefly:
coldness, obesity with a non-pitting,
sensation
of
rough, dry skin; supra-
scapular swellings or pads, loss and coarseness of hair, brittleness
and ridging of the
nails,
cutaneous disorders,
leucoderma,
pigmentation,
There
is
etc.
;
predisposition to
onychia; various
scleroderma,
vitiligo,
mental tor 2ior, depression, and
brown
irritability.
intense weakness, especially of the legs, with occasionally
a tendency
to
tabes-like
paralysis,
hemiplegia,
or muscular
which may begin during the sthenic stage. There is a heart weakness and dilatation than in ordinary eases of myxoedema, owing probably to exhaustion of atrojihy,
tendency to greater
the cardiac muscle during the sthenic stage.
If the patient
is
not carried off by some intercurrent disease, cachexia supervenes
with a tendency to fainting spells and heart-failure, the usual cause of death.
Etiology.
In the
first
edition of this
work (1903)’“
I
traced the iirimary cause of exophthalmic goiter to the pituitary
body (the neural lobe), a nervous connection having been shown by Cyon, a physiologist, to exist between this organ and the thyroid, similar to that traced by myself between the pituitary
body and the adrenals.
The following year Salmon” also concluded that the pituitary body was the seat of primary irrita:-
tion,
though his explanation of the process differed from mine. from my viewpoint, the pituitary body contains the
Briefly,
center of the thyroid
and adrenals, and when certain toxics capable of irritating this center, such as the toxic wastes of pregnancy and menopause, various toxins, toxins of intestinal origin,
endotoxins,
auto-
occur in the blood during a prolonged period both these organs are unduly excited, and. De Smet Sajous:
Salmon
Lc
:
etc.,
bulletin mfidlcal, Oct.
24,
190G.
‘Unternal Secretions," etc., 1st ed., p. 514, 1903, and Clinique Moderne (or Clinical Med.), Aug. 3, 1904.
p.
1861, 1907
224
THYROPARATHYROID DISEASES. socrotions being iiroduced in exuessiYe quantities,
tlioir
ease
That it
dis-
tlie
awakened.
is
e.xophtlialmie goiter occurs in persons predisposed to
by supersensitiYeness of the central nervous system, as in
and other neurotic subjects, is suggested by the frequency with udiicli such disorders proceed or occur with the disease. Eobinson^'* and others have even gone so far as to hysterical, epileptic,
consider of 32
it as
cases,
a form of hysteria.
Grandmaison,’® in a study found hysteria in 19. Abadie ascribes the di.s-
ease to irritation of whichever center governs the svmpathetic
vasodilator branches of the thyroidal vessels.
safed a similar opinion.
Von
Dana®® vouch-
Griife, Ivober, Charcot,
and many
other authorities have directed attention to the sympathetic in this connection, while
and others have found not
necessarily
Virchow, Trousseau, von Eecklinghausen, lesions (which,
occur)
of
the
Now,
branches supply the thyroid. thetic that
posterior
from
cervical it
is
C'yon traced nerve-paths from
lobe
of
which
is
a
my
viewpoint, need
whose through the sympaS)'mpathetic,
the pituitary
(the
sympathetic structure, rich in
chromaflin substance) to the thyroid, and, as I show in the second
volume (pp. 982
ct seq.),
the pituitary contains, in
all likelihood,
the previously unidentified center of the sympathetic system.
One
most evident indications of the influence of the waste accumulation on the genesis of the disease is shown in of the
pregnancy.
Eichardson®' states that "in southern Italy
it
has
long been the custom for the parent to measure the circumference of the daughter’s neck before size
and
after marriage, an increase in
being considered as an evidence of conception.”
Time
has
sanctioned this popular custom, various observers having shown that the thyroid
becomes temporarily congested and enlarged
under the influence of what Audebert®® tenns, in describing a case in which exophthalmic goiter developed during the seventh month the "usual symptoms of hepatic toxiemia.” While :
exophthalmic goiter occurs rarely, the fact remains that
it
is
but the exaggerated expression of a physiological process.
Thus,
’"Robinson: “Etudo sur les syndrome de Graves-Basedow consIddrC manifestation de I'hystfrie,” Paris, 1899. Grandmalson Medeclno moderne, July 7, 1897. ** Dana: New York Medical Journal, June 14, 1902. *’ Richardson: “The Thyroid and Parathyroid Glands,” p. 20, 1905. Audebert: Annales de gyn. et d'obstOtrlque, Sept., 1906.
comme
:
225
EXOPHTHALMIC GOITER.
133 cases of pregnancy, found the thyroid fifth enlarged in 108, the enlargement beginning about the month. The thyroid ceased to increase in volume when thyroid Lang,-'® in a series of
gland was administered, remedy was withdrawn.
and resumed
its
growth when the
That we are dealing with an antitoxic function having for purpose the destruction of wastes of foetal and maternal
its
origin,
is
suggested by the fact that the thyroid gland has long
We
been credited with such a function.
have seen that
my
view
that it increased the opsonic power of the blood has been sus-
Eeid Hunt-'* found, moreover, that when mice were fed on small amounts of thyroid they showed marked resistance tained.
to poisoning
by
acetonitrile.
The
relationship of the pituitary
body with the toxsemia of pregnancy is also shown by the observations of Comte,^® that during pregnancy the pituitary body is also markedly enlarged, a fact confirmed by Launois and ]\Iulon.2“ more recent paper Launois” reaffirms his former conclusion, stating that the anterior lobe (which, as I will show,
page 1072, receives the toxics that awaken the impulses transmitted by the posterior lobe to the thyroid and adrenals) is, during pregnancy, “in a state of marked hyperactivity.”
Another feature which points to the pathogenic role of is that, as stated by Ord and Mackenzie: “In diswhere ordinary goiter prevails, the exophthalmic form is
intoxication tricts
also
met with.”
Grasset observed
France, and Carter,^® in England.
a
similar
The
coincidence
latter
author
in
states,
moreover, that, while, in a certain valley in the West Riding, the
who drink water from hills from goiter, those on the other side of the river, who drink water from hills to the north, suffer a good deal from this growth. Moreover, it is from the latter, or goiter side, that cases of exophthalmic goiter are derived. This clearly suggests that the exophthalmic form is hut a development of inhabitants on one side of the river,
to the south, do not suffer
simple goiter.
“Lang: ^Hunt: -
p.
2,
Indeed, referring to. 3 eases of this “secondary”
Zeitseh.
f.
Geburta.
u.
Gyn., Bd.
xl,
S.
34,
1889.
Jour. Amer. Med. Assoc., July 20, 1907. Comte: ThSse de Doctorat; Lausanne, 1898. Launois and Mulon: Ann. de Gyn#coI. et d’Obst6t.,
2d
1904.
^Launois: Carter:
Th^se de la Faculty des Sciences de Paris, Edinburgh Medical Journal. Oct., 1899.
1904.
s6rle,
vol.
i,
THYROPARATHYROID DISEASES.
22G
Dean D. Lewis-”
type.
some
goiter of
writes
“In
:
these cases a history of
all
Two
years’ standing could be elicited.
goiters were of the diffuse, colloid type,
of these
and one of the mixed So far as I was able histologically, from the
type, partly parenchymatous, partly colloid. to determine, these goiters do not differ,
simple
colloid
or
parenchymatous
Basedow’s symptom-complex.”
unassociated
goiter,
with
Goiter being due, according to
prevailing views, to a telluric poison,
its exophthalmic fonn must likewise be due to such a poison. The relations between bacterial toxins, endotoxins and autotoxins and the thyroid (with the latter organ considered as the
source of one of the antitoxic constituents of the blood) afford
evidence
considerable
in
this
also
Boger and
connection.
Gamier’’® examined the thyroids of 33 cases which had died from scarlet fever, measles, diphtheria, small-pox, typhoid fever, cere-
brospinal meningitis, and septic peritonitis, and found in
all
congestion and hypertrophy with increased secretion, and in two instances
(variola
ha?morrhage.
typhoid
fever,
and.
diphtheria)
^Marine and Lenhart’’^ influenza,
foci
of
also
parench 3unatous
state
that syphilis,
and articular rheumatism are
fre-
quently associated with or followed by thyroid hyperplasia.
B.
Abrahams®” reported 3 cases which developed in the course of active syphilis.
Closely associated with this class of causes
is
that described
by W. H. Thomson,®® i.e., auto-intoxication from the alimentary canal due to imperfect gastro-intestinal digestion of nitrogenous Treatment based on this view, in which meat was foods. banished from the
diet,
gave satisfactory results. is
evident that, from
my
and
intestinal
antiseptics .were used,
^Yhile this view has been eriticised,
it
viewpoint, such poisons can, as well as
any of the others referred to above, bring about the disease in predisposed subjects, by exciting the thyro-adrenal center, and thus cause an excessive production of thyroiodase and adrenoxidase. In a case reported by Aiken,®'* the disease began under ether anaesthesia and persisted six
j^ears.
Surgery, Gynecology and Obstetrics, Oct., 1906. Roger and Gamier: La presse mddlcale, April 19, 1899. Marine and Lenhart: Archives of Internal Medicine, Nov.,
““Lewis:
Philadelphia Medical Journal, Feb. “'Thomson: Medical Record. Jan. 13. 1900. “ Aiken: Trans. Amer. Ophthal. Soc., 1897.
“•'Abrahams:
9,
1901.
1909.
'227
EXOPHTHALMIC GOITER,
Excessive and jirolonged exertion lias also been known to produce the disease. Overwork is a generally recognized factor. reported a case which came on after climbing rapidly which had a steep mountain.- Harland observed two instances appeared suddenly in soldiers who had been in action in the Daiischer'''''
Boer War.
Potain^® called attention to the fact that violent
formed the starting point of exophthalmic awakens symptoms quite similar to this disease, procidence
anger, which has goiter,
of the eye-balls, trembling, violent palpitations, sweating, diaiv
psychical
rhoea,
disturbances,
accumulate in the organism
In
etc.
all
such cases wastes
more rapidly than they can be
hydrolyzed into eliminable products, and the disease is brought about precisely as in all the forms of toxremia previously reviewed.
Fright and other violent emotions, which are relatively frequent causes of the disease, bring
though kindred, process.
and Sir Charles
Bell, accord-
person in intense terror in the fol-
“The heart
lowing words: it
Damdn
Carter,®'^ describe a
ing to
on through a different,
it
beats quickly
and
violently, so that
palpitates or knocks 'against the ribs; there is trembling of all
muscles
the
of
the
body; the eyes
start
forward,
and the
uncovered and protimding eye-balls are fixed on the object of
and clammy sweat, and
terror; the skin breaks out into a cold
tbe face and neck are flushed or jiallid fected.”
The resemblance
of these
;
the intestines are af-
phenomena
of exophthalmic goiter is obvious.
refer,
I
to the
sjnnptoms
elsewhere in this
volume, to the sympathetic center as the sensoriwn commune, in the sense that it bears the brunt of violent emotions, shocks, etc., as
one of the most sensitive of
Carter correctly says, intense terror
all is
somatic centers.
I7ow, as
“a condition in which the
somatic nervous system
is, for the time being, almost paralyzed.” Traumatic shock, blows upon the head, etc., may produce the
disease in a similar way, the violent concussion to
sympathetic center basal
centers,
is
which the and
subjected, along with the other cerebral
being tbe cause of tbe molecular
disturbance.
Delorme and Leniez,®® for examjile, reported 2 cases in “
Dauscher; Wiener med. Presse, Feb. 17, 1899. “Potain; Revue Intern, de mfid. et de chir., Oct. 10, Carter: Edinburgh Medical Journal, Oct., 1899. ™ Delorme and Leniez: Le bulletin mddical, July 20, 15
1895.
1910.
officers
THYROPARATHYROID DISEASES.
228 had been
ivlio
from their
tliroivn
pavement on their heads. two months
in the other,
by c.xophthalmie
though
etc.,
and one montli
later
They report a similar who had fallen from a roof,
goiter.
morbid
If the
tlie
in botli cerebral concus-
later in the one,
less severe case in a soldier
striking his head. shock,
was
Tliere
sion, followed
and had struck
liorses
effects of emotions,
traumatic
are attributed to a molecular disturbance of the
sympathetic center,
—
—which governs the
caliber of the arterioles,
it will become apparent that the morbid process that prevails under the influence of toxics likewise applies here.
We
have seen that poisons, by exciting tbe syunpathetic
thyro-adrenal center, so exaggerate the functional activity of the thyroid and adrenals that the characteristic action of an excess of thyroid secretion on phosphorus oxidation manifests
general
With
vasodilation.
fright
it«elf, viz.,
any violent emotion
or
capable of jiaralyzing the functions of the same center, we have general relaxation of
all arterioles
symptoms
governs, the acute
temporary exacerbation of the thijroid
which the sympathetic center
of fear being the expression of a
this vasodilation, including those of
and adrenals, and,
arterial blood in these organs.
therefore, 'an
abnormal influx of
This moans for them, as shown
in the salivary gland, a corresponding increase
by Claude Bernard
In the majority of such cases the result-
of functional activity.
ing disturbances, though sometimes severe, are either recovered
from
as soon as the central molecular equililirium is restored or,
if this restoration
docs not occur,
it
may
manifest
itself 1)V
other
however, heredity happens to predispose the victim of fright, shock, etc., to e.xophthalmic goiter, tliis disease is the one which develops; the circulation receiving an excess of thyroid disorders.
If,
becomes excessive, and the general vasodilation, the dcus ex niachina of the morbid
secretion, the oxidation of cellular phosphorus
process,
is
perpetuated.
prevailing view that heredity influences greatly the development of the disease is based on a sound foundation.
The
Among
the examples
Oesterreicher,*®
in
may
which
be cited the family referred tn by an hysterical woman’s 10 children
included 8 cases of exophthalmic goiter.
™
Oesterreiehor:
Paris, 1894.
cited
by
Chamberlain:
Ono
"Maladle
do
of these had 4 nasedow,"
p.
13,
229
EXOPHTHALMIC GOITER.
orandchildren, 3 of which suffered from the disease, while the Hare'*“ reported a case in a girl,
fourth was hysterical.
whose
great-grandmother and grandmother suffered from exophthalmic goiter, and whose great-aunt, aunt, and mother suffered from goiter, which increased with each pregnancy in the mother’s
exophthalmic goiter in the
Grober^’- reported 4 eases of
case.
same family, a brother, two
sisters,
and a
E. G. Curtin^"
niece.
collected 40 cases of the disease in 15 families.
Treatment.
—The
great value of thyroid preparations in
hypothyroidia suggests that they should prove harmful in the opposite condition, hyperthyroidia, and particularly in its most
marked
type,
exophthalmic
record suggest that such
is
Indeed,
goiter.
many
cases
on
But, in the light of the
the case.
views submitted in the foregoing pages, the reason for these
untoward
effects, is
plain:
they were due to the empirical use of
these powerful agents and regardless of the stage of the disease
and of dosage.
We
have seem that exophthalmic goiter
three stages
:
is
divisible
the erethic, that during which there
is
sensitization of the phosphorus of all tissues to oxidation
abnormally rapid cellular metabolism
into
excessive
and
the transitional, during
;
which the overactive thyroid has rmdergone sufficient fibrosis to produce only such secretion as is needed by the body, to carry
on
its
functions,
and the m,yxcedematous, during which advanc-
ing sclerosis of the gland
is
increasingly inhibiting
until these cease
and death oecurs.
the erethic stage
tlie
It
is
its
functions
apparent that during
use of thyroid could but add fuel to the
fire; that in the transitional it
might prove useful to arrest the which is inducing sclerosis, by work, and finally that in the myxoedema-
excessive activity of the thyroid, relieving it of part of its
tous
it
should prove invaluable, as
life-saving measure.
An
it
does in myxoedema, as a
even finer subdivision
is
necessary,
however, one in which the primary cause of the disorder is taken into account, if satisfactory results are to bo obtained. During the erethic stage, as a general rule, thyroid and iodine preparations are productive of serious harm. They enhance inordinately the oxidation of cellular phosphorus in all tissues
“
Hare;
^Grober: Curtin;
Intern. Medical Magazine, April, 1898. Medizinische Klinik, Aug. Jfi, 1908. Trans. Amer. Climatol. Assoc., Sept., 1888.
and
THYROPARATHYROID DISEASES.
230
the general vaso-dilation, n-hieh, as 1 have
increase, tliereby,
shown, underlies
the major phenomena of the disease.
all
In
certain mild cases that are clearly due to a to.xajinia of ovarian, uterine, or intestinal origin, thyroid is valuable (I have seen
cause comjilete retrogression of the goiter) 1
in small doses,
it
i.e.,
grain (O.OGG Gm.) of the desiccated gland during each meal,
with abstention from meats wastes
;
in its entirety, the
aim should be
to
and particularly of the
arteries,
volume of thyroid
to decrease the
formation of
but wdiere the symptom-comple.x of the disease
to.xic
present
promote constriction of the which control the
arterioles
admitted into the organs, including the
arterial blood
itself,
is
the post-orbital vessels, and the cardiac muscle.
my opinion,
Huchard obtained good results from ergot and hydrobromate of quinine. The latter drug has also been highly recommended in this country by Forchheimer. It may be given in 3-grain doses (0.198 Gm.) It is because of this action, in
that
3 times daily in capsules, increasing the dose until 5-grain doses
(0.33
Gm.)
To prevent
are given.
unpleasant
its
effects,
which
often occur promptly, and reduce the erethism of the cerebral centers
(those of the pituitary in particular)
Gm.) grains (0.99 Gm.)
grains
(1.32
of
sodium bromide on
of chloral hydrate
if
I
also give
retiring,
20
ndding 15
the bromides do not
counteract the insomnia.
Some
highly nervous women, especially those
who
suffer
from pseudo-liysteria, any preparation of quinine seems to increase discomfort. In these, tlie bromides at night, with chloral if necessarj' to counteract insomnia, should be supplemented by the u.se of phenacetin in the daytime, 5 grains (0.33 Gm.), gradually increasing the dose until 15 grains (0.99 Gm.) are taken three times daily. As stated above, the bromide reduces tbe pathogenic hypersensitiv-eness of the cerebral centers; the phenacetin maintains this action by causing constriction of the
—
which supply them with blood a common action of the coal-tar products (of which phenacetin is the safest), as I arterioles
point out in the second volume.'*®
The
favorable effects obtained by
pituitary gland are explainable in
« See vol. « Renon and
li,
p.
128.1
Delille:
to 1291. Hull. gfn.
Fenon and
Delille'*'*
much the same manner.
do Thfirap.,
May
„ 8,
190(.
with
In
231
EXOPHTHALMIC GOITER.
Gm.) of the whole gland (ox), which they subsequently deemed advisable to increase to 71/2 grains improve(0.5 Gm.) in divided doses daily, they obtained marked
doses of -JV2 gi’ains (0.3
Hallion and Carrion''® then found experimentally that pituitary extracts ‘‘'always produced their effects by raising the
ment.
arterial tension,”
constrictor action
producing at the same time “an intense vasoupon the thyroid body.” Briefly, we have
—the
here precisely the phj'siological action necessarj^ strictor
power of the adrenal component of
tlie
vasocon-
pituitary gland
superseding the vasodilator action of the thyroid, the underlying cause of the disease. 'The to
morbid
effects of
the excessive oxidation of phosphorus
which the cellular elements are subjected require attention. resulting exhaustion of the phosphorus in the muscular layer
The
of the. arteries aids powerfully the action of the depressor nerve ill
keeping the general vasodilation, including that of the thy-
roidal vessels, thus keeping
must, therefore, be replaced.
up the disease. This phosphorus Hence the value of sodium phos-
phate, noted long by ICocher, Trachewski, A^etlesen (40 cases),
and
others,
and of the glycero-phosphate of sodium in 20-grain M. Allen Starr though none of
—
doses three times daily, noted by
knew the modus operandi of these agents. Of great importance to enhance the curative process is the free use of saline solution by enteroclysis and hj^poderraoelysis. The fonner, given at 108° F., sometimes suffices when, after clearing out the intestines by means of an enema, the solution,
these autliors
using a quart at a time, considerable absorption.
is
retained sufficiently long to insure
If this
is
not the case, hj^podermoclysis
every other da}q regulating the quantity according to the case,
By
indicated.
is
increasing markedly the osmotic properties and
the viscidity of the blood,
its toxicity
and
its
exciting action on
the thyro-adrenal center are greatly reduced, and the elimination of is
tlie
pathogenic poisons by the kidneys and the intestinal tract
greatly enhanced.
The
must he carefully sought and, if removed. In cases due to pregnancy, menopause, and inadequate ovarian development, the disorder is mainly due to causative condition
possilile,
inability
of
the thyroparatliyroid
“Hallion and Carrion:
Soc. do Thdrap.,
apparatus to neutralize the March
13,
1907.
232
THYROPAUATHYROID DISEASES.
increasing tide of wastes
tlie blood eontains. The organ is abnormally stimulated, in the sense that its arterioles are widely opened to allow a vastly gi-eater volume of arterial blood than usual to enter it, and it heeomes enlarged. Here, thyroid
preparations, starting with 1 grain (0.006 Gm.) t.i.d. of the dried gland, are of great value by compensating for the organ’s If the toxasmia
deficiency.
he banished,
and free
is
of intestinal origin,
saline
purgation
—
in
meats should
addition
to
the
—
measures advocated in the preceding two paragraphs is indicated. Highly nervous or pseudo-hysteric cases are also helped
by the bromide, phcnacetin, and saline solution treatment, but rest in these cases and in those due to traumatic shock is of great importance. In fact, it must be borne in mind that exertion increases toxic waste formation, and, therefore, the asset of pathogenic poisons, and that rest
is
always indicated in these
cases.
from animals deprived of their thyroid Ballet and Enriquez’s dog serum, Mobius’s sheep serum, or “antithjToidin,” Eogers and Beebe’s serum, obtained from rabbits or sheep inoculated with extracts of exophthalmic Various
obtained
sera
:
goiter, are all of value in that they are all antitoxic substances
which aid the blood in neutralizing the pathogenic poisons. This applies also to Lanz’s results with the milk of thyroidectomized goats’ milk, which gives the same reactions as blood-
serum in so far as its antitoxic constituents are concerned. During the transitional stage the treatment depends entirely upon the progress made by the atrophic process. As a rule, howsigns
ever,
of
myxeedema
are
already present; in that case
thyroid preparations are indicated, as they are during the myxee-
dematous
stage.
The
latter is virtually a case of
mj'xiedema and
requires the measures enumerated under that heading in the
preceding chapter.
marked tendency
In both these stages, however, there
to cardiac failure,
and
is
a
digitalis or strophan-
thus are precious adjuvants.
When cated
:
medicinal treatment
fails,
surgical measures are indi-
partial thyroidectomy or, as frequently done hy the ttlayo
brothers, ligation of the thyroid arteries
—a
measure quite in
keeping with the aim of the treatment detailed above.
—
CriAPTEE
VI.
THE ADEEHAL SYSTEM AND FUNCTIONAL ACTIVITY. By
“adrenal system,” I
three organs studied so far,
mean a
viz.,
and the tliyroparathyi’oid apparatus, taining, as previously stated
center of the two others. assert itself
when we
functional union of the
the pituitary body, the adrenals, tlie
first-named organ con-
(see also p.
610), ihe governing
The importance of this union will
consider such diseases as acromegaly, which,
though due primarily to a lesion of the pituitary, manifest themselves through their influence upon the adrenals and the thyroparathyroid apparatus.
To make
this
and other questions
intelligible,
however,
necessary to show that what I have termed adrenoxidase
it is
(the
oxidizing substance of adrenal origin) circulates in all organs in conjunction, of course, with the thy ropara thyroid secretion,
though the
latter will
not be mentioned, to avoid confusion.
Even the nervous system, we dase,
by adrenoxi-
shall see, is traversed
thus bringing the neuron itself within the field of the
general circulation.
ADRENOXIDASE AND THE MOTOR NERVES IN THEIR RELATION TO MUSCULAR CONTRACTION. The functions.
skeletal muscles stand apart in respect to
The sympathetic system
striped muscular fibers elsewhere,
known
to
supplies
and yet
extend to the extremities.
vasomotor
nerves
this system
to is
unnot
Again, vasoconstrictors
and vasodilators are said
to accompany the larger nerve-bundles, the sciatic, for instance; but a survey of the field distinctly shows that the evidence as to the existence of separate vasoconstrictors is purely inferential. Since the sympathetic
nerve
does not appear to send subdivisions to this class of muscles, the association of constrictors of another source
introduces an ele-
ment
of confusion, not only as regards the peripheral structures themselves, but particularly in respect to the central origin of the two systems classed under the one single term of “vaso(
233 )
THE ADRENAL SYSTEM AND FUNCTIONAL
234
motors.” question,
ACTIVITY.
As it is imjiossible to proceed witliout clearing this we will first ascertain whether the prevailing views as
to the physiology of the circulation in the
my own
not, in the light of
Adrenoxidase AND
]\I
muscular system
may
conceptions, be subject to change.
YOSINOGEN.— In
the production of
muscular contraction a nerve-impulse is of course transmitted to the muscular elements; but how are this impulse and the resulting contraction related to the functions of the blood itself?
This question
is
suggested by the role I have assigned to the
oxidizing substance or adrenoxidase.
Stewart'
refers
to
contraction as follows:
the
thermal
“When
phenomena
perature rises; the jjroduction of heat in is
most distinct when the muscle
of
a muscle contracts,
is
proved for single contractions.
it is
muscular tem-
its
This
increased.
tetanized, but has also been
The change
can be detected by a delicate mercury- or
temperature
of
air-
thermometer;
and, indeed, a thermometer thrust among the thigh-muscles of a dog may rise as much as 1° to 2° C. when the muscles
phenomenon of hyperoxidation through suprarenal overactivity we have suggested when studying the action of drugs. This affords a are
thrown into tetanus.”
first clue:
If the
That tetanus
is
a
plasma contains an oxidizing substance, the
chemical changes in muscular tissue during contraction
—
i.c.,
absorption of oxygen, increased production of carbon dioxide,
change of reaction from neutral or alkaline to the
formation
of
sarcolactic
acid
—
clearly
acid,
and
suggest
finally
that
the
and the mechanical energy utilized may be due to an increased supply of oxygen through the agency Indeed, Ivronecker has shown of the oxidizing substance. that “the injection of arterial blood or even of an oxidizing contractile
process
agent like potassium permanganate into the vessels of an If an agency hausted muscle also causes restoration.”
remote in
composition from the
e.x-
so
normal organic fluids can power an exhausted mus-
restore merely through its oxidizing
eminently ph}'siologieal a fluid as the blood-plasma, charged with oxygen in loose comhination, must surely possess Indeed, the link seems to correspondingly active properties. cle,
1
so
Stewart:
“Manual
of Physiology,” p. R98.
—
235
ADRENOXIDASB AND MYOSINOGEN. be a strong one
if
the full
meaning
of the following sentence
from Foster’s “Physiology” (sixth edition) is gathered: “We might compare a living muscle to a number of fine, transIf we parent, membranous tubes containing Tjlood-pt'asma.” also recall the fact that capillaries do
not possess contractile .
and that arterioles represent the ultimate subdivision which vasomotor nerves are distributed, it becomes clear that we have all the mechanical elements necessary to account fibers
to
some unexplained phenomena that attend muscular contraction. An impulse capable of causing a change of caliber of a peripheral arteriole would thus suddenly admit more arterial for
—
more oxygen-laden plasma into the “fine, transparent, membranous tubes,” and contraction, an inherent property of muscular tissue, would follow. blood
i.e.,
The
prevailing
views
as
to
the
nature
of
the
j^roeess
through which the mechanical energy utilized during muscular activity cause contraction or retraction
from
selections
Professor
Foster’s
may
te.xt.
be illustrated by
Eeferring
to
the
chemical analogy between the axis-cylinder and .muscle-tissue,
“We
he says:
have no satisfactory evidence that in a nerve
even repeated nervous impulses can give
rise to an acid re“nor have we satisfactory evidence that the progress of a nervous impulse is accompanied by any setting
action”
.
.
.
form of heat.” In the summai’y, referring phenomena, he remarks: “This muscle-impulse, of which we know hardly more than that it is marked by a current of action, travels from each end-plate in both direcfree of energy in the to the terminal
tions to the end of the fiber, all events,
where
it
appears to be lost; at
we do not know what becomes
of it. As this impulse-wave, whose development takes place entirely within the latent period, leaves the end-plate, it is followed by an explosive
decomposition of material, leading to a discharge of carbonic acid, to the appearance of some substance or substances, with
an acid reaction, and probably of other unknown things, with a considerable development of heat. This explosive deconi]X)sition gives rise to the visible contraction-wave, which travels behind the invisible muscle-impulse at about the same rate, but with a vastly increased wave-length. The fiber, as the wave passes over it, swells and shortens, and thus brings its
two
THE ADRENAL SYSTEM AND FUNCTIONAL
236
When
ends nearer together.
ACTIVITY.
repeated shocks are given, wave
follows wave of nervous impulse, muscle-impulse, and visible
contraction; but the last do not keep distinct; they are fused into the continued shortening which
The
we
call tetanus.”
word, “tetanus,” stands as the highest expression
last
of a rapid succession of nervous impulses; hut, viewed
from
my
standpoint, this succession of impulses can as readily produce
and give
successive variations of vascular caliber,
rise to pre-
the phenomena, witnessed, by admitting the oxidizing sub-
cisely
“membranous
stance of the blood-plasma into the fine,
The shock experienced when
tubes.”
the current
is
turned “on” or “off”
further suggests that the latter process
is
the true one.
mere passage through
a
of
nerve
a
constant
does
not,
current
of
uniform
“The
intensity
under any circumstances,” says
Professor Foster, “act as a stimulus generating a nervous im-
only set up when the current either from the nerve. It is the entrance or the exit of the current, and not the continuance of the “It is the sudden current, which is the stimulus.” change from one condition to another, and not the condition
pulse; such an impulse
is
into or is shut off
falls
.
itself,
.
.
which causes the nervous impulse.”*
The confusion that attends manner in which muscular tissue contract
is
newer conceptions outlined in the the
various
causal
views
as
to
the
physiologically caused to
readily accounted for when,
is
dissociate
prevailing
in
the light of
last chapter,
elements
of
we
the
analytically
muscular
activity.
Indeed, we have seen that various phenomena ascribed to the sympathetic system belonged to the domain of the adrenals
have tenued the adrenal system; we are again brought to realize that in all organs certain functions must likewise, and for the same reasons, be disconnected from
i.e.,
to
what
I
immediate purpose in the tissues. Thus, the fact that the musc\o-iinpiilse, which “travels from each end-plate in both directions to the end of the fiber, where others
it
as
regards
their
appears to be lost,”
though
causal,
element
material, etc.,” through
*
All Italics are
is
my
own.
at present considered as an inherent, of the “explosive decomposition of
its activity as
a physiological stimulus.
—
—
ADRENOXIDASE AND MYOSINOGEN.
But
we can separate
if
237
these elements of the process into two
a nervous impulse to the muscular the elements themselves, and (2) a simultaneous change in impulse leaves caliber of the local arterioles, the fact that as the viz.:
distinct parts,
(1)
followed by an explosive decomposition of stand as material, leading a discharge of carbonic acid,” will necesbecomes Such a division the only result to be expected. sary in the light of my conception of the process.
tlie
end-plate “it
is
While the nerve-impulses only have for their purpose i.e., the bloodto excite and govern contraction, the blood becomes the substance oxidizing plasma mainly through its factor through which the chemical process to which contractile
—
—
work tion
due
is
suddenly awakened.
is
per se
feature of this concep-
—
must be laid since it applies organs is that it dissociates from the oxidation process a stimulus which does not belong to it and which, there-
upon which particular
to all
A
stress
—
“We
fore, introduces elements of confusion.
Stewart, “in what the
cannot
muscular contraction in the intact body really
how
differs
it
from
tell,” says
‘natural’ or ‘physiological’ stimulus to
artificial
stimuli.”
consists,
nor
Believed of this au-
tonomous agency the organic physico-chemical processes enter within the limits of exact investigation.
Oxygen
in
other fields of thermochemistry
is
kno'wm to
which “explosive deawakened and sustained. That it fulfills the same role in this connection, some complex organic compound in the muscular fibers constituting the primary source of en-
constitute the reactionary agent through
composition”
ergy
or
is
fuel,
is
Under
probable.
these
passive “irritability” of a living muscle
circumstances
the
would be maintained
by a continuous reaction in which the reagents would he these compounds i.e., hydrocar])ons and the oxygen held in loose
—
combination in the blood, particularly the hlood-plasma, which penetrates
the
contractile
elements
themselves.
This
irrita-
would then become abruptly converted into contractility when the blood-supply i.e., the plasma in the contractile fibers ^\vould be increased through the arrival of more oxygen. bility
—
Considerable
duced
is
familiar
evidence besides
that
already
ad-
available in support of this conception of the general
physiology
of
muscle-tissue.
Although continuous muscular
THE ADRENAL SYSTEM AND FUNCTIONAL
238
contractility
is
generally thought to be associated with nerve-
impulse, destruction of does not cause
ACTIVITY.
it
in this particular
all
nervous connection with a muscle
to lose its excitability. is
shown by the
Its inherent property
fact that, although the apex
of the heart contains no nerve or nerve-cells,
responds to stimulation.
nevertheless
it
Even when detached from the body,
muscles preserve their contractility for a time under suitable conditions. This would appear to eliminate the need of further energy to account for the phenomena witnessed; but the
contrary
is
the case, since
it
shows why .muscular
tissue,
owing
to its inherent irritability, responds to various stimuli: vital,
physico-chemical, and mechanical. Electricit}'^, we know, acts as a powerful stimulus, but heat alone acts in precisely the same manner if the temperature is adequate and is electrical,
marked contraction may thus be caused when reached, and violent activity induced before the mus-
raised rapidly;
30° C. cle is
same
is
Chemical stimuli
heated to 45 degrees. effect,
will
produce the
provided the reaction induced occurs with
suffi-
cient rapidity.
That the nervous impulse
is
not the source of mechanical
energy utilized under these circumstances,
is
shown by the
fact
that a chemical stimulus applied to a nerve, ammonia, for instance, will not stimulate
it
though
various acids, hydrochloric, acetic,
it
will excite the
etc.,
will
muscle;
give rise to the
same phenomena. “Certain poisons (curare) cause the motor nerves to become completely incapable of action,” says iM. Duval, “and, therefore, incapable of transmitting irritation to a muscle; nevertheless, under these circumstances, the excited
muscle can directly pass from the state of rest to that of activity (Claude Bernard, Kolliker) ; the ultimate and fine nervous ramifications that they contain take no part in this irritability, since the poisons referred to kill .mainly the intra-
A motor nerve muscular endings of the nerves (Vulpian). separated from the cerebro-spinal axis loses, after four days, inall excitability; the muscle, on the contrary, previously than more excitable nervated by this nerve remains directly months (Longet).” That muscle is directly and independently excitable by a large number of stimuli is evident; that oxygen should. three
—
239
ADRENOXIDASE AND MYOSINOOEN. exacerbations
through
of
physico-chemical
continuous
a
action of which its tissues are the scat while state,
the passive
in
he able suddenly to awaken the active state
AVhen the muscle
is
re-
as clear.
is
in the passive state, the transformation
upon the continuous reaction manifests heat; while, when it is active, it manifests itself
of energy incident self
as
Armand
greater heat plus mechanical work.
it-
as
Gautier has as-
certained that a working muscle took up nine times more blood than a resting one, and that the ratio of carbonic acid given
by it or transmitted to the venous blood was nearly one hundred times greater. This raises the question as to whether off
tl:e
work
conversion of chemical energy into the mechanical
upon which contraction depends must
A
heat energy. based on voltaic
showed
Carnot’s investigations,
cell
in
be transformed into
that,
just
in
as
a
which the chemical potential at once appears
under the form, of intermediate
first
study of this question by Professor Gautier,
state
without
electricity
of
heat,
can
so
passing
through
intramuscular
tlie
chemical
energy become directly transformed into work. Indeed, he found that 65° C. (149° F.) would represent the final temperature of an active muscle, were
conclusion that “a mistake direct
transformation
tension,
of
it
otherwise, and reached the
contracts
the
and works owing
chemical
potential
into
to
a
elastic
without ever requiring the intervention of the heat
which theoretically accounts for internal co.mbustions.” These facts seem to me to warrant the deductions 1. That the mechanical energy utilized by living voluntary :
muscles in the passive state
is converted chemical energy, the a reaction in the muscular contractile elements during which various compounds, mainly hydrocarbons, are oxidized. 2. That active muscular worh is the result of an exacerba-
result of
tion of the activity of this mechanical process, attended with a direct transformation of the passive potential: i.e., irritability, into the active potential:
i.e.,
contractility.
The
suggestion that the reaction occurs in the living contractile elements themselves cannot, for obvious reasons, be demonstrated experimentally. But if we associate Foster’s
comparison of a living .muscle to parent,
‘ka number of fine, transmembranous tubes containing blood-plasma” with my
—
—
THE ADRENAL SYSTEM AND FUNCTIONAL
240
ACTIVITY.
conception of the nature of blood-plasma as an excipient for an oxidizing agent of adreno-pulmonary origin, on the one side, and, on the otlier, recall the view of Eugleniann, that a
from the bright bands of the
Iluid substance passes
the interstitial disks
—
into the dark bands
i.c.,
— the intimate process would be as follows
fiber
i.e.,
the contractile
The hydrocarhon compounds would occupy the contractile dishs, while the oxidizing substance would fill the interstitial disks, and on the proportion of the latter entering the contractile disks would depend the activity of the oxidation process and the degree of contraction.
d isks,
:
Further evidence that the general process outlined prevails
may
substance
be obtained by tracing the identity of myosin
found in the muscles after death.
:
the
“While dead
muscle contains myosin, albumin and other proteids, extractives,
and certain insoluble matters, together with gelatinous and other substances not referable to the muscle-substance itself,” says Professor Foster, “living muscle contains no myosin,^ but
some substance or substances which bear somewhat the same relation to myosin that the antecedents of fibrin do to fibrin, and which give rise to myosin upon the death of the muscle. There are, indeed, reasons for thinking that the myosin arises from the conversion of a previously existing body which may be called myosinogen, and that the conversion takes place, or may take place, by the action of a special ferment, the conversion of myosinogen into myosin being very analogous to We may, in fact, the conversion of fibrinogen info fibrin. speak of rigor mortis as characterized by a coagulation of the
muscle-plasma comparable to the coagulation of blood-plasma, hut differing from it inasmuch as the product is not fibrin, but myosin.
The
rigidity,
the
loss
of
suppleness,
and the
diminished translucency appear to be, at all events, largely, though probably not wholly, due to the change from the fluid plasma to the solid myosin. We might eompare a living muscle to a
number
blood-plasma.
of fine transparent
When
membranous tubes containing
this blood-plasma entered into the ‘jelly’
many much of
stage of coagidation, the system of tubes would present
of the
“
phenomena
of rigor mortis.
All italics arc our own.
They would
lose
241
ADRENOXIDASE AND MYOSINOGEN.
amount suppleness and transhicenc)', and acquire a certain imporand marked very one There is, however, of. rigidity. the and muscle tant difference between the rigor mortis of
tlieir
coagidation of blood. a
slight
Blood during
change only in
its
its
coagulation undergoes
reaction; but muscle during the
onset of rigor mortis becomes distinctly acid.” of rigot If .myosinogen were the precursor of the myosin
what would its composition probably be and how would become metamorphosed into myosin ?
mortis, it
I
my
have submitted the data sustaining
existence of the oxidizing principle,
view as to the
and have referred
to
it
body derived from the suprarenal glands, which, in passing through the lungs, entered into loose combination with as a
The
oxygen.
labors
Jaquet,
Salkowsky,
Schmiedeberg,
of
Abelous and Biarnes were quoted to show that such a principle had also been found by chemical methods, though its origin remained
unknomi
to them.
If combustion of products of nuclein metabolism in the
blood-plasma, through the presence therein of oxidizing substance, can produce uric acid, it seems reasonable to conclude
same substance
that, if this
is
also present in
should find evidence of a similar action.
myosinogen, we
Not only
this the
is
musportion of muscle-plasma obtained by
case, but the same products of metabolism are found in
cle-serum;
the liquid
Though obtained
rubbing up and expressing fresh muscle.
only in very small quantities, the purin bases, creatin, xanthin,
hypoxanthin, and creatinin, are always found in addition to their end-product, uric acid.
Phosphoric acid
—
a waste-product
derived mainly from the catabolism of nerve tissues
—
is
an-
other link between muscular plasma and that of the general
Of
bodies
should
not
be considered as elements of muscular activity.
Their
his-
blood-stream.
course,
these
various
tory indicates that, along with other albuminoids found, they are
mere passive hosts
of
the
muscular plasma
products of muscular fisstTupathetic nerve, the character of the cells is changed to such a degree that one thinks he has to deal with a completely new organ.” They also refer to tlie experiments of von Wittich. which showed that “excitation of the cervical sympathetic nerve remained without effect of saliva
.
ADRENOXIDASE AND THE LACRYMAL GLANDS.
upon the the same
271
secretion of the parotid gland, if the facial nerve of side
had been torn out from the cranial cavity either All this suggests that the
immediately or some days before.” sympathetic
fibers,
as disconnected
which are
from the
also distributed to the vessels, are
active function as in the lacrymals:
a view strongly sustained by
tlie
experimental observations of
Heidenhain, which showed that the secretion obtained by exciwas very
tation of the sympathetic nerve (in dogs or rabbits)
That similar experiments in the submaxillary gland have given corresponding results is well kno^vn. But the S3unscarce.
pathetic cannot be regarded as a secretory nerve on this account since the secretion is merely the result of a
blood pumped,
as
were,
it
into
the gland
slight excess of
bj'’
the increased
propulsive activity which the stimulated fibers provoked in the spiral muscular, coat of the arterioles.
from Professor Foster’s also be found to show that
If the annexed engraving, taken
work,
is
carefully examined,
the circulation
of
the
intimately associated. of
the
carotid,
while
will
it
organ and the sympathetic
The
arteries
the
veins
ultimately lead to the jugular:
fibers
are
are terminal subdivisions
are
primary channels that
features which emphasize their
Over these are entwined sympathetic from the superior cervical ganglion, which fibers are
functional importance. fibers
inclosed
in
present,
the
a
common
vagus:
sheath
further
with the main
evidence
sensory nerve
that they must,
in
a
measure, govern the quantity of blood distributed to the organ. In fact, this association with the vagus, sufficiently intimate “to form udiat appears to be a single trunk,” almost imposes the deduction that the arterial branches of the latter nerve transmit the afferent or sensory impulses in the reflex arc upon
which the “nervousness” of speakers, actors, etc., depends as “dry-mouth,” or temporary xerostomia, so
to the condition of
frequently observed.
hazard;
it
Such an inosculation
is
not due to mere
strongly suggests that the s}Tnpathetic fibers form
part of the mechanism through which the intraglandular bloodpressure of the organ is governed. All this shows clearly that the influx of blood regulates the secretory activity of the gland', and that we are dealing with
a vasomotor phenomenon.
This idea would seem to be opposed
THE ADRENAL SYSTEM AND FUNCTIONAL
- ST ss
Centralbl.
f.
d.
med. Wissensch., Dd.
d.
xvlil. S. 945,
ges. Physiol., Bd. xxll, S. 12G, 1880.
Luchsinger: Archly Langley: Lor. rit., p. 061. Ostroumoff: PflUger’s Archly., Dd. f.
xll,
S.
219,
1876.
1880.
277
ADRENOXIDASE AND THE SWEAT-GLANDS. of sympathetic origin
is
to observe the effects of stimulating
the abdominal sympathetic,” he refers to the experiments of Gaskell-® who found “ a slight decrease of the blood-flow
through the muscles,”
who observed
and lleidenhain*® “Neither found on
vasoconstriction,
i.c.,
a slight fall of temperature.
direct stimulation,” says Langley, “evidence of the presence of
Bayliss^^ recently reviewed
vasodilator fibers.”
had been recorded on the
cpiestion,
what evidence “It seems
and remarks:
have been almost taken for granted, up to the present time, that the dilators must run in the abdominal sympathetic, but to
the actual evidence for this
that the sympathetic,
t.e.,
is
It is clear
very unsatisfactory.”
the vasomotor system, takes no part
in the process.
Conversely, there
is
evidence to show that the skeletal mus-
contain vasodilator nerves and that the fifth pair presents
cles
which ]3oint to it as their motor nerve. Thus Dastre and Morat^^ obtained dilator effects by stimulating this nerve in attributes
the cranium
and
also
by exciting the Gasserian ganglion, while
Laffont®* caused flushing by stimulating the fifth nerve after the sympathetic fibers anastomosing with to degenerate.
had been allowed
it
GaskelP'* also observed that the branch of the
fifth
distributed
Such
effects
to
the
mylo-hyoid
contained
vasodilators.
cannot be attributed to excessive vasoconstriction when a cranial nerve is the source of dilation, since the only
—in
the light of
views, with the vasa-vasorum of those arteries.
They cause
connection of the latter with the arteries
my
is
dilation or nothing.
Moreover, the manner in which its influence on the muscle manifests itself points to a pure motor
Thus the mylo-hyoid takes part
action. less
says
by transmitting efferent impulses. :
“The
efferent impulses
in deglutition, doubt-
Starling,^® for instance,
from the center pass by the hypo-
glossal nerve to the muscles of the tongue,
by the
“Gaskell: Jour, of Anat. and Physiol., vol. xl, p. 3G0, 1877. Heidenhain; Heidenhain, Alexander u. Gottstoln, Archly t.
fifth to the
»>
Bd. xvl.
S.
1,
Bayllss:
“
ges. Physiol.
Jour, of Physiol., vol. xxvl, p. 173, 1901.
Dastre and Moral:
““Laffont; “ Gaskell:
d.
1878.
"Recherches sur
le Syst.
Nerv.,”
1884.
Cited by Vulplan: C. R. de I’Acad. d. Scl., T. li, p. 981, 1885. Jour, of Anat. and Physiol., vol. xl, p. 720, 1877. “Starling: Schafer’s “T. B. of Physiol.,” vol. li, p. 320, 1900.
THE ADRENAL SYSTEM AND FUNCTIONAL
278
muscle, by
iiiylo-liyoid
glosso-pliaryngeal,
llie
branches of the vagus, the
the pharyngeal
and the spinal accessory nerves
fifth,
to the muscles of the fauces
ACTIVITY.
and pharynx.^’
Conversely, Charles
Bell obtained paralysis of the facial muscles on cutting the
(Quoted by Schafer.^”)
fifth nerve.
When
these observations are supplemented in the light of
the experimental facts previously adduced, and the aggregate is
taken as the basis of analysis, a close functional relationship
between the muscles of the sweat glands and the skeletal muscles not only suggests itself, but the fifth nerve stands out
prominently as the motor nerve of both. Sherrington*^ states that “the nerves of muscles derive
numbers of
from the spinal ganglia.” In the limb muscles of the monkey and cat he** found “from a half
large
their fibers
He
to a quarter of all the nerve fibers to be sensory.”
—muscle
says tliat “these sensory fibers end in end-organs
modified
Golgi-organs,
dles,
bodies.”
As
is
Pacini-organs,
and
in
also
spin-
Pacini
well knouTi, anassthesia of the surface prevents
the development of convulsions:
it is
therefore by paralyzing
the cutaneous sensory end-organs, of nerves connected with the
muscular nerve-supply that these abnormal muscular contracAgain, while Binswanger obtained spasm tions are prevented. reflexly
—
are
the
—
efferent
motor impulses being necessary
factors of the
in various parts of the body by stimulating branches of
fifth
pair,
Sherrington as interpreter of the prevailing
knowledge, states that the gelatinosa which caps the posterior horns and receives all the fibers from the sense organs of the
body surface and muscles extends “without break from the cranial fifth to the lowest coccygeal, inclusive”
The
vasodilator
observed
effects
by Dastre
and
Moral,
Laffont, Gaskell point to the presence in the sweat and skeletal muscles of the head and neck of stricto-dilator nerves belonging
In the light of the above data, it seems probable that this applies to the trunk and extremities as well. What experimental evidence there is to show that an influx to
the fifth pair.
of blood into a gland *>
cited by Schafer:
3"^
Sherrington: Sherrington
***
:
is
not the factor which incites function
Ibid, vol.
Ibid, vol.
ii,
p.
il,
p.
726.
1007.
Jour, of Physiol., vol. xvii, p. 211, 1894.
—
279
ADRENOXIDASE AND THE SWEAT-GLANDS.
views I have submitted are “The action of the Howell/® for instance, writes: sound. nerve-fibers upon the sweat glands cannot be explained as an loses considerable of
—
indirect effect
M^eiglit if the
for instance,
a result of variation in the
as
Experiments have repeatedly shown that, in
blood-flow. eat,
its.
stimulation of the sciatic
still
tlie
calls forth a secretion after
the blood has been shut off from the leg by ligation of the aorta, or indeed after the leg has been amputated for as long as twenty
An
important feature of these experiments, however, is that the secretory activity is of very short duration and that the relaxation of the arterioles and the sudden influx of blood
minutes.”
among nerve
the epithelial cells induced by stimulation of the sciatic
is sufficient
human
beings
accompany a
it
to accoimt for
known
is
it.
Howell
also states that “in
that profuse sweating
may
often
In all of shown in the second volume, there is gen-
pallid skin, as in terror or nausea.”
these conditions, as
eral vasodilation, including of course relaxation of the arterioles,
which
also increases the
lial cells.
M. DuvaE®
growing weaker, sweating of the toe-pads occurs; these are not pigmented they become pale and exsanguine.
heart-action
and
if
volume of blood admitted to the epithemoribund cats, while the
states that in
is
This corresponds with the profuse sweating of death-agony in
human
beings, which is also attended, of course, with pallor an obvious sign that the vascular arterioles are relaxed allowing a temporary influx of blood into the sweat-glands. Finally, as I will show on page 1380, pilocarpine as well as other drugs, nicotine, for
example
—owes
—
its sudorific
properties to the fact that it depresses the sympathetic center, thus causing relaxation of the arterioles. A et, division of the sciatic nerve, through
which the S3Tnpathetic
fibers reach the arterioles of the lower not prevent sweating in the corresponding But we must not lose sight of the fact that the relaxation
e.xtremities,
limb.
does
of all the arterioles of the
body by the drug produces a conmoribimd animals, and that
dition akin to that observed in
under such conditions division of the sciatic would not prevent an influ.x of blood into the gland and cause sweating. The process through which the functions of a sweat-gland Howell: hoc. cit., p. 790. ‘“Duval: “Cours de physiologic, ”
1892.
—
.
THE ADRENAL SYSTEM AND FUNCTIONAL
280
ACTIVITY.
are influenced by variations of blood-flow becomes all the more evident when we take into account its histology and especially
the
manner
in which the muscular elements are disposed. In the light of all this evidence, the following conclusions seem warranted :
The
secretory activity of a sweat-gland is increased hy the circulation of an excess of adrenoxidase-laden plasma in its epithelial and muscular elements. 1.
2. All the intrinsic structures of the gland being thus rendered hyperactive, the secreting activity of the glandular elements is enhanced and the spiral muscles around the coiled and
straight tubes are caused to contract periodically, each contraction causing an outflow of sweat. 3.
The increased supply
of blood
due to dilation of the glandular arterioles by vasodilator impulses received through the secreto-motor nerve of the gland (probably an extension of the fifth including 4.
The
its
is
spinal extension)
secretory activity of a sweat-gland
the volume of blood circulating through
contraction of
through
its
its arterioles
it is
is
reduced when
decreased owing to
by vasoconstrictor impulses, received
sympathetic terminals.
The
capillaries form a close net-work around the coiled and reach down to an extremely thin basement membrane, which, in turn, surrounds the layer of muscular fibers that coil around these tubes. An important feature of this muscular layer, ^^vhich is only separated from the cavity or lumen of the tube by the secreting epithelial cells and their
tubes,
—
endothelial lining,
—
^however,
is
tliat
its
ribbon-like fibers are
wrapped round the tube, and in such a manner as to a gap between their border, throughout their whole length.
spirally
leave
Not
only, therefore,
is
the thin basement
to reach the secreting cells
membrane thus enabled
through the gaps, but the former
actually project through the latter so as to touch the
brane.
Furthermore, the projecting
mem-
cells are so related to
one
another as to form canaliculi-like spaces, which extend from the capillary-covered
membrane completely through
to the
lumen
of the tube (Itanvier).
and Sebaceous Glands. influence of
— Foster
refers to the
the nervous system upon the mammary glands
in
ADRENOXIDASE AND THE MAMMARY AND SEBACEOUS GLANDS.
281
“That both the secretion and ejection the following words: system is shown by of milk are under the control of the nervous but the exact nervous mechanism has not ^Yhile the erection of the nipple 3^t been fully worked out. breast are ceases when the spinal nerves which supply the
common
exjjerience,
divided, the secretion continues,
and
is
not arrested even
when
the sympathetic as well as the spinal nerves are cut.” The nerves that supply these organs and the skin cover-
ing them are the intercostals from the second to the sixth, inclusive ; the thoracic branches of the brachial plexus ; and the descending branches of the cervical plexus, while thetic filaments
accompany
we
In this analysis since the to
mammary
sympa-
all blood-vessels.
will, in
secretion
is
a measure, cover two subjects, carried on in a
that which prevails in sebaceous glands.
manner similar The functional
and the similarity referred to are well the following quotations from the work of W.
process in the latter illustrated in
Eoger
autlior says:
part cells,
we
glands,
the
sebaceous
“Within the membrana
propria of
Williams.'*^
Eeferring to
its
this
secretory
find a stratum of small, irregularly-shaped epithelial
each with a large nucleus (Fig.
1, &).
The
cells of this
region are constantly proliferating, and, as the products of the
become changed and gradually form the secretion.” If the words that we have italicized are placed in immediate sequence, they will be found to describe exactly the histological arrangement of the sweattubes from the delicate membrane to the lumen. “The steps of the process are as follows The cells next the marginal cells (Fig. 1, b) inerease in size and their nuclei duundle. As they approach the center of the acinus their nuclei disappear, and the cells become distended with granules and oil-globules. Finally they burst and their debris forms the secretion, which is discharged.” This also coincides with the manner in which
process gradually shift toward the duct, they
:
sudoriferous glands produce their secretion.
“Lactation
Mr. Williams.
is the outcome of a similar process,” continues “Milk must, therefore, Ije regarded as the prod-
uct of the deliquescence of successive degenerations of epithe-
W. Roger Williams:
“Diseases of the Breast,” London.
1894.
THE ADRENAL SYSTEM AND FUNCTIONAL ACTIVITY.
282
cells 'which
licil
relays of
new
are destroy eel in this process and replaeed by derived by division from other still active
cells
epithelial eells of the part.
Thus we
see that growth, devel-
opment, and seeretion are but slightly varied manifestations of .
eellular .
aetivity
finding
eventuates in lactation process
is alwa3’s
is
gradual.
Creighton’s deseription of
hand
e.xpression
“The complete degree
.
in
funetion
in
different
function that only attained periodically, and the
The it
:
hand with imdoing
following
a brief aeeount of
is
Subsidence of the funetion goes of structure,
and
revival of the
with the building up of strueture.
Variations
intensity in the seeretory foree are measured by
Fig. 1.— Histologicai. Section
Cyst. a,
Fibrous
stratum
stratum,
which correspond
The beginning
c,
to
ways.”
mammary
of
of the
its
of
produets
Wall of a Sebaceous
(Cornil and Rani
ier.)
with connective tissue corpuscles. 6, Hornlfying cells, d, Sebaceous cells.
Marginal
changing aspects of the secreting
aeini.
of the rising function coincides with the be-
and the process occupies the entire During the intervals between its periods
ginning of pregnancy, period of gestation.
of functional activity the breast remains in a quieseent funetionless state: is
the resting stage.
shrunken and surrounded by
fibro-fatty
tissue.
The
acini
are
In this condition the gland a
considerable shriveled
up.
quantity
On
of
miero-
examination of sections of the gland in this stage (Fig. 2) each acinus appears as an alveolar space bounded by a thin layer of fibrous tissue, denuded of epithelium.' Its eonscopical
ADRENOXIDASE AND THE MAMMARY AND SEBACEOUS GLANDS. tents
irregularly-arranged,
are
polymorphic,
epithelial
with large nuclei and scanty surrounding protoplasm.
283 cells, .
.
.
“During the rising function the size of the acini gradThe cells inually increases from that of the resting stage. crease in number and size and acquire more protoplasm. They gradually arrange themselves so as to form a lining membrane for the wall of the acinus
proaches,
is
(Fig. 3), which, as lactation ap-
converted into a regular mosaic.
The
cells
become
granular, irregularly shaped, excavated, and vacuolated, secret-
ing granular and is
mucous
fluids.
always somewhat cnide,
The milk
of the first few days
containing colostrum-cells,
Pig.
2.
Fig.
3.
which
The Mammary Lobule Near the Restino Stage (Upper) and During Functional Activity.
(Creighton.)
are the last of the long series of secretory products during the period of rising fimction.
thrown
off
“The fully-expanded acinus secretion stage.
is
(Fig. 4) in a state of active at least four times as large as that of the resting
contained cells are much more numerous than at any other period, and they form a perfect mosaic, lining the membrana propria. Each cell is flattened and of polyhedric sliape, and has a large nucleus surrounded by a broad zone of Its
protoplasm.
“During the period of subsiding function the organ gradually reveits to the resting stage through the converse series
ADKBNAL SYSTEM AND FUNCTIONAL
284 of changes.
In
ACTIVITY.
this process the cells pass through a succession
of transiormations,
from the forms
characteristic of the per-
mosaic of lactation to those peculiar to the various stages of the subsiding process. These changes are accompanied by fect
constant destruction and renewal of the participating cells. ‘‘With regard to the influence of the nervous system on the mammary secretion, most of those who have studied the subject are agreed that the secretion of milk
is
not directly
under its control. LaflFont,'*however, maintains that the niamnuE possess vasodilutor nerves which, when stimulated, cause augmentation of the quantity of milk secreted; but de Sinet)',''^ who has repeated his experiments, is unable to accept his conclusions.”
Fig
4.
—Expanded
Mammary Acinus, Showing the Arrangement OF Epithelial Mosaic. {Creighton.)
The foregoing
review
not only indicates
the
important
part cellular metabolism plays in the functions of the
mary
glands, but also that the blood
of active functional work.
“The blood
is is
mam-
an important source the ultimate source
it becomes milk only through the and that activity consists largely in a metabolic manufacture by the cell, and in the cell, of the common things brought by the blood into the special things ])resent in the milk. Experimental results tell the same tale.” Another feature which it places on a solid footing when asso-
of milk,” says Foster, “but activity-
of the
cell,
“ Laflont: Comptes-Rendus de I’Acad6inle des Sciences, “ De Slndty: Mdmolrcs de la Socldtd de Dlologle, vol.
1,
vol. jxxxlx, 1879. 1879.
—
—
—
glands. adrbnoxidase and the mammary and sebaceous
285
and one whidi I wish dated with Professor Fosters remark, emphasize, is the identity of the liquid which particularly to
in solution, viz.: hloodholds the various constituents of milk of M. Duval’s, plasma. This is also suggested by a statement “The transsays: who, referring to the formation of cream, reprevessel the of parent portion that remains at the bottom
plasma of the milk that is to say, the milk without We employ the word ‘plasma’ here to establish a globules. the blood. parallelism between the analysis of milk and that of sents the
:
corresponds to the liquor of the blood.” In another chapter the true identity of blood-plasma, owing its antitoxin, to its inherent oxidizing substance or adrenoxidase, will be connection, this as a prophylactic, and its role in
Skimmed milk
etc.,
But, bearing directly upon the question in the presence of plasma i.e., the functional mechanism, point, in the milk forcibly indicates that an important vasoconstrictor In fact, that so system must exist in the mam.mary gland. further studied.
—
careful an investigator as Laffont should have observed vasodilation further emphasizes this, and tends to indicate that a
process similar to that described
by
maxillary functions must prevail,
me i.e.,
in
my
analysis of sub-
indirect vasodilation,
a fact sustained by the counter-experiments of an equally competent physiologist, de Sinety, who was unable to find vasodilators per se. Laffont reached his deduction that vasodilation
occurred by measuring the
blood-pressure
in
the
mammary
artery of a bitch, during lactation, after severing the mamma,ry nerve and stimulating the peripheral segment of the latter. Congestion of the gland and increase of milk-flow followed,
but after cessation of the
artifieial
not arrested, was greatly reduced. clude inferentially that the
stimulation the flow, though
This led Laffont to con-
mammary
gland possessed typical
submaxhave shown that the phenomena upon which
vasodilators similar to those thought to exist in the illary gland.
I
such a deduction could be based, in respect to the latter organ, could be accounted for without vasodilators and dilation
was a mechanical impossibility.
testimony to this
is
that active
Claude Bernard’s own
indirectly afforded by the fact that the
“interference” or “inhibition” theory was introduced by to
account for vasodilation:
him
the existence of which he was
THE ADRENAL SYSTEM AND FUNCTIONAL ACTIVITY.
286
—
first
as lie
had been
in the case of vasoconstriction
—
to
dem-
onstrate.
The
various data reviewed seem to me,
when considered
col-
lectively, to suggest modifications of generally accepted views.
mammary
In the
have seen,
first
second, by latter
a
gland the secreting apparatus is formed, we by an extremely thin basement membrane, and,
single
layer
of
epithelial
secretory
The
cells.
supply the milk-forming elements other than the liquid
which liquid responds to various tests of blood-plasma (Duval) and seems to replace the water secreted by the sweat, salivary, and lacrymal glands. In all three of the latter organs, however, the secreting structures are surrounded by a net-work of cajiillaries. That such is also the case in' the mammary
per
se,
gland
is
evident,
vessels, says:
since
“From
referring to
Piersol,'*^
the glandular
these vessels on the anterior surface of
organ branches penetrate into the glandular mass and
the
pass between the lobules, giving off twigs which break capillaries
inclosing the
A
alveoli.”
up
into
nCt-work of nerve-fila-
ments are also traced to the glandular elements of salivary' and sudoriferous glands a feature also reproduced in the mammiB. Thus, Bohm and von Davidoff,'*® alluding to the :
terminations of the nerves in the
mammary
glands, recall that
they have been studied by means of the methylene-blue method by Dmitrewsky, who found that “the terminal branches form epilamellar
plexuses
outside
the basement
membrane
of
the
from which fine nerve-branches pass through the basement membrane and end on the gland-cells in clusters of alveoli,
They
terminal granules united by fine filaments.”
also state
form capillary net-works surrounding the that “the alveoli.” The ducts when nearing the nipple have an outer vessels
layer of cellular tissue containing a large fibers
and smooth muscular
fibers
which
number
the axial line in direction, though insufficiently so to “spiral” as in the case of the sweat-gland muscles. the
mammary
of elastic
from be termed
depart slightly
gland, suckling, by creating a
But, in
vacuum and
caus-
ing elongation of the nipple, fulfills the function of the latter. “Plersol:
"Normal Histology,”
« Bohm and von p.
361, 1900.
Davldotf:
p.
241,
seventh edition,
1900.
“Text-book of Histology.” translated by Huber,
ADRENOXIDASE AND THE MAMMARY AND SEBACEOUS GLANDS.
We
thus have
all
287
the structural elements of the j^reviously
studied glands present in these.
should also correspond, however’.
Their peripheral mechanisms As to the nervous supjrly,
seen that dilation of arteries was found to be con-
we have
by motor nerves, by Laffont, and that the presence of vasomotors was denied by de Sinety. Hence, the vasodilation must be due to indirect action, especially since Laffont caused it by stimulating these nerves, precisely as Claude Bernard had trolled
The stimulation
done in the case of the submaxillary glands. must, therefore, have caused this
dilation
manner described when the chorda tympani was
the
in
vascular
indirect
question:
i.e.,
That
vessels.
by causing this
stricto-dilation
the
of
conception of the process
is
in
glandular justified
is
further sustained by the experiments of Eohrig,^" Mdio found that a motor nerve, the external spermatic, supplied constrictor fibers
the
to
glandular blood-vessels
in
the
goat,
division of one hrancli of this nerve, the lower,
tion
and that
enhanced secre-
(evidently due to relaxation of the vessels through loss
of their
normal stimulus), while stimulation of the peripheral
end of this subdivision of the nerve decreased the secretion. This clearly suggests that, just as is the case in the submaxillary and other glands, the secretory activity of the organ should be attributed to an increase of the blood coursing through
its
secretory elements.
As to the sympathetic fibers, they are also stated by Roger Williams to “accompany the mammary blood-vessels”; and, as section of a sympathetic nerve is always followed by dilation of the arteries, they can only act as vasoconstrictors here as elsewhere. That all efferent fibers distributed to the gland-
ular elements and to the blood-vessels originate tral
nervous sj'stem
from the cen-
evident when their relationship with the cord, and particularly the results of section immediately below the medulla, are recalled. That a single stream of imis
from the cerebral centers can sustain the entire function that is to say, that part of it under nervous control scarcely needs, under these conditions, to be emphasized. pulses
—
An *“
important characteristic of the functions of the
Rohrlg:
Virchow’s Archiv,
vol.
Ixvii,
187G.
mam-
THE ADRENAL. SYSTEM AND FUNCTIONAL ACTIVITY.
288
mary
however,
glands,
nervous supply
This
is
is
it
is
its
dependence upon their
their is
the case with other organs.
when the
conversion into milk-plasma;
probably merely filtered through
is
propria and the epithelial layer of
cells in
becomes charged with their products. source of the latter; lial
identity of the liquid
The blood-plasma must undergo
realized.
change during
little
deed,
not as great as
readily accounted for
portion of milk
but
that
is
cavities,
in-
membrana
the lobules and thus
Leucocytes are the main
them both
Kadkin'*^ found
and alveolar
lining
the
“wherein
in the epithe-
disintegration
of
their nuclei supplies the milk with a proportion of its nuclein,
amount
the remaining
of the latter being furnished by the These bodies and the oxidizing substance of the blood-plasma not only transfer to the milk their immunizing qualities, but the oxidizing substance is itself a source of
epithelial cells.”
functional energy through which leucocytes and' epithelial cells are
caused to endow the milk with
^luch of the organ’s work “\i\diile
its
experiments
is
not arrested even
as well as the spinal nerves are cut,”
soon
Laffont’s animal, the flow,
when only one
nutritive principles,
therefore automatic.
“the secretion continues and
when the sympathetic control
is
show that, though not
set of nerves is cut.
as
was the case with
arrested, is reduced even
This indicates, when con-
sidered along with the fact that stimulation of the
mammary
end of the nerve increases the gland’s activity, that the nervous supply must not be disregarded, and it also suggests that the sharp line drawn between “active” and “passive” activity, in the case of other organs, and which mainly depends upon nerve-impulses to secreting structures and vascular walls, is Indeed, we are doubtless dealing scarcely applicable here.
with mere fluctuations of activity, called forth, during lactaa feature tion, by afferent impulses to the motor centers: the inand nursing which the rapid formation of milk after In framing our fluence of emotions upon its flow suggest.
summary
of the functional
mechanism
of the
mammary
gland,
not the difference between active and passive activity that we have in mind, but the manner in which fluct-
therefore, it
«Kadkln;
is
Inaugural Dissertation,
1890.
—
289
THE ADRENAL SYSTEM AND THE KIDNEYS. activity
of
nations
The
brought about.
are
actual
process
one, even here, however, is' primarily a mechanical elements secreting since filtration of the blood-plasma into the As blood-pressure torepresents no mean expense of force.
involved,
tally
independent of the normal systemic pressure must account we are relegated to the vessel-walls and their nerve-
for this,
out. supply as the intermediaries through which this is carried mammary of a On the whole, the functional mechanism gland may, in the light of the foregoing facts, be interpieted
as follows
:
The formation
1.
of milk is due to
an exacerbation of
secretory activity, the nutrient fluid being held in reseive by the organ until withdrawn mechanically by the suckling.
Blood-plasma, including
2.
oxidase),
is
the
main
plied to the secretory cells by the
fourth, fifth,
and sixth
When
3.
and is supglandular arterioles when these
constituent of milk,
fluid
vessels are dilated by their
oxidizing substance (adren-
its
motor nerves, the terminals of the
int'ercostais.
the formation of milk is to cease, the arterioles
referred to resume their normal caliber, the result of constrictor
impulses received through the intermediary of their sympathetic nerves.
Kidneys.
—HowelP®
states that “the kidneys receive a rich
supply of nerve-fibers,” but that
“most
histologists have
been
unable to trace any connection between these fibers and the epithelial cells of the
kidney tubules.”
standpoint such a connection as 'I have
now shown
is
Interpreted from
my
not in the least necessar)', since
repeatedly, the function of an organ is
dependent upon the volume of arterial blood circulating through it.
as
My view is fully sustained by tbe prevailing doctrine, since, Howell says, the marked effects obtained during purely physi-
ological experiments are “all explicable
in the blood-flow through the organ.” ,
by the changes produced It becomes a question,
therefore, as to how, lated,
for
and by what nerves this blood-flow is reguas stated by Stewart’*® “increased blood-flow entails
increased secretion.”
‘“Howell: T. B. of Physiol., second edition,' ‘“Stewart: Loc. cit., p. 419.
p. 763,
1907.
— THE ADRENAL SYSTEM AND FUNCTIONAL
290
ACTIVITY.
Tliat the vasodilation necessary to the inception of an ex-
—
acerbation of function
as it
is
in the
subinaxillary gland
occurs in the kidney as well as in the organs previously reviewed,
shown by
is
tlie
experiments of Bradford®® who found that
vasodilator nerves entered the kidney with the vasoconstrictor fibers,
and that when the anterior roots of the eleventh,
twelfth,
and thirteenth dorsal nerve roots were stimulated with induction shocks one second apart, the organ swelled though no sufficiently marked rise of blood-pressure occurred to account for
it.
Stewart®’^ also states that the presence of dilator libers
for the kidney has been “demonstrated in the splanchnic nerves.”
That is
which enhance the flow of urine
these vasodilators
it is
sustained by the prevailing opinion that true secretory nerves,
nerves influencing directly the epithelial elements, are not
i.e.,
present in the kidnc3\
The
source of these renal vasodilator nerves
by the fact that
it
is
is
disclosed
only by stimulating the splanchnic that
the caliber of the renal arteries
is
Indeed, Eckhard®-
increased.
found that stimulation of the vagi below the diaphragm does not influence the flow of urine. This imposed the conclusion that even the vasodilators of the kidney belong to the sjin'
confirmed by the researches of Berkley®® which showed that “the innervation of the kidney is de-
pathetic system.
This
is
pendent directly upon the great svnnpathetic and histologically speaking, it is found that all the nerves of the glands belong to ;
the non-medullated type.”
Briefly,
the vasodilator nerves of
the kidney which promote the flow of urine belong to the sympathetic system.
How
are the arteries restored to their normal caliber
—
^that
compatible with the normal excretion of urine? In the light of the conclusions submitted in the foregoing pages the kidneys should receive filaments capable of causing
when the That such
constriction of the renal arteries
the organs
is
to be decreased.
shown experimentally by many “Bradford: '>
Stewart:
“Eckhard: “Berkley:
excretory activity of is
observers.
the case has been
In
the
dog,
Jour, of Physiol., vol. x, p. 358, 1889. Lor. cit., p. 152. Cited by Starling: Schafer’s “T. B. of Physiol.," vol. Jour, of Path, and Bact., vol. 1, p. 40G, 1893. ,
I,
the
p. 645.
THE ADRENAL SYSTEM AND THE KIDNEYS.
291
vasoconstrictor nerves leave the cord, according to Stewart, ‘diy
the anterior roots of the sixth thoracic to the second
nerves and especially the last three thoracic.”
lumbar
Langley®* ob-
and upper part lumbar nerve, and slower, though still great, pallor on stimulating the second lumbar in the eat. As stated by Starling®® a rise of the general bloodpressure coincides with marked shrinkage of the kidney, so that the effects observed by Langley must be of vasomotor origin. served prompt and great pallor of the kidney of the ureter on stimulating the first
Moreover various toxics known to raise the vascular pressure produce effects similar to stimulation of the renal vasomotor nerves. to
Thus Sakussow®®
recently found that digitalin in
1
1,000,000 solution caused contraction of the renal vessels.
The same
effect
adrenalin.
The
ford®^
was obtained from a 1
to 1,000,000 solution of
latter result accounts for the fact that
Brad-
obtained renal vasoconstriction by stimulating, besides
the nerves included within the above limits, the fourth fifth thoracic,
thus including
among
and
those stimulated, the fibers
which pass to the splanchnic and thence to the kidneys. He found, however, that the most active vasomotor nerves were those of eleventh, twelfth,
and thirteenth thoracic.
That
all
these
filaments are distributed, to the arterioles in the organs has not
only been established histologically, but as stated by Bohm, Davidoff, and Huber,®® “from the plexuses surrounding the vessels small cells of
branches are given
off
which end on the muscle-
the media.
As to the source of the vasoconstrictor fibers, it corresponds with that of the vasoconstrictors supplied to other abdominal organs, the splanchnic. Thus Hollner®® and others have traced from the sympathetic chain through the great and small splanchnics to the solar plexus, and thence to a network of fibers lying in the fat between the adrenal and the kidney. these nerves,
Several of the filaments were found by Nollner to enter the latter with the renal artery.
M Langley:
“ Starling: “ Sakussow '’'Bradford:
® Bohm,
:
Schafer's “T. B. of Physiol.,” vol. IhUl, vol. 1, p. 645. Vratch, April 10, 1904.
It,
p. 643.
Jour, of Physiol., vol. x, p. 358, 1896.
Davidoff and Huber: too. off., p. 335, 1905. “Nollner: Beitrage z. Anat. u. Physiol, v. Eckhard, Bd. 19
Iv,
S. 139, 1869.
THE ADRENAL SYSTEM AND FUNCTIONAL ACTIVITY.
292
We
thus find ourselves in the presence of the surprising
and vasoconstrictor nerves
fact that both the vasodilator
kidneys
—those which preside over the functions
are of s}Tupathetic origin. is
of tlie
of these organs,
Indeed, as will he shown later, this
a characteristic of the adrenals, these organs and the kidneys
working in harmony
:
the adrenals by supplying, as
we have
seen, the oxidizing substance of the blood,
which takes part,
among
or
other
functions,
the
disintegration
proteolysis
of
waste-products in order to convert them into eliminable end-
products;
the kidneys, by insuring the excretion of these end-
products from the system. Tliis accounts for various observations that present knowl-
edge
to
fails
concomitant
explain.
lesions,
Thus Aubertin and Ambert®“ found
both on naked eye and microscopical exami-
and kidneys in all cases of nephritis studied by them characterized by high-pulse tension. The latter phenomenon suggests that while an excess of adrenal secretion was being produced ^this product and adrenalin causing, ^the as is well known, a marked rise of the vascular tension kidneys had also been overworked in these cases, i.e., excessive In other words, excretor}'^ activity had brought on the nephritis. nation, in the adrenals
—
marked increased functional
—
activity of the kidneys, as repre-
sented by renal vasodilation,
—
should coincide
renals are simultaneously stimulated
—with
since
the
ad-
increased vascular
This has been actually observed experimentally by He found that urea
tension.
Cavazzani,®^ though unexplained by him.
—and
caused simultaneously expansion of the kidney
—
therefore
an increased production of urine and general vasoconstriction. Puncture of the floor of the fourth ventricle (Bernard’s piqure) produces glycosuria through the intermediary of the adrenals, as will be shown elsewhere; a similar puncture also produces, as stated
by Stewart, “a copious flow of urine.”
We
need not
And ani]fle proof of the fact that polyuria is a prominent symptom of diabetes, i.e., that the adrenals and the kidneys work in harmony. The importance of this relationship asserts itself when the obscurity surrounding Thus referring to polyuria, Ilensell, the question is recalled. go beyond
common
experience to
Aubertin and Ambert; Tribune m^dicale, o^Cavazzaul: Arch. Ital. de biol., vol. xvlii, 00
p. 119, 1904. p. 168.
——
293
the adrenal system and the kidneys. Well, and
Jelliffe'’-
common
state that “it is
two diseases— nephritis—but in to
diabies mellitus and chronic interstitial this symptom does not exist.” either case a clear explanation of following additional evidence to this effect the
Pending
conclusions as to the functions
warranted 1.
of
the kidney appear to
us
:
When
the flow
he increased, the renal
of urine is to
sympaare dilated hy vasodilator terminals of the splanchnic nerves thetic which reach the organ hy way of the thus and the semilunar ganglia. The glomerular tufts being
arterioles
urine traversed hy a greater volume of hlood the components of are thus filtered out into Bowmans capsule. 2.
When
the flow of urine
is to
he decreased the
same
arteri-
normal caliber hy the vasoconstrictor which reach the hidneys also hy sympathetic filaments of the way of the splanchnic nerves. reduced
oles are
J^.
to their
The adrenals and
the Tcidneys are functionally united,
the adrenals contributing hy their secretion to the conversion Icidneys excrete of waste-products into end-products which the
with the urine.
of
With the functions of the kidneys as complemental to those the adrenals, what we have termed the “adrenal system”
acquires greater importance in the vital functions of the organsupplies the body the substances which susand metabolism, but provides also for the elimination of end-products of catabolism and other wastes. By “substances” here, are meant both the adrenal and thyroid secretions. The former of these, by becoming oxygenized in the
ism as a whole
;
it
tain oxygenation
lungs, constitutes the oxidizing substance of the blood,
albuminous portion of
its
hsemoglobin
;
i.e.,
the
the thyroid secretion as
previously stated, and as will be shown, enhances the vulnerability of all tissues to oxidation,
including the adrenal center
in the pituitary body.
As they
to the functional relationship
may
evidence
The
between
all these
organs,
be briefly summarized as follows, pending additional
:
pituitary body contains a center which governs the
“Hensel, Well and
Jellifte:
“The Urine and Faeces,”
1905.
—A THE ADRENAL SYSTEM AND FUNCTIONAL
294
ACTIVITY.
functional activity of the adrenals and of the kidneys. Any excitation of this center by the thyroid secretion in the blood,
may
or certain toxics that
occur in the latter, increases the functional activity of both the adrenals and the kidneys, and therefore, general oxygenation and renal excretion.
Geneilvl Conclusions as to the Mechanism of Functional Activity. number of general questions have been referred to in this chapter the discussion of which has to be
—
continued in the next, but the following deductions regarding the several organs the physiology of which has been analyzed
appear warranted 1.
The
:
arterioles of the skeletal muscles
mal, salivary, sweat, and
mammary
of two kinds of nerves: plied by a cranial nerve;
a,
and
of the lacry-
glands receive the terminals
motor or secreto-motor
b, constrictor fibers
fibers sup-
supplied by the
sympathetic system. 2.
The terminals
of the cranial nerves cause the arterioles
of these organs to dilate
and
to
admit an excess of blood,
i.e.,
of
oxidizing substance (adrenoxidase) , into them, thus enhancing their functional activity. S.
When
this exacerbation of functional activity is to cease,
the sympathetic fibers cause the arterioles to contract until they
resume their normal
caliber.
of the kidney are carried on in the same roay, but this organ differs from those enumerated above in that both its vasodilator and vasoconstrictor nerves are supplied by Jf.
The functions
the sympathetic system.
Another important feature to be emphasized in this connection is the manner in which the epithelium of these various organs are enabled to carry on their functions by the blood. According to the prevailing view, the red corpuscles, as the
deemed necessary participants in functhe evidence we have submitted and which
carriers of oxygen, are tion.
In the light of
will be greatly amplified in the
second volume, the red cor-
oxipuscles are not distributors of oxygen, but the carriers of is It blood-plasma. dizing substance which they supply to the
plasma which, after traversing the walls of the capillaries tissues leaving behind it the red corpuscles penetrates to the oxidizing and activates their epithelial elements by means of its
this
—
CONCLUSIONS AS TO NATURE OP FUNCTIONAL ACTIVITY. substance.
On
295
the whole, the evidence referred to warrants the
conclusion that 5.
In
all
the above-mentioned
stance (adrenoxidase)
—a
organs the oxidizing sub-
combination of adrenal secretion and
oxygen formed in the lungs and of which the red corpuscles and the blood-plasma are the vehicles is the physico-chemical agency
—
through which cellular metabolism functional activity.
activity,
is
sustained during passive
and increased during active functional,
—
CI-IAPTEE VII.
THE ADRENAL SYSTEM IN THE FUNCTIONS OF THE DIGESTIVE ORGANS. THE ADRENOXIDASE AND THE DUAL NERVOUS SUPPLY OF THE ORGANS OF DIGESTION.
The shown
to subserve the needs of several sets of
to
find, it
now been organs; we will now
oxidizing substance, or adrenoxidase, has
assume similar functions in the stomach,
liver, heart,
lungs, etc., notwithstanding the dissimilarity of the functions of these organs. tions
I
Here, again, the uncomplicated nervous func-
have described
—
all
apparently carried on, as far as
efferent impulses are concerned, t.e.,
through the agency of a motor,
—
vasodilator and a sympathetic vasoconstrictor
suffice,
the
gastric vasodilator being, however, the pneumogastric or vagus.
The In
an
Stoh-vcii
able
review
and
its
Physico-Chemical Functions.
of
the
relationship
between the nervous
system and the production of gastric secretion HowelP introduces the following remarks:
“It has been very difficult to
obtain direct evidence of the existence of extrinsic secretory
In the hands of most experimenters stimulation of the vagi and of the sympatheties has given negative results, and, on the other hand, section of these nerves to the gastric glands.
nerves does not seem to prevent entirely the formation of the gastric secretion.
There are on record, however, a number
observations
point to
that
a
direct
influence
of
of
the control
Thus, Bidder and Schmidt found that in a hungry dog with a gastric fistula the mere sight of food caused a flow of gastric juice, and Richet reports nervous system on the secretion.
man in wliom tlie oesophagus was completely ocand in whom a gastric fistula was established liy sur-
the case of a
cluded
gical operation
*
Howell:
:
It ivas then
"American Text-book
( 296 )
found that savory foods chewed
of Physiology,” second edition, 1900.
:
297
ADRENOXIDASE AND THE STOMACH.
mouth produced a marked flow of gastric juice. There would seem to be no clear way of explaining the secretions in these cases except upon the supposition that they were caused by a reflex stimulation of the gastric mucous membrane through in the
the central nervous system.”
Nervous Supply and the Formation of Gastric When the nervous su23i3ly of the stomach is closely
The Juice.
—
Gastric
examined, a rather unusual state of affairs presents itself it contains no bona fide motor nerves, unless we grant the sympathetic fibers distributed to to
recognize
But,
if
we do
these,
it
motor
accept the vagus
this, to
as
:
i.e.,
many
qualities, or, refusing
the secretory nerve.
which nerve must we ascribe the afferent
imprdses, which the ingestion of various substances that cause
nausea and other manifestations udiich clinicians so often witness induces? as
The sympathetic has everywhere shoum
itself
an efferent nerve, and I
have already furnished consider-
my
view that sympathetic nerves serve
able evidence in favor of
to constrict the arterioles after these vessels have been dilated by vasodilator nerves. We can thus account for the phenomena witnessed and relegate also to the vagus the role of afferent
nerve;
thus construed,
its
impulses to the vagal center evokes
therefrom secretory impulses to the gastric mucosa. Howell,
continuing
the
remarks
quoted
above,
says
“These cases are strongly supported by some recent experimental work on dogs by Pawlow and Schumowa-Simanowskaja. These observers used dogs in which a gastric fistula had been established, and in which, moreover, the oesophagus had been divided in the neck and the upper and low'er cut surfaces brought to the skin and sutured so as to make two fistulous openings.
In these animals, therefore, food taken into the
mouth and subsequently swallowed escaped through the upper stomach.
oesophageal
Nevertheless, this
fistula
to
without
the
exterior
entering the
meal,’ as
the authors brought about a secretion of gastric juice. If in such animals the two vagi were cut, the ‘fictitious meal’ no longer caused a secretion of the gastric juice, and this fact may designate
‘fictitious
it,
be considered as showing that the secretion obtained when the vagi were intact was due to a reflex stimulation of the stomach
THE ADUENAL SYSTEM AND THE DIGESTIVE ORGANS.
298
In
througli these nerves.
later
experiments- from the same
laboratory the secretion caused in this is
way by
the act of eating
designated as a ‘psychical secretion/ on the assmnption, for
which considerable evidence
is
must insensations accompanying
given, that the reflex
volve psychical factors, such as
tlie
the provocation and gratiflcation of the appetite.
In favorable was continued for as long as five to
cases tlie fictitious feeding six hours,
with the production of a secretion of about 700 cubic of pure gastric Juice. Finally, these observers
centimeters
were able to show that direct stimulation of the vayi^ under proper conditions causes, after a long latent period (four and
marked
a half to ten minutes), a
The long
latent period
secretion of gastric Juice.
attributed to the simultaneous stim-
is
Howell closes his review of this “Taking these results together we
ulation of inhibitory fibers.”
subject by the
must
remark:
believe that the vagi send secretory fibers to the gastric
glands,
and that these
fibers
may
be stimulated reflexly through
the sensory nerves of the mouth, and probably also by psychical states.”
Indeed,
Pawlow
in collaboration with
Madame Schumow-
Simanowski’‘ demonstrated conclusively that the vagus was the secretory nerve of the stomach.
They obtained no
secretion by
exciting the splanchnics, while stimulation of the peripheral
ends of the cut vagi gave positive results, even twent 3'-four hours Schneyer® confirmed these after the nerves had been divided. observations.
a
secretion
Juice.
do
so.
Stimulation of the vagus in the neck produced chemically and physiologically similar to
Stimulation of any
The experiments
gastric
portion of the splanchnic failed to
of Eutherford® pointedly suggest the
Having cut both vagi during digestion he noted that the mucous membrane became paler;
stricto-dilator action of the vagus.
on stimulating the cut fibers connected with the organ the membrane became hyperaemic.
*
Pawlow and Schumowa-Simanowskaja:
“Die Arbeit der Verdauungsdril-
sen,” Wiesbaden, 1898. » All Italics are our own. *
Pawlow and Schumow-SImanowskl: “The W'ork of the Digestive Glands, St. Petersh., 1897; transl. by W. H. Thompson. 1902.
hy Pawlow, 6 «
Schneyer: Zelt. f. kiln. Med., Bd. xxxll. Nos. 1 and 2. S. 131, 1897. Rutherford: Trans, of Royal Soc. of Edinburgh, vol. xxvl, 1870.
ADRENOXinASE AND THE STOMACH.
The
of
identity
the
299
vagus as the gastric seereto-niotor
nerve being established, another feature of especial interest is its power to provoke the muscular contractions it governs. Moraf^ observed that the movements of the stomach could be arrested reflexly by stimulating the central end of the vagus.
WerKronecker and Meltzer® noted a similar phenomenon. end central theimer® reached the same results by stimulating the of the sciatic.
Openchowski,'^® however, obtained direct relaxa-
by stimulating a nerve formed by filaments derived from both vagi, and overlying this part of the organ. Langley^^ among other investigators, repeated Opention of the cardiac orifice
chowski’s experiments and confinned his results.
After “con-
necting the (Esophagus with a vertical tube containing fluid at
and stimulating the peripheral end of the vagus after curari and atropine had been given” he writes “the sphincter opens and fluid passes a pressure of 15 to 20 centimeters water pressure
He
into the stomach.”
also
ascertained experimentally that
the body of the stomach and the pylorus receive inhibitory as well as motor fibers
from the vagus.”
relax the gastric orifices
when
fibers
can
ingesta are to pass through them,
and, in the case of the pylorus, only
we
As the vagal
when they
are
fit
to pass,
are dealing, in vagal inhibition, with a physiological func-
tion,
whereas sympathetic “inhibition,” as
only be
we have
seen,
can
artificial.
Thus, besides
its
role as secretory nerve, the vagus also
governs the stomach’s motor functions, contractions during digestion.
i.e.,
its
This dual role
is
movements and well illustrated
by the observations of Eeynard and Loye^^ in a decapitated criminal. They stimulated the vagus forty-five minutes after the execution and not only obtained the characteristic movements of the stomach, but numerous drops of gastric juice appeared on the gastric mucous membrane.
On the other hand, P. May^® showed experimentally that “the splanchnic nerves
W. ’’
Moral:
Lyon medical,
T. xl, p. 289, 1882.
Kronecker and Meltzer: Archly f. Anat. "Wertheimer: Archives de physiol, norm, Openchowski: Loc. cit. «
“Langley:
Suppl. 1883.
et pathol., p. 379, 1892.
Jour, of Physiol., vol. xxlli, p. 407, 1898. la Soc. de biologle, p. 433, 1887. P. May: Jour, of Physiol., June 30, 1904.
“Reynard and Loye: Comptes-Rendus de
“W.
u. Physiol., S. 328,
—
THE ADRENAL SYSTEM AND THE DIGESTIVE ORGANS.
300
no direct influence whatever, either motor or inhibitory on the muscular wall of the stomach” thus showing that the sympathetic was not the stomach’s motor nerve. liave
The sympathetic system it is
is
represented in the stom.aeh as
While Langley*'* includes both the glands and
elsewhere.
the muscular coat of this organ
with a double nerve supply,
t.e.,
among
the structures supplied
cranial
and sympatbetic, Ruth-
found that “normal secretion occurred after division of the splanchnics.” This points to the correctness of my view that in the stomach as elsewhere, the sympathetic terminals act as vasoconstrictors, since their division must under these circumstances produce exactly the effect noted, the resulting relaxaerford*®
tion
of
the
gastric
bringing
arterioles
about
the
condition
through which the secretory nerve, the vagus, incites nonnal secretion,
The
i.e.,
vasodilation.
arterial
distribution also
sustains
this view.
As
to
Auerbach’s plexus, we know that after piercing the external serous coat of the stomach
its
nerves pass between tbe circular
and longitudinal muscular layers, where they form a close network strewn with ganglia, the whole constituting the plexus.
The terminal
flbers of this plexus are distributed
as is usual
in the muscular coat of the stomach
they form an wiiramuscular plexus which entwines, as it were, the muscular fibers. Furthermore, this plexus gives off filaments which, entering deeper into the wall of the stomach, form another in muscles
:
plexus, also containing
many
ganglia:
i.e.,
Meissner’s plexus.
—
This net-work of sympathetic elements fibers, ganglia, cells, i.e., immediately under the lies in the submucous coat, etc. muscularis mucosae, which separates the latter from the secre-
—
tory glands.
Besides the
thin submucous muscular
many
filaments
layer, it
it
distributes to the
gives off a large
number
that
These, on reaching the glands, form a close net-work in the connective-tissue sheath surrounding them, which net-work gives off delicafe fibrils that enter into the penetrate this layer.
glandular elements themselves. They likewise supply terminal tlieir vasfibers to the neighboring muscular elements and to cular supply.
»
Langley: Schafer’s "T. B. of Physiol.,” '“Rutherford: Loc. clt.
yol.
II,
pp. 692
and
693, 1900.
ADRENOXIDASB AND THE STOMACH.
The
blood-vessels of the
301
stomach are distributed in a very as follows:
“The
larger arteries, after penetrating the outer coats, divide
within
similar manner.
PiersoP”
them
describes
the submucosa into smaller branches, one set of which pierces
mucous mem-
the muscularis mucosai, to be distributed to the brane, while the other enters the muscular
The
and serous
supplying the mucosa form a rich
vessels
tunics.
stib epithelial
capillary net-work as well as mesh-iuorks surrounding the gastric
glands, the capillaries lying immediately beneath the basement
membrane
in close proximity to the glandular epithelium.
branches
The
to the outer layers form long-meshed from which the muscle-bundle and fibrous
distributed
capillary net-works
tissue derive their supply.’’
A
feature that requires emphasis
manner in which the vessels are finally mucous membrane The small arteries or
in this connection is the
distributed to the
:
do not themselves ascend between the glands, but
arterioles
These, by anastomosing
give off fine capillaries that do so.
with one another, form a very rich plexus which surrounds each glandular tubule in a net-work of close hexagonal meshes.
The
secreting elements
cellular
of the glands
being covered
by a delicate basement membrane, the capillaries are thus related to the former precisely as we found them to be in the sweatglands.
Indeed,
the intrinsic structures of the stomach are compared with those of the organs reviewed, it soon becomes evident that the mechanism to which the production of secretions is due does not differ from them.
We
if
cannot, however, say the same in respect to the exand nerves, and to this feature of the process
trinsic vessels
we wish
to
call
especial
vascular supply of
the
attention.
stomach
is
As is well made up of
lenown,
the
the
gastric,
and right gastro-epiploic branches of the hepatic artery and the left gastro-epiploic and vasa brevia from the splenic. 1 he important feature referred to is this The gastric, hepatic, and splenic arteries arise from the cceliac axis, and, as shown pyloric,
:
in the earlier chapters, the cceliac axis is the first great arterial tiunk to receive the blood from the lungs: i.e., before the activity of the oxidizing substance in the downward
blood-stream has
“Plersol;
“Normal Histology,”
p.
166, 1900.
THE ADRENAL SYSTEM AND THE DIGESTIVE ORGANS.
302 in any
way been reduced.
that the cceliac axis
Another very suggestive feature is surrounded by the cceliac plexus, a portion
is
of the solar plexus of the sympathetic, and that extensions of the cceliac plexus
and
—the
gastric,
hepatic,
gastro-epiploic plexuses
name
—
^follow
the walls of the stomach.
to
pyloric,
gastro-duodenal,
the arteries of the same
We
thus have as the co-
ordinators of gastric function, the two nerves which
elsewhere to
fulfill
similar roles,
viz.,
we found
the vagus, to carry on
the secretory and motor functions of the stomach, and sympathetic jilexuscs and nerve so distributed as to constrict the blood-vessels supplied to the organ
blood circulating in the digestive process
and
to reduce the
volume of
its
glands and muscular walls, when, after
is
ended, the stomach must be restored to
the passive state.
Another feature requiring our attention is the formation In the blood-plasma we have sodium and potassium chlorides; in the secretion of the stomach these represent the most important and abundant salts, and constiof the gastric secretion.
tute the source of the hydrochloric acid in the gastric juice,
according to prevailing views.
Has
the oxidizing substance of
the plasma any influence upon the formation of this acid?
marked want.
affinity of chlorine for
It takes it
up whether
combination extra corpore; gastric
it
hydrogen seems able
to
fill
The the
the gas be free or in vulnerable doubtless does the
same in the
But here conditions are especially well such a reaction, if we analyze the question with
structures.
adapted for
Equal volumes of chlorine and hydrogen can only be kept in an absolutely dark place; diffuse the aid of thermochemistry.
light causes
them
light, for instance
to slowly unite, while a bright light
—brings
—sun-
on such an instantaneous combina-
tion of the two elementary bodies that the flask containing
them
flies
into pieces.
The
fact that this
on with a n.agnesium light which, is
as is
rich in chemical rays, indicates that
may
also be
brought
the ease with sunlight,
we
are dealing with a
Precisely as process in which heat plays a predominant part. the sun sends radiations which the earth transfonns into heat, so does it, in the experiment mentioned, send radiations which the combined chlorine and hydrogen transform into heat; the mixture absorbs the undulations of the ether and transforms ^
303
adrenoxidase and the stomach.
moUcular energy, i.e., heat. But a multitude of increased molecular familiar every-day phenomena prove that
them
into
be procured without light-rays, etc.; the cause it to mere rubbing of a match against a dry surface will That this occurs without in the least inlight, for instance. energy, or heat,
may
against volving the need of a chemical body on the substance which the match is rubbed to start the reaction indicates that friction causes increased vibratory activity in the ingredients of the match-tip, and, these only
combining when a given tem-
perature is reached, heat must obviously be accepted as the Now, a very significant featcausative factor of the process.
ure in connection with the formation of the gastric hydrochloric acid is the fact that the combination temperature, when an im-
mediate reaction is obtained between chlorine and hydrogen, is SO. 5° C. (103.1° F.), while that of the gastric cavity is about S8° C. (100.1/° F.). The fact that the walls of the stomach,
must show a higher temperature
the seat of the blood-fiow,
than this (at least 2 degrees, that of the liver being 106 degrees) pointedly suggests that the formation of hydrochloric acid only occurs
when the stomach
is
brought up to the
re-
quired temperature.
Under
these conditions, the formation of hydrochloric acid
The volume of blood circulating in the would be as follows gastric mucosa being increased by vasodilation of its arterioles under the auspices of the vagus, the oxidizing plasma, by enhancing metabolism, raises the temperature of the stomach at :
least the 1.5° C. required to
render the formation of hydrochloric
acid possible.
The
acid would be
formed when needed:
in accord with experimental data.
The
a feature quite
parietal cells of the
glands, which are the seats of
its formation, are only active during digestion, and then increase in size; they continue in
this condition as long as the
stomach contains food, and then
return to their normal
The following
size.
also tend to indicate that
my
lines of Howell’s
conception of the process
may
be the right one:
“The chemistry of the production of free remains undetermined. No free acid occurs in the blood or the lymph, and it follows, therefore, that it is manu-
HCl
also
factured in the secreting
cells.
It is quite evident, too, that
—
THE ADRENAL SYSTEM AND THE DIGESTIVE ORGANS.
304
the source of the acid is the neutral chlorides of the blood; these are in
hydrogen
to
some way decomposed, the chlorine uniting with form HCl, which is turned out upon the free
surface of the stomach, while the base remains behind
and
probably passes back into the blood.” Closely related with the formation of hj'drochloric acid that of pepsin.
Landois,'’ for example, writes:
is
“The glands
themselves contain no pepsin, but only a zymogen, namely, the jiepsinogenic substance or propepsin, which occurs in the gran-
The zymogen,
ules of the chief cells.
ence upon proteids. chloric acid or
If,
however,
sodium chloride,
The hydrochloric
acid
is
of itself, exerts no influ-
it
it is
be treated with hydro-
transformed into pepsin.”
formed by the parietal or
in the cardiac portion of the stomach, while pepsin
o.xyntic cells is
produced
in the peptic cells which occur both in the cardiac and pyloric regions.
The mutual
influence
of
these
products brings in
other factors, however, which are reviewed at length in the
second volume.
For the present,
mode
it
may
be said that
my
views as to the
of action of the vagus and sjunpathetic nerves upon the
cardiac arterioles elucidates several obscure points.
Thus, the
fact that the secretion of the gastric juice continues after diviis explained by the passive dilation and the admission of an excess of arterial blood
sion of the gastric nerves
of the arterioles
to the secreting elements.
This leaves to the vagus alone the
function of secretory nerve ings) since
it is
a vasodilator.
(in
accord with Pawlow’s teach-
The
sympatlietic has no function
other than to restore the arterioles to their normal caliber after On the whole, the functions of the digestive process ceases. the stomach, in the light of
lows
my
views, are carried on as fol-
:
During the phase of gastric inactivity, the arterioles distributed to the mucosa and muscles of the stomach are constricted sufficiently under impulses received through their sympathetic nerves, to admit only sufficient blood into the secretory and muscular elements to insure their nutrition and the forma1.
tion of the substances necessary for the digestive process,
”
Landols:
“Text-book of Physiol.,” tenth American
viz.,
edition, p. 293, 1905.
305
ADRENOXIDASB AND THE INTESTINES. pepsinogen in the pepiic
cells,
hydrochloric acid in the parietal
and myosinogen in the muscular
cells
-fibers.
begin the arterioles are dilated by terminals of the vagus, and an excess of arterial blood being thus caused to circulate in the peptic, parietal, and muscular 2.
^yhen digestion
gastric juice is
cells,
is to
formed and
secreted,
and muscular move-
ments of the gastric walls are incited. 3.
When
the digestive process
is to
cease the arterioles are
restored to their normal caliber by vasoconstrictor fibers of the
sympathetic nerve, and the stomach resumes the passive state described in the 1.
r
The
first
conclusion.
oxidizing substance (adrenoxidase) which circulates
the blood-plasma in the cellular elements, secretory
until
vruscular, sustains the functional activity
elements, both during the resting stage
4.
r
^ ^ *
B jp 5-
& I I >
Intestines.
We
find the
of all these cellular
and during
—The innervation of the
with that of the stomach.
and
digestion.
intestines corresponds
same secreto-motor nerve
the vagus, and, as constrictor of the arterioles, the sympathetic.
HowelP® refers to the extrinsic nerves of the intestines as fol“As in the case of the stomach, the small intestine and
lows:
the greater part of the large receive viscero-motor nerve-fibers
from the vagi and the sympathetic chain. The former, according to most observers, when artificially stimulated cause movements of the intestines, and are, therefore, regarded as the motor fibers.”
Among
the earlier writers to observe that this applied both stomach and intestines were Hemak,^® Weber, Pfiiiger, Budge and v. Braam Houckgeest, Ludwig and Kupffer,^® and Engelmann.^^ This was confinned by the more recent experi-
to the jr a;
A k
€
ments of Bechterew and Mislawskip^ Jacobi,^® Morat,^^ and Pohl.®® Pincus and Pannm both found that the intestinal movements persisted after section of both vagi, however, a feature wliich indicates that
'
an inherent contractile power
exists in the
’“Howell:
"Amer. T. B. of Physiol.,” p. 384. ’“Remak: MUller’s Archlv, 1858. Ludwig and Kupffer: Zeit. f. ration. Med., Bd. 11, S. 357, 1858. Englemann: Archly f. d. gea. Physiol., Bd. Iv, 1871. “Bechterew and Mlslawskl: Archlv f. Physiol., Suppl. Band, S. 243, “Jacobi:
Archlv f. exp. Pathol., Bd. xxlx, S. 171, 1891. “Morat: Archives de physiol, norm, et pathol., T. v, p. “ Pohl: Archlv f. exper. Pathol., Bd. xxxiv, S. 87, 1894.
142, 1893.
1889.
THE ADRENAL SYSTEM AND THE DIGESTIVE ORGANS.
306
intestines as well as in the stomach.
Bunch,-® Courtade and Guyon,-^ contend that contraction of the circular coat was never obtained by them by stimulating either nerve. But Cash®*
noted that waves of constriction jiassed down the intestine when substances were placed in it after the splanchnic nerves had
been cut
—evidence
that the remaining nerve contained both
sensory and motor fibers.
ment
Starling emphasizes this by the state-
that “true peristaltic contraction
is
a coordinated reflex,
carried out by the local nervous centers in the walls of the gut.
He
also points to various disturbing factors
calculated to obviate them.
and
means
to the
“If these precautions are observed,”
he writes, “stimulation of the vagus in the neck, after paralysis
by means of atropin, will always movements.” Hallion and Frangois-Franck^® observing the same precautions, noted that stimulation of the peripheral end of the cut vagus caused of the cardio-inhibitory fibers
produce an
marked
effect
upon the
intestinal
vasodilation in the intestine.
dilator properties
An
This proves the
stricto-
of this nerve.
inhibitory action of the vagus
is
also generally recog-
Pfliiger, according to Bunch, “saw sometimes an insometimes a diminution of the intestinal movements on vagus stimulation.” Bechterew and ]\Iislawski concluded that while the vagus contained both motor and inhibitor nerves, the
nized.
crease,
former predominated.
Starling gives tracings in support of
and also states that “the vagus contains two sets of fibers to the muscular coat of the intestine,” one set inhibiting, Bunch also states that “the the other augmentor or motor. fibers for the musinhibitory vagi contain both augmentor and
.this view,
cular coat of the intestine.”
tion
The sympathetic fulfills in this connection the same “The that we found it to fulfill in other organs.
funcfibers
from the sjunpathetic chain, on the other hand,” as stated by Howell,*® “give mainly an inhibitory effect when stimulated.” We have seen that this is due to an exaggerated contraction of “Bunch:
^ “
Jour, of Physiol., vol. xxll, p.
25, 1898.
Courtade and Guyon: Archives de physiol, norm, et pathol., 1897. Cash; Proceedings Roy. Soc. of London, vol. xl, p. 469, 1886;
“ Halllon
and Prancols-Franck:
xll,
Archives de physiol, norm, et path., T.
vlll, p. 502, 1896.
"“Howell:
vol.
„
p. 213, 1886.
T. B. of Physiol., second edition, p. 669, 1907.
307
ADRENOXIDASE AND THE INTESTINES. the
arterioles
by the sympathetic terminals
—proof
that
the
Briefly as elsewhere, function is
latter act as vasoconstrictors.
and arrested by vasoconstriction. The kinship with the stomach applies also to the hitestinal lines of secretory organs. This is emphasized by the following follow the Piersol’s: “The blood-vessels supplying the intestines veslarger The general arrangement of those of the stomach. slendei sels pierce the serous and muscular coats, giving off the reaching upon tunics; the twigs to supply the tissues of incited by vasodilation,
submucosa the
vessels
Numer-
form a wide-meshed net-work.
ous branches then pass through the museularis mucosie, to be distributed to the deeper as well as to the more superficial parts of the mucosa;
narrow
form net-works which
capillaries
surround the tubular glands, while beneath the epithelium wider From this capillaries encircle the mouths of the follicles. superficial capillary
tween the
follicles,
net-work the veins arise and, passing bejoin the deeper venous plexus, which, in
turn, empties into the larger vein of the submucosa.
parts of the intestine where
villi exist
In those
special additional arteries
villi, when they expand into which run beneath the epithelium and around the central lacteal as far as the ends of the villi. These capillaries terminate in venous stems, which descend almost perpendicularly into the mucosa, in their course receiving the Brunsuperficial capillari'es encircling the glandular ducts. ner’s glands and the solitary and agminated follicles are supplied from the submucosa by vessels which terminate in capillary net-works distributed to the acini of the glands and to the
pass directly to the bases of the capillary
net-works,
interior of the lymph-follicles.”
.
.
.
“The nerves
distrib-
uted to the intestines are arranged almost identically to those of the stomach fibers,
tery
;
they are composed largely of non-medullated
derived from the trunks which pass within the mesen-
from the larger abdominal sympathetic plexuses.
After
giving off branches to the serous coat, the nerves pierce the
form the rich intramuscular composed of a rich net-work of delicate, pale libers, at the nodal points of which microscopical ganglia exist; after supplying the longitudinal and outer part of the circular muscular coats the fibers obliquely pierce the
longitudinal muscular tunic
plexus of Auerbach.
This
is
to
THE ADRENAL SYSTEM AND THE DIGESTIVE ORGANS.
308
submucous tissue, vlicre they form the plexus of Meissner, which closely resembles Auerbach’s nervous net-work witliin the muscularis, jiossessing, however, smaller latter tunic to gain the
ganglia and somewhat closed meshes.
From
the plexus of the
submucous tunic
fibers pass into the mucosa, to form net-works about the glands and to send fibrillie into the villi.” In analyzing the functions of the intestinal tract it is im-
portant to note that two distinct sets of active structures are (1) the secreting glands of Lieberkiihn and of Brun-
present:
ner; (2) the villi of the agminated lymph-follicles patches) and the solitary lymph-follicles. Secreting Glands
found in
.
—The
(Peyer’s
glands, or crypts, of Lieberkiihn,
throughout the entire length of the
close array
intes-
including the colon, are present only in the upper, or
tine,
mucous,
They
layer.
are simple in construction
sweat-glands, minus the coils and muscles:
i.e.,
and
recall the
a net-work of
and probably nerve-fibrils overlying a delicate basement-membrane which in turn surrounds a single la}'er of columnar epithelial cells. These cells radiate toward a common center and thus form a minute tube which opens upon the mucous membrane between the villi. Their functional mechanism is doubtless that of all simple tubular glands. Howell refers to the crypts of Lieberkiihn as follows: “These structures resemble the gastric glands in general apcapillaries
pearance, but not in the character of the epithelium.
The
the goblet is of two varieties: form mucus, and columnar cells with Whether or not the border.
epithelium lining the crypts cells,
whose function
is
to
a characteristic striated crypts
form a
iologists are
definite secretion
.
.
.
has been
accustomed to speak of an
much
debated.
Phys-
intestinal juice, 'succns
formed by the glands of Lieberkiihn ; but practically nothing is knovoi as to the mechanism of the secreWe have seen that nerve-filaments are distributed to tion.” the secreting cells of the intestines, as stated by Piersol. The entericus,’ as being
functional needs of those stnictures seem, therefore, to be satisfied.
mucus seems evident if their histologcan be taken as guide. As we pointed out in this
That they
ical attributes
secrete
1903, however, the intestinal secretion serves also to protect the body against infection through foods^
work
in
ADRENOXIDASE AND THE INTESTINES.
309
—The
gastric juice
Intestinal Immunizing Functions.
not only concerned with digestion, bnt it is likewise a powerlul Howell refers to this property in the following antiseptic. is
“One
words;
It
in which it witlistands putrefaction.
way
tlie
of the interestmg facts about this secretion is
for a long time, for
with very
little
may
be kept
months even, without becoming putrid and
change,
if
any, in
its
digestive action or in its
This fact shows that the juice possesses antiseptic properties, and it is usually supposed that the presence This might serve of the free acid accounts for this quality.” acidity.
total
beyond the pylorus further protection of this unnecessary; but greater is the care with which Nature
as evidence that sort is
Every structural
protects her organic creations.
in any
cell
way
exposed seems to be surrounded not only with prophylactic weapons, but also with second and even third lines of defense to
cope with what the
line
first
may
have failed to disarm.
Eemoval of the stomach in animals has been followed with return to normal health;
it
seems plausible that the intestinal
tract should also be supplied its
with means for the protection of
organs.
The material formed first
in the living crypt of Lieberktilin
presents the form of granules, then becomes transformed
into a transparent substance
which accumulates in the spaces
This either constitutes the mucin found
of the cell-substance.
in the secretion or represents
The secretion proper That it may possess
is
clear,
to
labors of St. Clair
prove bactericidal.
“mucus”
nasal cilli
viscid, yellowish,
killed
—
and
staphylococci
nasal “mucus,”-
i.e.,
Thomson and
alkaline.
by the thanks to
—
Hewlett,®^ has been found
Page^^ experimentally ascertained that
anthrax
bacilli,
were almost actively destroyed
lence of
this material.
antiseptic properties is suggested
fact that a very similar fluid, tlie
an antecedent of
that
Klebs-Loffler
ba-
it, and that the viruand streptococci was reduced. Nasal largely made up of serum a feature
liy
“mucus,” however, is which also applies .to the secretion of the glands of Lieberkuhn. Brunner’s glands, which occur in the duodenum, at the :
St.
Clair
Thomson and Hewlett:
Medico-Chlrurgical Transactions, vol.
Ixxviii.
Paget:
Journal of Laryngology, Nov.,
1896.
—
THE ADRENAL SYSTEM AND THE DIGESTIVE ORGANS
310
portal of the intestinal canal, would seem to suggest, by tlieir situation and their general conformation, just such a function.
While they resemble in general structure the pylorie glands, which most authors compare them, they also present many
to
characteristics of the
mammary
man-
lobules, especially in the
ner in which their interlobular ducts are disposed. The gland jiroper is situated beneath the smaller erypts just deseribed,
submucous
the
in
he.,
surface between the
tissues,
villi
—
or into
that
products.
Indeed, their secretion
plasma relieved of
The juiee,”
analogy
considerable
serous:
also
is
:
an
between their i.e.,
blood-
its fibrin, globulins, etc.
of these two glands
secretion
“suceus
or
is
erypts of Lieberkiihn
tlie
indication
tliere
ducts penetrating to tbe
its
entericus,”
and
is
termed “intestinal regarded by many as is
capable of acting on starch, proteids, fats,
with intestinal digestion:
in connection
etc.,
which could not conmight possess through the presence of oxidizing substance and alexins. Professor Poster, however, referring to this supposed action on foods, says: “Even Moreover, many obat its best its actions are slow and feeble. jiroperties
all
any antiseptic power
trovert
it
servers have obtained negative results
ments are
And
conflicting.”
conclude that at present, at
;
so that the various state-
he adds:
“We may,
we have no
all events,
therefore,
satisfaetorj'
reasons for supposing that the actual digestion of food in the intestine will- see
is,
to
any great extent, aided by such a juice.”
in the second volume, however, that such
is
We
the case.
These two glands are the only ones forming part of, the intestinal tissues per se to which the protective functions reHence, the facts that they both ferred to could be ascribed. produce a secretion so be
called
“serous,”
of serous
source Asiatic
cholera.
—
nearl}^ identical
for
the
diarrhoea, ]\Ioreover,
glands
and
of
to blood-plasma as to
Lieberkiihn
are
the
the rice-water discharges of
the
recognized
fact
that
blood-
plasma is the normal excipient for chemical protective agencies, suggests, as a working proposition, that the. glands of TAeherTciilin
and
having for
the duodenal glands of its object to asepticize,
Brunner supply a secretion and prevent the putrefaction,
digestive of, the intestinal contents, besides tahing part in the
process.
311
ADRBI^OXIDASE AND THE INTESTINES.
of a bactericidal fluid in the intestinal canal,
The presence
at least along its walls,
It is
now
suggested by various facts.
is
generally recognized that the nursing infant
receives through its mother certain substances which increase the bactericidal power of its blood-serum. Thus while Schmid
and Pflanz®* found experimentally that the antitoxic substances in the blood of parturient also
women
exist also in the milk, Figari®®“
noted that calves and young goats are not only capable of
absorbing agglutinins and antitoxins with the milk of
immu-
nized mothers, but that rabbits immunized by the administration
immunized milk taken by the mouth, are capable of transmitting to their young both agglutinins and antitoxins. This suggests that apart from the stomach general immunity may be conferred by fluids absorbed from the intestinal canal. This of
accounts for the fact that nursing babies are able to withstand
more
effectually than bottle babies
tions.
As
mechanism
will be
both local and general infec-
shown elsewhere in
this volume, the adrenal
not developed in the nursling sufficiently to pro-
is
tect the child against infection,
and Nature
insures,
through
the mother’s milk, not only the child’s nutrition, but its protection.
Welch, in his Harvey Lecture, said
:
“It
is
an impor-
tant function of the mother to transfer to the suckling through
her milk immunizing bodies, and the infant’s stomach has the capacity,
which
in active state.
is
afterward
The
lost,
of absorbing these substances
relative richness of the suckling’s blood in
protective antibodies, as contrasted with artiflcially-fed infant,
explains the greater freedom of the former
from infectious
dis-
eases.”
The importance
“Among
of this fact in practice, cannot be over-
who believe in the omnipotence of chemical formulae,” wrote Jacobi, recently, “there prevails the opinion that a baby deprived of mother’s milk may just as readily be brought up on cows’ milk that is easily disproved. ; In Berlin they found that among the cows’ milk-fed babies estimated.
those
under a year, the mortality was breast-fed infants. slightly smaller,
si.x
times as great as
Our own groat
cities gave us similar, or proportions, until the excessive mortality of
Schmid and Pflanz: Wiener klin. Woch., No. Rlforma Medlca, April 8, 1905.
““Figarl:
among
42, 1896..
—
THE ADRENAL SYSTEM AND THE DIGESTIVE ORGANS.
312
the very young was somewhat reduced by the care bestowed on the milk introduced into both our iialaces and tenements. ]\Iilk
was examined for bacteria, cleanliness and chemical reaction. It was sterilized, Pasteurized, modified, cooled, but no cow’s milk was ever under the laws of Nature changed into human milk; and with better milk than the City of New York ever had, its infant mortality was greater this summer (1904) than it has been in many years. That hundreds of thousands of the newly-bom and small infants perish every year on account of the absence of their natural food, is a fact which is knoum and which should not exist.” Winters states that “during the siege
Paris
of
(1870-71), while
the
general
mortality was
doubled, that of infants was lowered 40 per cent, owing to
mothers being driven to suckle their infants!” This shows that the alimentary canal may be the seat of an immunizing process, and suggests that if the intestinal secretion of adult animals
is
bactericidal,
the intestinal im-
munizing process must prevail at all ages. That the intestinal secretion are endowed with immunizing properties is suggested by various facts. Pawlow found that the succus entericus increased strikingly the proteolytic activity of the pancreatic fer-
ments
—sometimes
to
an astonishing degree.
When we
con-
sider that jMetchnikoff’s “cytase,” the substance which enables
phagocytes to digest bacteria
is
mainly
a
pancreatic ferment,
same ferment should likewise digest bacteria in the intestine and thus protect the body This is further suggested by the fact that Wender at large. trypsin,
it
is
self-evident that the
found that milk contained a ferment to which he refers as “galactase or trypsin,” an observation confirmed by several inThe intestinal secretion can thus replace milk vestigators. obviously with greater activity as an immunizing agent, since
—
both fluids contain the same proteolytic and therefore cidal agents. We will see in the second volume that
bacteriall
the
agents concemed in the immunizing process are present in the intestinal
secretion as well
That the
as in milk.
bacteriolytic process occurs
the intestinal mucous
membrane
is
upon the surface of
rendered probable by the
by Howell, “extracts of the walls of the or the juice squeezed from these walls have been small intestine fact that, as stated
'
313
ADRENOXIDASE AND THE INTESTINES.
found to contain four or five different enzymes, and to exert a most important action upon intestinal digestion. Whether these enzymes are actually secreted into the lumen of the intestine,” continues the author, “is not satisfactorily shown, but since they are contained in the intestinal wall, as secretory products
and lonsider them
we must regard them a‘s
the important and
characteristic feature of the intestinal secretion.”
The most
direct evidence, however, is
that furnished by
Charrin and Levaditi, Zaremba, and others, who showed that the pancreatic juice could digest bacteria
and
their toxins.
The
and Morgenroth
investigations of Bordet, ]\Ietchnikoft, Ehrlich
having demonstrated that the distinction of bacteria in phagocytes
was due to the presence in these
pancreatic ferment, trypsin,
it
is
cells of the
difficult to
corresponding
conceive how, in
accord with the prevailing views on the subject, intestinal bacteria, especially those
ingested with foods, can escape digestion,
along with the food-stults. It is
now
the intestinal
believed that intestinal bacteria are necessary in digestive pirocess;
“By taking embryo
states:
but as
IsToel
Paton
(1905)
guinea-pigs at full time from the
uterus and keeping them with aseptic precautions,
it
has been
shown that the absence of micro-organisms from the intestine does not interfere with digestion.”
Por reasons that will be submitted in the second volume, immunizing process is carried on mainly, as far
the intestinal
as liquids are concerned,
by a recently discovered ferment (a compound containing trypsin and the oxidizing substance, as 1
IV ill
show) which has been found to act more vigorously than and termed “erepsin” by Cohnheim. It splits peptones
trypsin,
and many other
jiroteids into their
component
bodies, particu-
laily the is
As
di-amido and non-amido acids leucin and tyrosin. It thought to supplement the proteolysis begun by the trypsin. bacteria are proteids,
thus destroyed as living teids.
l
ienee
m this work
tlie
it
follows that they are digested— and
organisms— as w^ell as the other proimmunizing process urged by myself
intestinal
in 1903.
Ponding additional testimony
I may submit as a working proposition, the conclusion that intestinal digestion of proteids includes that of living proteids, viz., bacteria and that this
THE AUUENAL SYSTEM AND THE DIGESTIVE ORGANS.
314
bacteriolysis represents a function through which general infec-
tion is prevented, Villi
now
an immunizing process.
i.e.,
and Lymph-follicles.
conceived by physiologists,
—The
process of absorption, as
concisely described by Howell
is
in the second edition of his text-book (p. 733) takes place very readily in the small intestine. correctness of this statement
loops of the intestine.
may
:
“Absorption
The
general
be shown by the use of isolated
Salt solutions of varying strengths or
even blood-serum nearly identical in composition with the animals’
own
blood,
may
be absorbed completely from, these loops.
Examination of the contents of the intestine in the duodenum and at the ileocecal valve shows that the products formed in digestion have largely disappeared in traversing this distance.
All the information that
mucous membrane
we
possess indicates, in fact, that the
of the small intestine absorbs readily,
and
one of the problems of this part of physiology to explain Anatomically the means by which this absorption is effected. it is
two paths are open to the products absorbed. They may enter the blood directly by passing into the capillaries of the villi, or they may enter the laeteals of the villi, pass into the lymph
and through the thoracic duct
circulation
of the Ijunphatic sys-
tem eventually reach the blood vascular system. The older physiologists assumed that absorption takes place exclusively through the central laeteals of the were described as absorbents.
villi,
and hence these
We now know
vessels
that the digested
and res^mthesized fats are absorbed by wa^f of the laeteals, but that the other products of digestion are absorbed mainly through the blood-vessels, and therefore enter the portal system and pass through the liver before reaching the general circulation. Aca patient with a fistula at the end of the small intestine [Macfadyen, Nencki, and Sieber],
cording to observations
made upon
food begins to pass into the large intestine in from two to five and a quarter hours after eating, and it requires from nine to twenty-three hours before the last of a meal has passed the ileocecal valve; this estimate includes, of course, the time in the
stomach.
During
this passage absorption of the digested prod-
ucts takes place nearly completely.
In the
fistula case referred
was found that 85 per cent, of the protein had disappeared, and similar facts are known regarding the other foodto above, it
—
315
ADRENOXIDASE AND THE INTESTINES. stuffs.”
“The energy
.
•
.
that controls absorption recides,
presumably in the epiand constitutes a special form of imbibition which
therefore, in the wall of the intestine, thelial cells,
not yet understood.” Various facts tend also to suggest that the intestine is the seat of a protective process, where bacteria and poisons of all is
kinds are most likely to penetrate the blood-stream:
i.e.,
the
organs of the intestinal wall connected with absorption. Viewed from my standpoint the question embodies features
which seem
to
me
to have been overlooked, but
which require
a review of the functions of each organ involved in the process
and lymph-follicles. The villi, the and the agminated lymph-follicles, or
studied, especially the villi solitary Ijunph-follicles,
Peyer’s patches, are considered together, because they appear to represent parts of a single- system.
The
structural similarity between the walls of the stomach
and those of the intestine must be function referred
to,
in connection with
—
set
absorption,
i.e.,
the intestines,
aside here,
—a
since the
predominating one
can hardly be said to be
worth considering as a factor of gastric functions. Conversely, the villi distributed throughout the whole small intestine are adapted for this purpose.
especially
nerves, muscular tissue, basement
-
Besides the capillaries,
membrane, and epithelium,
these structures contain a lymph-trunk, or lacteal, the purpose of
which
is
to take
up nutritional agencies from the
intestinal
contents as they pass along.
Each gland, is
villus
may
be considered as a sort of “reversed”
a sweat-gland
if
outside
i.e.,
is
taken as standard.
The epithelium
exposed in the intestinal canal,
the epithelium lies the basement
membrane.
—
^while
under
Combined, these
two constitute a glove-finger-like projection inside of which are the structures that we found over the basement membrane
The capillaries form a close-meshed network not only in contact with the inside of the basement membrane, but entwined with considerable connective tissue in the sweat-gland.
strewn with leucocytes, the tissue and cells constituting “lymphoid tissues.” T said “connective tissue,” but at this point ve must emphasize the fact that it is not true connective tissue, as met with elsewhere, but a fenestrated membrane made
up
entirely
of
star-like
cells
that
give
oft
thin projections,
or
a
THE AUUENAL SYSTEM AND FUNCTIONAL ACTIVITY.
81 G
make np the tissue itself: The fenestra, or openings, cytogenous membrane is permeated accommo-
pseutlopodia, which by intermixing i.e.,
witli
Kblliker’s
which
cyiogenoiis iissue.
this
date the capillaries.
Another
histological
feature
of
interest
special
presence of smooth muscular fibers wliich stand upright
being horizontally capillaries
and
disposed
—and
are
interwoven
villus’s
delicate
among
We
cell-fibers previously referred to.
immediately under the
is
the
—a few the
thus have
basement membrane a
Intestinal Villus; Venous radicle shown at
a.
(Cadiat.)
though minute, suction-pump which by alternately contracting and relaxing causes the organ to absorb the pre-
perfect,
viously asepticized intestinal fluids. Xext in order inwardly are the venous steins (one or two) veins Avhich carry the blood from the villous capillaries to the caii} A\hicb These vascular channels, in the dee])or tissues.
end the bulk of intestinal foodstuffs to veins which ultimately and cut, annexed in the portal system, are well shown in the will again be referred to.
Last of
all,
in the
middle of the organ,
is
the lacteal,—
317
ADRENOXIDASE AND THE INTESTINES. thick,
club-like,
sometimes
double,
lymphatic
vessel,
which
the tip of stands upright and reaches almost to the inside of the former. the villus, its own blind apex almost touching This vessel. Each lacteal represents the origin of a lymphatic is illustrated
Lymph
in the second figure.
—derived
contains chyle
from the
intestines
—only
At other times the fluid found during intestinal digestion. that in the lacteal and neighboring structures is identical to
Intestinal Villi; Injected Lacteals in the Middle of each Villus. (Cadiat.)
found elsewhere in the organism. emphasize the fact that lymph
and
is
It is perhaps
advisable to
very similar to blood-plasma,
owing to the presence of leucocytes. Indeed, it only differs from blood in the absence of red corpuscles. It undergoes coagulation and separates, as does plasma, into serum and clot, the latter likewise containing fibrin-globulins. It contiiins serum-globulin and serum-albumin in relative proportions similar to those in blood, though in smaller quantity: a feature which accounts for its somewhat richer than this fluid,
THE ADRENAL SYSTEM AND THE DIGESTIVE' ORGANS.
318 lower
ipiantities,
counted
correspond
also
vehicle^ for
Inorganic
gravity.
siiecific
derating,
various
and the
those
to
substances,
it
plasma.
constituents
is,
Being a
are
variable
-conflicting analyses published are thus ac-
Stewart says, in this connection
for.
;
the chlorides prepon-
the
of
its
been defined as blood without j\Iuller)
salts,
red
its
“Lymph
:
has
(Johannes
corpuscles
in fact, a dilute blood-plasma, containing leu-
some of which (lymphocytes) are common
cocytes,
to lymph and blood, others (coarsely granular basophile cells) are absent from the blood. The reason for this similarity appears when
recognized that the plasma of lymph is derived from the plasma of blood by a process of physiological filtration (or osmosis) through the walls of the capillaries into the lymph-
it is
spaces that everywhere occupy the interstices of areolar tissue.
But, in addition to the constituents of the jjlasma, lymifii appears to contain certain toxic suhstances produced in the metabolism of the tissues and destroyed in the lymphatic glands.”
now seems
It
probable that the intestinal tract, being one
of the two regions
most exposed
to toxics, the villi not only
have for their function to absorb chyle, but to protect the orThe lacteal is the recognized absorption organ for
ganism.
emulsified fats.
As
I
view the process involved, the fat-con-
taining fluids, as soon as they reach the basement membrane, are
first
submitted to the asepticizing influence of
They
thelial cells.
epuration,
phoid
and probably chemically transformed
layer
endo-
its
are then submitted to the next process of
—Kolliker’s
cytogenous
layer
in
the
l3’m-
—immediately
be-
neath, in which leucocytes, and, therefore, antitoxic substances, are constantly being formed.
M'hen
it finally
reaches the lacteal,
it again meets endothelial walls, and when through these and in the lacteal, must run the gauntlet of an accumulated array
of
fresh
therefore,
leucocytes is
met
from the cytogenous
as soon as
latter’s protective resources:
tissue
cells,
endothelial
it
layer.
The
enters the organism by
chyle,
the
all
phagocytes, stellate or connective-
cells,
and
finally
the
oxidizing
sub-
stance, the latter probably serving here to convert products of local
metabolism and other toxic materials into inert bodies.
which thus absorb all nutrient substances assimilated by the organism whether by their venous stems or
The
villi,
319
ADRENOXIDASE AND THE INTESTINES. distributed
thickly
are
lacteals,
tlieir
throughout
the
entire
In the duodenum and jejunum
length of the small intestine.
they doubtless fully satisfy the needs of the organism, both In the lower part of the as to absorption and prophylaxis. canal,
intestinal
however, more protection
is
required,
owing
perhaps to continued exposure of the contents to a relatively high temperature during the time elapsed since this material has been submitted to powerful antiseptic
stomach
A
several hours to a day, according to the meal.
i.e.,
:
treatment in the
morning movement of the bowels, for instance, includes
products of the breakfast of the preceding day, thus representing twenty-four hours of exposure in the intestine to a This additional temperature averaging 39° C. (102.2° F.).
precaution
is
and While the
represented by the solitary lymph-follicles
the agminated lymph-follicles, or Peyer’s patches. solitary lymph-follicles are
found throughout the entire canal,
small and large, they are by far most numerous in the lower
part of the ileum and in the
first
part of the colon.
patches, or the agminated follicles, are likewise
duodenum and jejunum, though site of predilection is also in
Peyer’s
found in the
rarely in the former; but their
the ileum, and, inasmuch as they
vary from one-half inch to four inches in length and are oval or round, they cover to thirty in
number.
practically limited
to
an extensive area, though only twenty Especially
is
this the case since they are
one side of the intestine:
t.e.,
to
portion facing the latter’s attachment to the mesenter ^ 3 also frequently
the
They
form a continuous layer in the vermiform ap-
pendLx.
A
single “solitary follicle” is typical of
ing those in Peyer’s patches.
A
them
follicle consists,
all,
includ-
on the whole,
of a rounded mass lodged in the of its
submucous tissue, a small part upper portion appearing upon the free surface of the
though the epithelium of the intestine also covers it. 'I'he overlying layer of epitlielium, however, is separated from the follicle by a special delicate membrane perforated with a latter,
multitude of holes that surround communicate with the organ itself.
The
its
projecting portion
and
structure of the body of the follicle will perhaps he
best understood if
it
is
divided into three different parts, be-
THE ADRENAL SYSTEM AND THE DIGESTIVE ORGANS.
320
from
ginuiiig
work of
tlie
A
inner portion of the organ.
capillary
blood-vessels
fine
net-
which acts as a supporting
fabric, furnished by underlying arterioles, is the central feat-
ure;
this,
fibrils,
turn,
in
is
surrounded with a close net-work of
in which “lymph-corpuscles, small round cells, with a
large nueleus
and very
little
perinuclear protoplasm” so com-
preponderate as to almost entirely obscure the net-
pletely
But there is a feature of special interest here which remind us of the cell-forming membrane of Kblliker foimd in villi i.e., a central nodule, described by Flemming, in which some cells undergo active karyokinetic division, while others, Ijunphocytes, are formed in continuous quantities. “In the center of the nodule,” say Bohni and von Davidoff,®'""' the cells often show numerous mitoses, and it is here that an active work.®'"'
will
:
The
proliferation of the cells takes place.
cells
may
either
remain in the lymph-follicle or the newly-formed cells are pushed to the periphery of the nodule and are then swept into the circulation by the slow lymph-current which circulates between the wide meshes of the reticular connective third portion
is
tissue.”
The
the interval referred to, a delieately partitioned
sinus which surrounds the
follicle.
To
this sinus the
lymph,
from the blood-capillaries, after it has permeated the meshes and cell-spaces of the adenoid tissue and became charged with the newly created cells, gravitates, finally to find its way into the lymph-vessels of the submucous tissues beoriginally
neath.
The
physiological functions of the follicle seem plain
when
anatomical relations
we consider two salient features of its with the mucous surface of the intestine and with the villi. As to the relationship between 'the interior of the follicle and the intestinal canal,
it is
suggested by the perforations to which
we have previously referred, but tliere seems to be no mechanism to insure absorption. The case is not the same, however, in respect to the connection with the
phatic vessels
villi.
which originate from the
Indeed, the lym-
lacteals of the latter
constitute the afferent supply of the sinus, while the lymphatic vessels of the submucous tissue represent its efferent system. Clarkson:
“Histology,** 1896. Davidoft: Loc.
Bobm and von
cit.
ADRENOXIDASE AND THE INTESTINES.
we
It is very evident, therefore, that
powerful adjunct to the overlying projibylactic villi
means
321
have, in each follicle, a
villi,
to
add
While the
those already enumerated.
to
do not occur upon
another
still
portion of the follicle that projects
tJie
into the intestinal free surface, they are nevertheless present
and their lacteals when below the level of the epithelium break up into vessels which find their way to the lympharound
it,
sinus.
“When
they reach the level of the closed follicles,” says
Berdal,®®^ “the chyliferous vessels
become united
to the sinuses
which they constitute the afferent
of these follicles, of
vessels.
Crossing the muscularis mucosie, they form part of a varicose
net-work
capillary
submucosa.
the
in
arise true l}'mphatic trunks Supplied
intestinal
From
net-work
this
with valves that cross the
and then reach the subperitoneal Ijunphatic
coats
net-work.”
The intimate phatic follicle their
is
relationships between the villus
and the lym-
further emphasized by the similarity which
mechanisms present.
If the l}Tnph-sinus of the latter
considered as functionally encircling
what in the
villus
is
has
been termed cytogenous tissue by Kolliker, including
its
work of
Indeed,
capillaries, this similarity
the fact that the sinus sue instead of in
becomes striking.
net-
situated around the l3unphoid tis-
is
as it is in the villus,
its center,
to indicate that the follicle does
would tend,
not absorb intestinal
fluids,
would merely, before reaching the sinus, be subwhat epuration the epithelium and the fenestrated
since these
jected to
memhrane
overlying the organ could afford. It is, therefore, probable that the solitary follicle or organ does not include absorption among its attributes. Indeed, unless possessed of a suction
mechanism such
surrounded, as its
is
its
as that of the villi, it is evident that,
projecting part, by these minute pumps,
usefulness would he
ver}!"
slight.
hat can be the use, therefore, of the minute apertures encircling the projecting part of the follicle and which constitute
the
“fenestrated”
subepithelial
orifices
memhrane?
“These
appear,” says Ecrdal, “to afford passage to lymphatic cells that emigrate from the follicle toward the cavity of the ““Beraal:
"Hlstologio Normale,”
p. 3C5, 1894.
THE ADRENAL SYSTEM AND THE DIGESTIVE ORGANS.
322
intestine”
—and
to
assist,
considered from
if
ni)’
standpoint
in asepticizing the contents of the lower end of the small intestine
hy permeating
now connect
it
with mobile phagocytes and alexocytes.
If
we
this fact with the predilection of Peyer’s patches for
it would seem as if funcimpairment of these organs would render possible the
bacterial invasion in typhoid fever, tional
pnllulation of pathogenic organisms in the ileum.
This would normally lead to infection of the patches, and of the system at large through the apertures. Besides this
first,
and
I
may
tective function, the follicular sinus,
by serving as a secondary
for the chyle, appears to afford a supplemental pro-
jiassage
tection to the organism of no
that
add, very important pro-
mean power
Avhen
we
consider
serves not only as a channel for freshly-manufactured
it
leucocytes, but that the follicle simultaneously receives freshly-
oxidized blood directly from the great arterial trunks, through
the mesenteric arteries.
This blood, which reaches the lym-
phoid tissue through the rich intrinsic capillary net-work to
which
I
elements
have referred, doubtless furnishes
way
with the various
—
the metamorphoses retrogressive and by Flemming and others, then forces its
required
progressive
it
for
—
^noted
into the sinus, carrying with
it
not only the newly-created
but also serum supplied with all the defensive agencies which the blood affords. The accumulation of Peyer’s patches cells,
in the lower two-thirds of the ileum seems to point directly to
—
most toxic part of the canal and clinicians well know how frequently this region becomes the seat of intestinal
this as the
disease.
It
would thus appear
as if in the
duodenum, the jejunum,
and the upper part of the ileum, the gastric juice, the secretion of tlie crypts of Lieberkiihn and that of the glands of Brunner, would subserve the to the end of the and that beyond protective process ileum, the follicles, either solitary or agminated in patches, in
addition
the
to
ultravillous
process,
this,
;
the villous process plus the folliculous process, including the output of lymphocytes into the intestine, united to accomplish the same prophylactic purpose.
The
colon
is
deprived of
villi,
but plentifully supplied with
crypts of Lieberkiilin, while solitary glands, somewhat larger
323
ADRENOXIDASB AND THE INTESTINES.
than those in the ileum, are scattered throughout its entire The former doubtless furnish the mucus, while the extent. latter
probably contribute the asepticizing lymphocytes.
Here
as
in
other organs of the
alimentary system the
sympathetic system alone, through its vasoconstrictors, does not account
for
vasodilation.
the
This
phenomenon which is
function,
initiates
Disturbance of the functions of the adrenal lesions of their nerves seriously
ing process.
i.e.,
supplied, as in the stomach, by the vagus.
Onuf and
hampers the
intestinal
system by
immuniz-
Collins refer as follows to the disturb-
ances that result from extirpation of the stellate ganglion in
“They .consisted of diarrhoea and putrefaction of the The faecal matter was semiconsistent, of yellow or darkgrayish-brown color, and of exceedingly foul odor. This putrefaction of the faeces was observed in two of the three animals from which we removed the stellate ganglion. In the third cat they were not noted; but it should be added that this cat was killed before a time corresponding to that which had elapsed antecedent to the occurrence of putrefaction in the first two cats. The putrefactive symptoms made their appearance as late as two or three months after the operation, and it was noted that the digestive disturbances had a tendency to increase and persisted until the death of the animals, three and four and one-half months, respectively, after the operation. In one instance the autopsy revealed marked aniemia of the incats:
faeces.
testines.”
We
are dealing, in these experiments, less with the effects
of section of intestinal
nervous supply on the local vascular
walls than with those of impaired adrenal functions,
as
the
extirpated stellate ganglion contains fibers to the thyroid, whose secretion sustains the functional activity of the adrenal center.
Decrease of adrenal secretion, the plasma, was the
i.e.,
main morbid
of
o.xidizing
factor.
substance in
The functional
energy of the intestinal crypts, glands, and follicles being impaired through loss of part of their pabulum energeticum in the blood, the asepticizing secretion of the crypts of Lieberkiihn
and the glands of Brunner became reduced, the production of IjTuphocytes by the follicles likewise, wdiilc the reduction of oxidizing substance in the secretions per se contributed to fur21
—
o24
THE ADRENAL SYSTEM AND THE DIGESTIVE ORGANS.
ther impair their prophylactic qualities. refer to
Onuf and
Collins also
one of their animals ope'rated in the same way, in
which diarrhoea developed in two weeks; the third week “the animal began to be uncertain in gait, which increased to wellmarked staggering” “within two da}’S it died in collapse.” That the functions of important organs the thyroid and adrenals had been impaired, is evident. The following deductions seem to me to be warranted by .
.
.
—
—
the analysis submitted:
The glands of LieberTcuhn and the duodenal glands of Brunner supply a secretion the purpose of which is to asepticize the intestinal contents.
The
villi,
through their venules and
and chyle-forming materials from
lacteals, absorb nutrient
the intestinal foodstuffs,
the contents of the lacteals are submitted to a
and
further asepticiz-
ing process, mainly in K'dllilcers cytogenic membrane.
The
solitary
and
agminated
lymph-follicles
(Beyer’s
patches) are cytogenic structures which further asepticize the materials absorbed by the surrounding villi, the efferent lymphvessels of the latter constituting the afferent lymph-vessels of the follicles, where both Icinds of organs occur together: i.e., in the
portion of the small intestine in which pullulation of pathogenic bacteria is most likely to occur, the ileum particularly.
The
solitary
and agminated lymph-follicles
also supply leu-
in cocytes to the intestinal canal, which leucocytes are formed out pass their- cytogenic area (Flemming’s central nodule) and
through the fenestrated membrane overlying each
follicle.
The
to insure the destruction
jmrpose of some of these leucocytes is result of putrefaction of the of pathogenic agents formed as a intestinal contents or introduced into the intestine. rich In the colon, the asepticizing process is fulfilled by a bathed walls its keep which supply (1 ) of Lieberkuhn’s crypts, irregularly scatwith their muco-serous secretions; and (2) of latter secretion tered solitary lymph-follicles, which supply the with bactericidal
cells
and
their antitoxic blood-scrum.
the The nervous supply of the intestines is derived from various the to vagal and sijm pathetic systems, the distribution to that similar being action mode of intestinal coats and their inifibers vagal the stomach: While of the same nerves in the
—
325
FUNCTIONS OF THE VERMIFORM APPENDIX.
causing vasodilation, the sympathetic fibers
Hate function
hi/
arrest function
by restoring the arteries
to their
normal
caliber..
—
Vermiforji Appendix. Solitary follicles being also very numerous in the cascuni, and the appendix so rich in agminated follicles as to have suggested to some anatomists that it was a large Peyer’s patch, I
was
led, in
view of the facts presented
in the foregoing pages, to the conclusion that
The ccecum, being
:
particularly exposed to the accumulation
of putrefactive materials, is supplied with
an organ in which
agminated lymph-follicles are particularly numerous,
The functions
vermiform appendix.
of this organ,
i.e.,
the
therefore,
be to supply the ccecum with bactericidal cells
and
phagocytic leucocytes and
alexocytes
(in
addition to those supplied by the ccecal agminated follicles)
and
appear
to
products,
their
i.e.,
antitoxic blood-serum.
Shortly after this conclusion had been published in the first
Prof.
edition of the present
MeAdam
work
(Januar}",
1903, page 323)
Eccles, of London,^®® stated, in his
Leetures, that practically
little
or nothing was
Hunterian
known concerning
the functions of the appendix, though he thought that
it
was
Favoring
probably “in part absorptive and in part excretive.”
the latter view he pointed out that the action of the muscular fibers in its
muscular coat tended “to force
its
contents toward
and into the cavity of the ciecum,” the caliber of the aperture, “while amply sufficient in its natural state to allow the free evaeuation of secretion from the itself.”
He
also
shows that in at
positions of the organ, its orifice
mucous membrane least
was
of the tube
two of the fairly
common
so situated as to facilitate
“the exit of the secretion.”
Corpe®^' in experiments on dogs found that the appendix secreted considerable fluid, estimating this at four ounees daily in these animals, and that the secretion was powerfully germicidal. Hoefer*®® noted, in the course of appendiceetomy, that the appendix secreted a light, strawcolored fluid, and refers to Macewen as having seen a stream of alkaline fluid poured
from the appendix just before the cscal contents passed into the colon. Each time a small quantity of
chyme passed the Eccles:
Corpe:
“eHoefer:
orifice
of
the
appendix
London Lancet, March 14, 1903. Medical Sentinel. May. 1903. St. Paul Med. Jour., Jan., 1907.
it
would become
—
— ;
THE ADRENAL. GENERAL MOTOR. AND VAGAL SYSTEMS.
326
smeared by the exudation therefrom.
Condi
is
referred to as
stating that six ounces of this fluid were secreted in the twenty-
Hoefer concludes with Bunge and others that the
four hours.
purpose of this fluid
is
to alkalinize the caecal contents before its
migration to the colon. London,®^''
Eecently, however, E.
M. Corner,
of
a comprehensive study of the subject, con-
after
cluded that the vermiform appendix was “a specialized part of the alimentary canal, nature having structure and endowed it
lymphoid
tissue
organisms of the
use of a disappearing
with a secondary function, by giving
it
to
made
protect
ileo-csecal
body against the micro-
the
The trend
region.”
of evidence,
toward the immunizing function I attribute to the organ, a role which the resemblance of the glandular elements of the appendix to the tonsils had led various observers, notably
therefore,
is
Kilbourn,®®' to suspect.
The
Liver and its Physico-Chemical Functions. There is considerable evidence available to show that oxidation is one of the most active factors of hepatic functions, and yet it must be admitted that, according to prevailing views, there is no blood-supply capable of accounting for this powerful
To
source of energy.
the portal vein, essentially a channel
for physiologically impotent blood,
blood replete with the
i.e.,
waste-products of four important organs and the oxygen of
which has been ponderating
utilized in these organs,
role.
On
thought to supply the
—
is
ascribed this pre-
the other hand, the hepatic arter}'
liver
“with the blood of nutrition.”
is
Text-
books on physiology, therefore, seldom refer to this vessel works on histolog}' hardly grant it more than two or three lines, In text-books on anatomy it receives if they refer to it at all. attention, but only in its general topographical bearing.
more
As viewed from
my
standpoint, the hepatic artery does not
only supply the liver with ously with the blood
upon
its
nutritional blood, but simultane-
tvhich all its functions depend.
develop this proposition a review of the histology of Clarkson®'* gives the following comthe lobule is necessary.
To
plete,
though succinct, description of
this
Corner; Annals of Surgery. Oct.. 1910. “‘Kllbourn: Philadelphia Med. Jour.. May 17. Clarkson: “Text-book of Histology.” 1896.
**
wonderful
1902.
little bod}'
327
FUNCTIONS OF THE LIVER.
—about
one-twentieth of an inch in diameter
—and
which in
has been termed a “miniature liver” “A lobule of the liver is polygonal in shape, and
itself
composed chiefly of a number of gland-tubes, which radiate from near the center of the lobule to the periphery, where they open is
Thus, the blind terminal end of the tube
into their ducts.
is
turned toward the center of the lobule; the ducts at the periphery lie in the interlobular connective tissue, which to the
naked eye marks the boundaries of the lobule. “The blood brought to the liver by the porUl vein^^ conveyed along
its
subdividing branches
which lie, surrounding the
divisions are reached,
connective tissue
till
ultimate sub-
tire
together with the lobules.
is
Here
bile,
in the
capillaries arc
which pierce the lobule and pass between the radiatgiven ing gland-tubes to reach the center, where they open into the off
intralobular radicle of the efferent vein of the liver, the hepatic vein.
—^the
These small hepatic radicles open into the larger vessel, and the sublobular veins unite to con-
—
sublohular vein,
tribute to the hepatic vein itself.
The
walls of the branches
of the hepatic vein are destitute of muscular fibers
adventitia
is
extremely thin.
and the
The radiating gland-tubes
tomose laterally with each other, as do the capillaries
The meshes
anasalso.
of the net-works are elongated in a radical direction.
is composed of a radiating system of gland-tubes and a corresponding radiating system of capillaries lying between them. A very minute quantity of connective tissue
Thus, a lobule
accompanies the capillaries as an adventitia and in this Ijunphatic channels are to be found separating the gland-tubule
from the blood-vessel.
“The
lobule
is
surrounded (in part or whole) with con-
nective tissue supporting branches of the afferent portal vein,
—the
feeder of the
capillary net-work,
—and
the
hile-ducts,
which receive the secretion of the gland-tubules. Thus, the blood flows from the periphery to the center of the lobule; the bile, from the center to the periphery.
“But in addition duets another vessel
The
italics
are
my
and the bilefound in the interlobular connective
to the afferent portal vein is
own.
THE A.DRENAL SYSTEM AND THE DIGESTIVE ORGANS.
328
This
tissue.
is
the lieixitic artery, which supplies blood for the
nutrition of the connective tissue of the organ, the vessel-walls, It ultimately terminates in the small portal veins,
etc.
and
perhaps partly in the capillaries in the periphery of the lobules.”
There
some uncertainty
exists
manner
as to the
in which
the subdivisions of the hepatic artery are related to the other perilobular
and intralobular
Pick and Howden®* refer
vessels.
to its terminal distribution as follows:
“Pinally,
it
gives off
form a plexus on the outer side and the accompanying bilelobular branches enter the lohule and end in
interlobular branches, which
of each lobule, to supply its wall ducts.
From
this
the capillary net-work between the
however, doubt whether
it
Harrison
capillary net-work.”
Some
cells.
anatomists,
transmits any blood directly to the
“Each
says:
Allen®'^
lobule
is
a miniature liver having at its periphery between the lobules
branches of the portal vein and hepatic artery
(interlobular
branches) which freely intercommunicate and form through the
and
lohule, betw'een its periphery
Directly at
the
center, a capillary net-work.
center the venules of this net-work
(intra-
lobular vessels) converge to form radicles of the hepatic vein.”
Labadie-Lagrave^® states that, “as regards the divisions (of the hepatic artery)
destined for the lobules, they penetrate con-
jointly with interlobular veins, hut without
communicating with
them, in the interior of the lobule, in the vergent views, which but exemplify
all
lies
capillaries
In the presence of these
distributed to the central vein.”
our only choice
form of
other
of
tliose
in the selection of the one region which
authors seem to consider as reached by the artery:
periphery of the lobule. arterial
capillaries
intralobular
But, as
penetrate in
supply,
we
Piersol,
“
all
is
who, in accord with
we
believe
that
—the
more conthe annexed engraving by
the true one
many
the
another to the
or
—though
indicated in
i.e.,
concede, also, that the
one way
adopt
will
Harrison Allen’s definition servative distribution
di-
authors,
describes the
histologists,
Pick and Howden: “Gray's Anatomy”: edition, 1901. Harrison Allen: “Human Anatomy,” 1884. Labadle-Lagrave: “TraitO des Maladies du Foie,” 1892.
,
329
FUNCTIONS OF THE LIVER. hepatic
artery
as
“supplying
to
nutrition
the
interlobular
capillary net-work. structures and terminating in the lobular envelopnoteworthy feature of the capillary net-work
A
ing the cellular bodies
one
cell,
but
is
that each
Indeed,
several.
mesh does not merely
cover
the
hile-
were
otherwise,
it
capillaries could not exist as individual channels
and give an
to their contents without allowing the To prevent this, and yet bile to penetrate the blood-stream. simultaneously insure perfect exposure to the blood and lymph,
uninterrupted free
a very simple
way
arrangement
exists
:
i.e.,
three or
more
of the
Section op Liver Showing the Lobules, Cells, and the Blood-supply. (Piersol.) H.A., Hepatic artery.
P.V., Portal vein.
cells
H.V., Hepatic vein.
(usually polyhedral) are joined longitudinally, and, while
the narrow passage serves as
the blood-
in the
a bile-channel,
and lymph-
center of the group thus fonned
the outside only capillaries.
When
is
in contact with
only two
cells
are
thus joined, the surfaces in contact have in their center a small
opening, which, being adjusted to that of the adjoining insures the continuity of the channel.
that the blood-plasma
may
cell,
It thus becomes clear
penetrate the
cell,
undergo or in-
duce metabolism therein, and the product pass out through the intercellular biliary passages or bile-capillaries.
The
cells
THE ADRENAL SYSTEM AND THE DIGESTIVE ORGANS.
330
are so joined as to form continuous, tliough correlated, chan-
which radiate from the center of the lobule
nels,
ery,
The intimate possesses is
to its periph-
where they join the interlobular bile-channels. structure of the hepatic cell
no limiting membrane; but
more dense than that
is
peculiar.
It
peripheral protoplasm
its
of its other parts
and the pseudocov-
ering so formed serves as the outer wall for numerous cavities or vacuoles which inosculate irregularly throughout
more
All these vacuoles, however,
rior.
inte-
its
or less directly con-
verge toward the center, where they meet a protoplasmic mass,
which in turn contains one and sometimes two nuclei. The cell, apart from its nucleus, suggests a miniature sponge the become filled with (secretion vacuoles) cavities of which
Biliary Canaliculi. a,
A
{Mathias Duval.)
biliary canaliculus cut transversely,
glj'cogen.
This substance seems
b.
Intercellular capillary.
accumulate in the outer
to
which appear wider in this location than the inner when, by artificial means, the glycogen has been removed.
vacuoles, ones,
noteworthy that this substance accumulates in the part of the cell nearest the blood-vessels and that the droplets, or “granules,” considered as bile are most abundant It is perhaps
in the opposite direction
:
i.e.,
near the bile-capillaries.
These
“droplets” accumulate between periods of digestion and diminA delicate canaliculus connects this ish during this process.
part of the
cell witli
the biliary channel.
The
vacuoles in the
in paraplasm, according to ICupffer, ‘^play an important part of confluence the the secretion of the cell, and are due to As soon as the minute drops of bile into a large globule.
vacuole has attained a certain size
it
tends to empty
its
con-
FUNCTIONS OF THE LIVER.
331
tents into the bile-capillary through a small tubule connecting
Kupffer’s
the vacuole with the bile-capillary.”
main vacuole
thought by him to constitute an intracellular vesicle connected with the bile-capillaries by means of delicate tubes. is
The
nerves of the liver enter the organ at the transverse
and accompany the blood-vessels and lymph-vessels to the interlobular spaces. That the vagus causes vasodilation of the hepatic arterioles was first observed by Cavazzani and fissure
Manca.®”
.
Frangois-Franck and
Hallion'*'’
also witnessed vaso-
on stimulating the central segment of the divided vagus with a weak current. Bruno^^ has shown, moreover, that the flow of bile was increased concomitantly with the passage dilator effects
of food-products through the pylorus under the influence of
the vagus.
The
vasoconstrictor
action
of
the
sympathetic nerve on
who found that stimufrom the coeliac plexus caused anaemia which they were distributed. Haffter,
the liver was pointed out by Vulpian^^ lation of nerves derived
of the hepatic area to
Samuel and Frerichs
all
observed congestive coloration phe-
nomena on dividing the splanchnic nerve and the plexus, similar to those that follow, in the ear, face, tion of the sympathetic nerve in the neck.
coeliac
etc.,
sec-
MalP® showed that
the splanchnics also contained vasomotor fibers for the portal Bayliss
vein.
and
Starling^'*
then found a rise of the blood-
pressure in the portal vein occurred in the dog, racic nerves between the third
were stimulated, the
maximum
the fifth to the ninth inclusive.
when
the tho-
and eleventh thoracic inclusive effect
following excitation of
Cavazzani and Manca^"^ were
led to conclude that hepatic vessels were also
under the influence of such nerves by passing warm saline solution at a given pressure through these vessels and measuring the outflow in a given
time.
Hallion.^®
™ and
This
The
was
confirmed
latter physiologists
by Frangois-Franck
Cavazzani and Manca: Archives ital. de biol., T. xxiv, p. 33, 1895. Frangois-Franck and Hallion: Arch, de physiol, norm, et path., T. ,
ix, 1896.
" Bruno:
Archives des Sc. biol., T. vil, p. 87, 1899. “Vulpian: C. R. de la Soc. de biol., p. B. 1858. “Mall: Archiv f. Physiol.. S. 409, 1892. “ Bayliss and Starling: Jour, of Physiol., vol. xvil,
“Cavazzani and Manca: Loc. cit. “ Frangois-Franck and Hallion: Loc.
cit.
and
showed, moreover, that the
p. 120, 1894.
viii,,
THE ADRENAL SYSTEM AND THE DIGESTIVE ORGANS.
332
true vasoconstrictor effects of the sympathetic were produced
by
from the cord on a level with the sixth thoand second lumbar inclusive, all passing to the splanchnic
fibers derived
racic
nerves.
On
the whole,
evident that the functions of the liver and inhibited by sym-
it is
are incited through vagal vasodilators
pathetic vasoconstrictors as in the stomach
Our inquiry
into
and
intestines.
the character and composition of the
substances that are transformed in the liver and of the secretions of this organ
must necessarily include the blood
portal vein, since
contains whatever products of metabolism
the organ
is
it
We
thought to transform.
shall, therefore,
of the
begin
with this channel, which brings to the liver essentially venous blood,
since
it
contains
— —
the by four organs the pancreas and the spleen in
that utilized
stomach and the intestines, which the metabolic products include, besides those incident
upon tissue-waste, food metabolites, physiological As is well known, there exist in the liver’s evidences
tinct
of
known
to
modify the com-
passes through
it,
but the purposes
The
position of the blood as
it
secretions dis-
with splenic haematopoietic or
association
haemolytic functions.
toxics, etc.
liver is
of the alterations involved are not established.
The Splenic Vein
.
—The path from the spleen
vein, through the splenic vein,
spleen sends to the liver
is
is
to the portal
a direct one, and the blood the
not, therefore, modified in transit
by any other organ, though the splenic vein receives a few Still, these are mere
branches from the pancreas and stomach. tributaries to a
common
comes directly from the
channel, and, as the arterial supply plexus,
coeliac
we can
say that the
spleen receives nothing but pure, freshty-oxygenated blood in
great
quantities.
Indeed,
the
splenic
artery
is
remarkably
and we can easily account for the so-called “ague-cake” and the temporary enlargement that occurs during malarial and other fevers when we include large for the dimensions of the organ,
suprarenal overactivity and excessive vascular tension in the pathogenesis of these phenomena.
To
this
we cannot
ascribe,
however,
the
post-prandial
splenic enlargement, which attains its maximum about five hours after an ordinary meal, since we now know, how inde-
333
THE LIVER AND THE SPLENIC VEIN.
pendently of suprarenal overactivity and merely through nervous influence an organ’s function can be excited and governed;
and pneumogastric again unite here to a passive period and for an active period: that
sympathetic
indeed,
account for
of gradual enlargement. to be
of the spleen seems
due to a relaxation both of the arteries and of the mus-
cular tissue of the capsule
Foster
evidence that
:
arterioles to areas,
“The turgescence
we
and of the trabeculae” says Professor are again dealing with dilation of the
increase the influx of blood into the functional
—the physiological process we have found
in other organs.
That the organ is concerned with some process incident upon blood-changes is evident. But what is this process? The various points that
may
afford a clue are these:
red blood-
corpuscles have been found in various stages of disorganization in the organ, but in the interior of amoeboid cells buried in the
The spleen-pulp
also contains an albuminoid proteid and a pigment which shows considerable carbon. That an active combustion process may go on in the organ is suggested not only by the latter, but also by the presence of various purin bases ; xanthin, hypoxanthin, and their end-
pulp.
rich in iron,
produet, uric acid. succinic, lactic, etc.
Various other acids
—
—
acetic, butyric, formic,
are also found in relatively large quan-
This appears suggestive when we consider the large
tities.
quantity of oxidizing substance that must course through the
organ especially during post-prandial activity.
The
spleen also seems to be a leucocytogenic center, since
the splenic vein contains a
much
cytes than the splenic artery.
larger proportion of leuco-
But
as these leucocytes leave
the organ through the splenic vein, and ultimately, therefore,
reach the liver through the portal, they must either be connected with some function in the liver or be destroyed there. Again, the arterial blood has been found to lose one-half of its
red corpuscles; half
of
those
from the spleen contains onefound in the blood of the splenic arteries. at least, blood
Coupled with the finding of disorganized remnants of these bodies in the splenic pulp, this certainly suggests, as
is
erally believed, that red blood-disks are disintegrated arid
corpuscles created in the spleen.
poor in red disks.
gen-
white
Indeed, the portal blood
Yet, the hepatic vein
is still
is
poorer in them
THE ADRENAL SYSTEM AND THE DIGESTIVE ORGANS.
334
in the sense that the proportion of red to white cells
is
as
four in the subhepatic vein is to one in the portal vein, after the blood has been submitted to the elfects of hepatic functions.
seems
It
clear,
therefore, that red corpuscles
are de-
stroyed both in the spleen and in the liver, and that, since the spleen
possessed of no external duct,
is
secretions that
we should
corpuscular elements.
find proofs
Indeed,
it is
in the liver’s
of this dissociation of
we have
in bilirubin,
a bile-
pigment derived from hiemoglobin, direct evidence of this fact. The Hepatic Blood-pigments We have already analyzed .
the second
(in
chapter)
—
the process through Avhich
We
blood-pigments are transformed one into another.
now only
refer, therefore, to the relations
various will
between these bodies
and the spleno-hepatic functions.
We
ascertained that the changes undergone in the liver
represented but a portion of a cycle of which the intestines were the starting-point, bilirubin (excepting that transformed
and stercorin) being reabsorbed from the intesand again used in the building up of ha?moglobin. Experimental evidence was adduced to show (Macallum) that in an animal fed on albuminate of iron free leucocytes crowded into urobilin
tine
with iron-pigment could be traced in transit through the in-
mucous membrane in the villi, and that similar leuhad cocytes been found in the spleen and in the liver. But can we conclude from this that the iron-laden leucocytes find their way to the spleen and that this organ constitutes a part testinal
of the cycle?
The anatomical
volved show that, even
if
relations of the structures in-
such an arrangement did
exist,
it
could serve no useful purpose, since the leucocytes would but penetrate the splenic structures to again enter the portal circulation. is
the
Obviously, the only pathway available anatomically
venous
one,
since
Macallum
found
the
‘fieucocytes
crowded with granules of iron-pigments” in the venules of the villi.
The
single venous channel
that of the distribution of the
mainly,
i.e.,
at our villi,
disposal, therefore,
is
the ileum and jejunum
the superior mesenteric veins,
—which
again lead
This probably means that the iron thus taken from the intestine is not ready for the circulation, and
us to the portal vein.
— 335
THE LIVER AND BLOOD PIGMENTS. that it
must undergo a secondary process
it
can serve
pliysiological
its
tion.
This
tions
of the
is
in the liver before
purpose in the arterial circula-
sustained by the prevailing view as to the funcspleen,
i.e.,
that
it
disintegrates
worn-out red
by the great increase of leucocytes observed in the splenic vein as compared to the proportion of these cells in the artery. It seems logical, therefore, to conclude corpuscles,
and
also
that both in the lymphatic structures of the intestine
and in those
formed which carry iron-pigments to from the intestine reach the latter by the superior mesenteric vein, and those from the spleen by the splenic vein. As Macallum observed iron-pigment leucocytes in the spleen similar to those witnessed in the intestinal villi, and the of the spleen leucocytes are
the portal vein; those
venules of the latter and the splenic vein ultimately transmitting their blood to the portal vein, no other conclusion seems possible.
The
similarity of the general
mechanism involved suggests
the presence of correlated functions. leucocytes are
formed in
situ,
Thus, in the spleen the
pass out into the pulp-channels,
and take up the iron-pigment and carry it out to the liver; in the follicle, the intestine they are formed in a similar structure,
—
—
pass out into the intestinal channel, take on a similar supply
blood-pigment, re-enter through the
of
system, and also proceed to the
liver.
villi
into
the
ascribed bactericidal properties to the leucocytes produced intestinal follicles;
which
is
shown by
their ability to take
the pigments, serves but to demonstrate that they
It
was
least
also
by the
but the chemotaetic property of the leuco-
cytes, the existence of
endowed at
venous
True, I have previously
must
up
also be
with phagocytic attributes.
shown, in the earlier editions of this work, that,
while the adrenals supply an o.xidizing substance to the blood, insufficiency of the
pound inferior
to
adrenals leads to the formation of a com-
haemoglobin in oxygen-absorbing powers,
methacmoglobin ; and, furthermore, that haematoporphyrin formed when the suprarenal insufficiency is still further ad-
i.e.,
is
vanced, hae,moglobin being unable to hold itself together, as it were, and to absorb oxygen. Again, we saw that haemoglobin
reduced to haematin when the reaction with the reducing agent occurs in the presence of oxj'gen. In tlie absence of oxj^gen
is
—
THE ADRENAL SYSTEM AND THE DIGESTIVE ORGANS.
336 a
hiemochromogen
is
formed which slowly
loses its
the
iron,
end-product being also hiematoporphyrin.
hemoglobin mole-
It is evident that the integrity of the
cule
dependent upon the quantity of secretion that the ad-
is
and
renals supply to the blood,
molecule at a given time.
may
also
upon the condition of that
In other words, while the adrenals
be supplying their normal proportion of secretion, the
hemoglobin molecule in the red corpuscles of venous blood blood about to return to the vena cava for
i.e.,
pty—may
a
fresh sup-
be compared to that of blood during insufficiency.
Even as hemoglobin, the blood-pigment is when approaching the end of its systemic
loosely combined; circle,
nearer the state of disintegration
—according
the oxidation processes which
has subserved.
it
is
it
still
to the activity of
Starting fro.m
it returns promptly to the heart as hemoglobin or reduced hemoglobin, ready to absorb at once
the lungs as oxyhemoglobin,
another supply of suprarenal secretion and, once in the lungs, take
up
its
oxygen.
Blood from the head, extremities, and other structures which the drain upon ^its resources has not been excessive
re-
turns such a molecule to the heart;
an
oxygen-carrier.
But not
so
it
is
efficient
As
is
pancreas, and spleen
—
is
known,
well
the blood from the organs of the alimentary tract
intestine,
as
with the hlood from any organ
directly connected with the digestive system. all
still
in
—stomach,
not returned to the heart
has been submitted to whatever action the liver may have upon it; then only can it re-enter the circulation through the hepatic veins, which carry the blood to the vena cava. But before
it
thus be rejuvenated; some has gone beyond ; it has, indeed, almost readied the state of ha?matoporphyrin, the last on the list of pigments, that which appears in the e have seen most advanced stages of suprarenal insufficiency.
not
all
the blood
may
that luematoporphyrin and bilirubin are similar ; and, as known, it is bilirubin which passes out with the bile.
A
salient feature of the hiemoglobin molecule
here, however,
namely; the
iron.
As
is
is
well
missing
stated, a reducing agent,
luemoglobin in if used in the presence of oxygen, will reduce the absence of oxygen; the primary' product is a lucmochromogen which gradually parts with its iron, leaving as end-
337
THE LIVER AND BLOOD PIGMENTS.
As
product hcEmatoporphyrin.
bilirubin
and liannatoporphyrin
are fundamentally identical, the presence of the former in the bile
such
is
first
of
the case
which
That
result of a similar process in the liver.
must be the
is
sustained by considerable collateral evidence, the invulnerability of the hannoglobin mole-
is
cule.
Paradoxical as this statement appears,
it
nevertheless con-
stitutes the key-stone of the entire edifice, since
it is
when
only
vulnerable that the molecule becomes the prey of disintegrating influences.
have used the words “reducing agents” several
I
times; but the haemoglobin molecule does not yield to even
moderately-strong
powerful it:
agent
reagents
—
of
nature ;
this
sulphuric acid,
for
only
indeed,
—
instance
a
dissociate
^will
an exemplification of the wonderful binding power which
the suprarenal parts.
secretion
must
exert
we must not overlook
Still,
substance in the blood-plasma
is
all
its
constituent
the fact that the oxidizing
identical to this binding
Indeed, I have accumulated so
pound.
upon
the fact that the plasma per se
much testimony
com-
affirming
a potent source of energy,
is
while the red corpuscles always played so secondary a role in the various intrinsic functional mechanisms, especially those con-
cerned with muscular and glandular elements, that I have been led to conclude that the red disks are, after
the blood-plasma
pack-mules, as
it
:
all,
but servants of
were, from which
draw, as needed, enough oxidizing substance to maintain
it
can
its
own
functional potentiality as previously stated.
Under
we can
see how the haemoglobin molecule, gradually deprived of its binding oxidizing substance during the inordinate metabolism which the tis-
these
circumstances
sues of the digestive organs activity,
It is
readily
undergo during their periods of
should yield more readily to dissociating influences.
evident that a molecule so weakened, thrust in blood
such as that of the portal vein, physiological
waste-products
—a
and
vast
sewer replete with
deoxidized
blood-cells,
all
bathing in a plasma itself despoiled of its oxidizing substance, should soon become dissociated. Transported through gradually narrowing channels, the walls of which, like all tissues, eagerly absorb any loose oxygen that it may contain, it must
mevitably undergo the transformation of haemoglobin referred
THE ADRENAL SYSTEM AND THE DIGESTIVE ORGANS.
338 to,
drops
leaving as end-product bilirubin.
its iron,
We or
the primary haemocliromogen, which soon
into
i.e.,
have here the identical process that occurs in the brain
other
when
structures
haimatoidin
preparatory
from
originate
“The
absorption.
haemoglobin,”
disorganized
are
blood-clots
to
Professor
says
into
bile-pigments
Howell
“this
;
origin was first indicated by the fact that in old blood-clots
or in extravasations there was found a crystalline product, the
which was undoubtedly derived from haemoglobin, and \vhich, upon more careful examination, was proved to be identical with bilirubin. This origin, which has so-called
fiiaematoidin,’
since been
upon
as
made
probable by other reactions,
That the infiuence
adopted.”
solid a foundation
of Boinet,
is
who found the blood
is
now
universally
of the suprarenal secretion rests illustrated
of a large
by the experiments
number
from
of rats
which he had removed the adrenals replete with “liasmatoidin.” To trace the itinerary of the two products, iron and bilirubin,
through the
liver,
naturally
brings
the
hepatic
cell
within the scope of our inquiry, since we have to account for the transfer of the former to the bile and the return of the iron to the general circulation.
The
importance
functional
molecule
is
generally
separated from
it,
recognized.
of
iron
Yet,
are not unable to take
we have ample evidence
in the
the
hiemoglobin
pigments,
up oxygen.
when
Indeed,
of this in the formulae of the very
products of which bilirubin is the primary compound. Thus, while bilirubin is CigHigNjOa, biliverdin is CiaH,gN204, and the latter can readily be prepared artificially from the former
supposed that, when the blood-corpuscles go to pieces in the circulation,” says Howell, “the haemoglobin of the is brought to the liver, and then, under the influence
by oxidation.
“It
is
converted into an iron-free compound: bilirubin It is very significant to find that the iron sepaor biliverdin. rated by this means from the haimoglobin is, for the .most part, retained in the liver, a small portion only being secreted in the liver-cells,
.
bile.
It
is
seems probable that the iron held back in the
again used in some
way
topoietic organs.”
We
fluence ofihe
to
make new Immoglohm
have seen that
liver-cells, as
now
it
is
believed, that
liver is
in the luema-
not uniter the in-
hwmoglobin
is
dis-
— 339
THE LIVER AND BLOOD PIGMENTS.
an important feature, since it removes the main element of confusion from our path. Indeed, we can now easil}" sociated:
account for the retention of the greater part of bilirubin in the liver, since
we have
at our disposal all the constituents for the
synthetic production within the portal capillaries of the hepatic
new lupmoglobin, and
lobule of
particularly oxidizing substance,
brought there by the terminals of the hepatic artery.
On
examining, on page 329, the illustration from Piersol’s
work, the distribution of the hepatic artery’s terminal arterioles or capillaries will be found to be unusual.
margin
the
vein breaks
of the lobule
up
into the capillary net-work of the lobule
may
hepatic arteriole
The
inference
from the
Immediately above where the portal or interlobular
i.e.,
is
obvious.
coeliac axis,
—the
be seen to open into the portal capillary.
The hepatic artery coming
brings freshly oxidized blood,
—which, mixing
—
directly
i.e.,
oxidiz-
narrow channels of the lobule with the portal blood, at once groups bilirubin and iron, and builds up all the hwmoglobin that the constituents ing substance,
freely in the
present (including what iron the splenic leucocytes
from the
intestinal follicles have brought)
and those
What
allow.
bili-
rubin cannot, owing to deficiency of either of the other constituents, be utilized, becomes an excretory product; and with many others
it
and
enters the hepatic cell
That
passed out with the bile. (adrenoxidase) can
is
deficiency of oxidizing substance
increase the excretion of bilirubin has been repeatedly herein.
I
may
refer,
for
example, to the
shown
many forms
of
acute poisoning and to the diseases attended with suprarenal insufficiency in
which there
is
increased excretion, either in the
urine or faices, of hiematoporphyrin, methiemoglobin, urobilin, stercobilin, etc. I
:
i.e.,
of
some derivative
have referred to the hepatic
This comparison, due to Berdal, Schafer^’ noted the existence,
is
of hiemoglobin.
a miniature sponge.
cell as
especially warranted, since
within this
cell,
of
canaliculi
which are in direct co.mmunication with the blood-capillaries. Having injected carmine gelatin into the portal vein, the colored substance
filled
this
vessel
and
"
Schater;
Journal of Physiology, Jan. 22
31,
subdivisions,
its
the canaliculi, but no other structure.
It
1902.
besides
may, therefore, be
THE ADRENAL SYSTEM AND THE DIGESTIVE ORGANS.
340
inferred, says Professor Schafer, “that the injection has passed directly from the blood-vessels into the liver-cells; indeed, here
and there one can see what appear to be such direct commuThese can readily be seen in the annexed illustra-
nications.”
He
tion.
on
refers to the conclusion reached by Browicz,-** based
normal and pathological, “that there must
appearances,
exist a net-work of nutritive canals within the hepatic cells which are in direct communication with lobular capillaries”; this he had not as yet, however, verified by injections.
Schafer’s observation probably accounts for the direct transfer of the bilirubin to the biliary capillaries, along with other
Liver of Rabbit Injected from the Portal Vein. The Injection has Passed into Canaliculi within the Livercells.
(A’.
A
.
Hchafer .)
products of oxidation, to which we will refer later on. J.
W. and E. H.
Fraser"*® are also stated to
Indeed,
have found intra-
communicating with the blood-vessels in the For the present it seems logical to conclude that one or more of the canaliculi may lead to the vacuole previously referred to as nearest the bile-capillaries, and that That even it is in this vacuole that bilirubin joins the bile.
cellular passages
hepatic cells of frogs.
this
vacuole Browicz: J.
W. and
p. 240, 1895.
is
supplied with a canaliculus
we have already
Bulletin de I’Acadfimle des Sciences de Cracovie, 1899. B. H. Fraser; Journal of Anatomy and Physiology, vol.
xxlx,.
A
THE LIVER seen; Kupffer found
341
IN ITS RELATIONS TO BACTERIA.
afford a direct channel between this
it to
and the bile-capillaries per se. The Hepatic Tissues in their Relations prominent feature of the work so far done
to
Bacteria
is
the
furnished that several physiological processes
now
bile-reservoir
the hepatic
cell
and
—
evidence
ascribed to
and that the
in no lyay involve this stnicture,
portal vein itself
.
the intercellular^^ capillaries are the seat
of several of these processes.
must be the connection between bacteria and the normal liver. proceeding
Before
made
to
however,
further,
reference
emphasize “normal” here, because I can thus simultaneous!}^ lay stress upon a feature which plays a predominating role in I
disease:
t.e.,
the fact that anatomically, as far as bacteria go,
no direct normal connection between the digestive The liver, in fact, is essentially a system and this organ. physiological organ in the sense that it is mainly intended to there
is
rid the system of waste-products
may
again
and
to
economize others that
by preparing them for reabsorption
prove useful,
in the intestine.
We
have seen that the venules of the
pigment leucocytes
to enter the mesenteric
A
their blood to the portal.
digestive structures
instance
—can
—such
allow
villi
veins which carry
depraved condition of
as that
iron-
all
the
induced by alcoholism, for
so lower the functional activity of these struct-
ures as to cause these venules to lose their normal turgescence
and afford passage to bacteria, alcohol in large doses being known to impair metabolism. The intestinal venules under
weakened protective
these circumstances, surrounded by ures, can well
instance, or
conditions to
struct-
give passage to Adami’s cirrhosis bacillus, for
any other capable of coping with what prophylactic
may
still
prevail.
Labadie-Lagrave.
“One
connections of this kind
of is
“The
portal vein can transport
from the
the liver morbid germs
the
best
intestinal
surface,”
established
the influence exerted
says
pathogenic
upon the
de-
velopment of hepatitis by dysentery; although this relationship is not constant, all observers have noted it. Phlebitis
GO
necessary to give the terminals of the portal this name in order they contain blood from both the portal and hepatic chanform part of both as extensions. S.
to avoid confusion; nels, and in reality
—
THE ADRENAL SYSTEM AND THE DIGESTIVE ORGANS.
342
from an ulcerated area and directed toward an hepatic focus has also been observed. When the primary portal strucstarting
tures are normal, transmission of the putrid material
through the lymphatics.
While
may
occur
this fact seems admissible, it
has not been verified.”
Again, pathological conditions of the stomach, pancreas, or spleen may supply the portal vein with
In the normal subject, however, the liverper tissues se are totally isolated anatomically from any of the
pathogenic elements. structures that
come into contact with exogenous
cisely as they are in other organs:
That
bacteria, pre-
the muscles, the heart, etc.
blood-stream affords protection from disease
its
is
un-
doubted, however, judging from the leucocytes that are con-
and the perivascular lymphatic is also an important field for of toxalbumins and their reduction to harmless
entering the
stantly
That the
channels.
the splitting
bodies itself
we is
organ,
portal vein
shall also see.
But
it
seems quite clear that the liver
not primarily a germ-killing organ, and that are
cell still
further from the functions
suggests
that
vessels
may
essentially
the
oxidizing
to
now
substance
be the main source of the
This brings us
its
at-
This removes the hepatic
chemical.
tributes
attributed to
in
liver’s
the
lobular
it,
and
blood-
functional activity.
the consideration of the functions in
which the oxidizing substance in the blood-plasma acts as a We have already reviewed, in this connection, the reagent. synthesis of haimoglobin; we will now take up and consider two equally important subjects i.e., the origin of urea and the :
conversion of sugar into glycogen.
—
Urea and its Formation. We will first analyze an experiment by Schroder®^ in which the liver was taken from a freshlykilled dog and irrigated through its blood-vessels by a supply Howell refers to this of blood taken from another animal. “If the supply of blood e.xperiment in the following words: was taken from a fasting animal, then circulating it through the isolated liver was not accompanied by any increase in the amount of urea contained in it. If, on the contrary, the blood was obtained from a well-fed dog, the amount of urea con-
Schroder; 1886.
Archlv
flir
exper. Pathol,
und Pharm., Bd. xv and
xlx, 1882
and
UREA AND tained in
it
ITS
343
FORMATION.
was distinctly increased by
jiassing
throngh
it
the liver, thus indicating that the blood of an animal after diffestion contains so,mething that the liver can convert to
urea.”
Considered from
my
During
other meaning.
standpoint, this experiment has an-
digestion, especially after copious feed-
organism
ing, as stated above, the entire
to a certain degree,
is,
involved in the digestive process, as shown by the general sensation of heat often experienced
and spleen, even after
pancreas,
intestines,
has passed, are
all
contains either in
its
In other words,
ing dog’s blood
is
—
corpuscles or in
its
serum a more or
less
Conversely, the
fast-,
especially if the fasting has been prolonged
unusually low, since suprarenal activity
We
that of the rest of the tissues. these their
liver,
digestion
abnormal blood, in which the oxidizing substance
really
is
As
at such times the blood
marked increase of oxidizing substance.
—
gastric
operating together, the suprarenal activity
doubtless enhanced.
is
after such a meal.
conditions,
the tissues
have
depressed with
is
also seen that,
under
continue to
absorb
nevertheless
normal supply of oxygen, the blood being thus actively It seems clear, there-
depleted while insufficiently oxygenated. fore, that the blood of the well-fed
dog contained more oxidiz-
ing substance than that of the fasting one.
That the injected blood taken from the well-fed animal should have been the source of the urea-forming substance Since
unlikely.
products,
it is
substances
the
liver
alone
receives
alimentary
is
waste-
only with blood from the portal vein that such
could have been obtained.
The urea-forming agent must, excised liver’s portal channels,
This
is
not specified.
therefore, have been in the and the only available agency
capable of inducing the reactions involved appears to be the oxidizing substance. Experimental evidence may be adduced
show that such is the case. I consider the blood of the hepatic artery, as previously stated, as the source of supply of the oxidizing substance, since it is directly derived from the to
coeliac
Stewart states that, “although the portal vein much greater supply of blood than the hepatic artery,
axis.
carries a
ligation of the latter causes a greater diminution in the ratio of the amount of urea to the total nitrogen in the urine than
THE ADRENAL SYSTEM AND THE DIGESTIVE ORGANS.
344
ligation of the former.
This seems to indicate that oxidation plays an important part in the formation of urea in the liver
(Doyon and Diifourt).” That the substances thus oxidized reach the liver by the portal vein needs hardly to be emphasized. But Foster says: “The introduction of even a small quantity of proteid material into the-
urine,
and
alimentary canal at once increases the urea in the
in the curve of the discharge of urea in the twent}'-
four hours each meal
is
We
to tliink that the proteids of a
have seen reason
followed
a conspicuous rise.
meal are
absorbed not by the lacteals, but by the portal blood-vessels, and such bodies as leucin probably take the same course. This being so, all these bodies pass through the liver and are subjected
to
may
such influences as
be exerted by the hepatic
cells.”
—one
Such bodies of leucin enous dissociation sel
has
main products of nitrognaturally follow the same course. Drech-
—
suggested that
tyrosin, glycocoll, etc.
all
—
first
of the
bodies
of
this
—
i.e.,
leucin,
undergo oxidation in the
tissues,
class
and that their ammonia and carbonic acid then combine synthetically, forming ammonium carbamate, this, in turn, being carried to the liver and there transformed into urea. It is clear that these
outlined by Foster: veins,
and
i.e.,
ammonia compounds
the venules of the
finally the portal vein.
villi,
take the course the mesenteric
That they undergo oxida-
tion in the blood of these vessels, however,
is
not
likely,
for
they contain probably the most watery blood of the organism,
and that most depleted of Quite anotlier the hepatic lobule
field is
its
oxygen.
when ammonia compounds
of activity is afforded, however,
reached
;
here
the
meet the oxidizing substance brought by the hepatic capillaries.
Taking the
ammonium compound
artery’s
referred to by
Drechsel, for example, the series of reactions outlined by
seem
to follow in normal sequence:
1.
him
In the portal vein:
hydrol 3dic cleavage with the formation of amido-bodies, such as 2. In the hepaticleucin, tyrosin, aspartic acid, glj’cocoll, etc. lobule
capillaries
and
their
oxidizing
substance:
oxidation,
with the formation of ammonia, carbonic acid, and water,
lowed by the synthetic union of ammonia and carbonic
fol-
acid.
—
—
UREA AND
ITS
345
FORMATION.
forming the carbamate of ammonium. urea
;
This being dehydrated,
formed, as shown in the following equation
is
NIL
CO< ONH^ — ILO = CO < That the conversion
ammonia compounds
of
into urea does
by experimental physiology. the experiments of Schroder, in which this
the
occur in
NH,
liver
is
sustained
Howell refers to demonstrated as follows:
“As further proof
is
forming power of the
liver,
Schroder found that
the urea-
of if
ammonium
carbonate was added to the blood circulating through the liver
—
to that
animal
—
from the fasting
It follows,
from the
last
from the well-nourished
experiment, that the liver-cells are
convert carbonate of
able to
actions
as well as
a very decided increase in the urea always followed.
may
ammonium
be expressed by the equation
The
into urea.
re-
:
(NH J 2CO3 — 2H3O = COM,.” The foregoing
facts,
considered collectively, indicate that
the formation of urea in the liver is probably accomplished in
the following manner, taking Drechsel’s series of reactions as
standard of the numerous ones of the same class that must occur in this organ
:
Granting that the nitrogenous bodies are absorbed by the A'enules of the
and transmitted by the mesenwhich would the hepatic lobules, the first reaction would
intestinal villi
teric veins to the portal vein, the ramifications of
then carry them to
occur in the prelobular portal vessels:
i.e,,
the nitrogenous bodies
would undergo hydrolysis, with the formation of amides, leucin, aspartic acid, tyrosin, etc. The second reaction would follow as
soon
owing
as
these
bodies
reached
the
pericellular
capillaries,
to the presence therein of the oxidizing substance sup-
by the terminal branches of the hepatic artery; in other words, further reduction of these bodies by. oxidation to aininonia, carbonic acid, and loater would occur in the pericellular capilplied
laries of the first,
lobule.
The
third reaction would seem, like the
to require comparatively inert suiToundings
not charged with oxidizing substance as cellular capillaries.
is
:
i.e.,
a fluid
the blood of the peri-
Such a medium we have, in
all likelihood.
THE ADRENAL SYSTEM AND THE DIGESTIVE ORGANS.
346
in the aHerent venous
channels, since
it is very improbable that any oxidizing substance, so precious in all physiological functions as I have now shown should be wasted in vessels
—
—
ultimately ending, via the hepatic veins, in the inferior vena
Hence, whether
cava.
it
involved a preliminary formation of
an ammonic carbamate or proceed
to
immediate synthesis,
it
appears as
if the terminal reaction ending in the formation of urea occurred in the efferent venous hepatic channels.
The
salient point of this
of reactions
series
the fact
is
that, contrary to the general belief, they all occur, not in the
hepatic
The
cells, hxit
in the bloodstream of the lobular capillaries.
following facts show this to be the case:
formed in transit through the
if
urea
it
should appear as soon
is
It
or at least soon after,
as,
is
clear that,
vessels of the organ, its
We
agencies are introduced in the portal system.
causative
will recall
from Professor Foster’s text, in which he says: “The introduction of even a small quantity of proteid matethe quotation
rial
into the alimentary canal at once increases the urea in
the urine, and in the curve of the discharge of urea in the
twenty-four hours each meal etc.”
When we
is
followed by a conspicuous
consider that the
entire
circulatory
rise,
circuit
occupies but twenty-six seconds, the cause of the rapid appear-
ance of urea
When
—heretofore
unexplained
—^becomes
apparent.
the role of the oxidizing substance in the produc-
tion of uric acid
from the alloxuric bases was analyzed in the
third chapter, uric acid was considered as the end-product of
a series of reactions in which, according to modern views, these toxic nuclein derivatives were converted into benign ones. All
nitrogenous products being transferred to the portal system, it now seems clear that normally the reaction must occur iu the intercellular capillaries of the hepatic lobules, and that is
when
this oxidation process in the liver is inadequate that
the so-called “uric-acid diathesis” acid
it
leaves
evident that
the
we
organism,
symptoms
occur.
As
as does urea, by the urine,
uric it
is
are again dealing with a function totally dis-
connected from the hepatic
cell
per
se.
Again, we have re-
peatedly seen, in the preceding chapters, that the elimination of phosphoric acid was increased by the administration of suprarenal, pituitary, and other organic extracts and by various
glycogen and
its
347
formation.
by the kidneys due to drugs always coincides with suprarenal overactivity, hence with enhanced oxidation. It thus becomes apparent that many
As we have
drugs.
seen, increased excretion
and abnormal,
constituents of the urine, normal
which
is
the origin of
obscure, are connected with variations in the oxidation
processes in the intercellular capillaries of the liver, caused by
corresponding
fluctuations
the
in
functional
activity
of
the
adrenals.
Glycogen and
its
Formation.
—Glycogen
obviously removes
our inquiry from the arteriole to the hepatic
organ
is
that in which
it
sight of the important fact that
the analysis, version
—
into
since this
two processes are involved in
(1) the formation of the glycogen and (2) its condextrose, and that the latter reactions must
—
occur in the vascular channels. sc
cell,
accumulates; but we must not lose
Again, the
bound up with the formation of the
first
process seems
bile that it
becomes
necessary to consider this subject simultaneously to avoid repetition.
The
sponge-like construction of the hepatic cell due to its
vacuoles, the
delicate
perilobular
room
bile-capillaries,
W. and E. H.
described by J.
canals
and Schafer, and, vacuole, or vesicle, leading through Fraser, Bro-wicz,
does
finally, its
not
own
the bile-collecting canaliculi to the
appear
to
afford
much
for protoplasm capable of undergoing functional metabo-
lism, since this
separating
all
would have to be embodied in the partitions these
cavities.
Yet,
ivere
—often duplicated, particularly almost one-third in that of the —^would represent a
nucleus
size
entire cell,
nucleoli
dent, judging
useless
which, as
otherwise,
the
and containing
structure.
by the appearance of the
fore, that the nucleus,
it
in herbivorous animals,
cell as a
we have
It
seems
evi-
whole, .there-
surrounded by a thin limiting layer of protoplasm, must impart its energy to this layer. This, in turn, being the central terminal of all seen, is
the partitions, which, along with the cell’s own pseudocovering, are protoplasmic, the vacuoles become receptacles, as it were, of the products of their walls.
Again, when we behold the minute canals so clearlj' shown Schafer’s illustration (shown on page 340) a direct communication with parts e.xternal to the cell is evident in several
m
THE ADRENAL SYSTEM AND THE DIGESTIVE ORGANS.
o48
and
it seems clear that, if his carmine gelatin could through these, so could an equally viscid substance, penetrate
places,
and with
As “no
greater ease, the blood-plasma.
still
injection
in the intercellular bile-canaliculi nor in the perivascular lym-
phatics nor between the cells” could be detected, the penetrathe gelatin can hardly be ascribed
tion of
to undue stress. “no diffusion of carmine nor any staining or nuclei by carmine,” the nucleo-mural net-work to
“There being,” of the cells
also,
must be an independent structure, circumscribthe canals and the vacuoles. The canals communicating with the exterior of the cell, they are probwhich
I
refer
ing two kinds of cavities
:
ably the receiving cavities, while the vacuoles, their neighbors, are the spaces in which the useful products of metabolism are
The
accumulated.
reached, would thus pour their excretory conand its various constituents into this cavity, and in turn, would convey them to the intercellular bile-capilvesicle is
fer’s
tents
canals themselves, -continuing until Kupf-
—
this,
laries
—
bile
through
its
own
canals.
W'hether so direct a connection between the intercellular
and the bile-channels through the cell exists is a be determined. Bile and the various bodies excreted
capillaries
point to
would be voided as are the intestinal contents, the canalicular walls taking up certain elements, while physiological substances would be mixed with the substances in transit
with
it
for definite purposes.
The
question that suggests itself
first
Is glycogen
formed
is
the following:
during the active functional activitj' of the
(during digestion) or during its passive state (between meals) ? We have seen that the production of urea is increased immediately after a meal ; we have evidence, therefore, that an liver
active
state
based
upon increased oxidation
processes
.must
and that it of which glycogen
is
during digestion that the substances out
is
formed reach the
oxidizing substance
is
prevail,
liver,
i.e.,
while the
This suggests take part in the forma-
present in the capillaries.
that the oxidizing substance
must
itself
tion of glycogen, though perhaps indirectly, and also in the elaboration of
bile.
coloring constituent of bile, bilirujjin, I have previously considered as the product of a reaction in the inter-
The main
GLYCOGEN AND
As such
cellular capillaries.
349
FORMATION.
ITS
probably eliminated with the
it. is
high oxygen constituent places it beyond the limits of further oxidation. Yet we have in another merely because
bile
component of
bile,
occurs
process
its
evidence
biliverdin,
during the passage of
some oxidizing bilirubin through the that
—
under certain circumstances, perhaps when more oxidizing substance is present, for Howell says “Biliverdin is supposed to stand to bilirubin in the relation of an oxidation cell,
—
Bilirubin
product.
is
:
given
CioHigNoOg, and
formula,
the
biliverdin, CioHigNaO^, the latter being prepared readily from pure specimens of the former by oxidation.”
With
this
evidence that oxidation does play
of the processes involved, it will facilitate
main
review the mutual relations of
my
role
task to briefly
By
biliary constituents.
made up
far the larger proportion of these is
some
of the bile acids,
—
namely: the sodium salts of cholic acid, i.e., glycocholic and These are obtained from cholic acid derived taurocholic acid. Now, Tappeiner"’" found iiself from sugars and fats (Voit). that cholic acid yielded fatty
on oxidation, and, since
acids
taurocholic and glycocholic acids are fatty acids, this suggests
that they become such during their passage through the hepatic cells
and
as the result of
The become of
various
when
clear
the intrinsic
portal vein
an oxidation process.
phases of the process in the hepatic the oxidizing substance
factors
included as one
is
The blood-plasma
involved.
cells
contributes the sugars and fats
of the
(along with the
waste-products to be excreted), ‘while the hepatic artery sup-
plasma containing the oxidizing substance.
plies
active
All
three
agents meeting in the canaliculi, a part of the sugar
(according to the proportion of oxidizing substance present)
and
all
the fat (if the proportion of oxidizing substance
abnormally reduced by suprarenal insufficiency) into
cholic
(probably
acid.
But, as the blood
collagen-cartilage,
gelatin-waste),
glycocholic
mucin,
acid
is
also
contains
connective
formed.
is
not
are oxidized glycocoll
tissue,
and
Again, since the
blood likewise contains taurin (probably muscle and pulmonarytissue waste), taurocholic acid is formed.
oxidizing substance “Tappeiner:
Just the amount of
necessary being supplied
Zeitschrlft fur Blologie,
Bd.
xll,
S.
60,
by the hepatic 1876.
THE ADRENAL SYSTEM AND THE DIGESTIVE ORGANS.
860
artery to each lobule, to properly regulate the functions involved, only the required sugar is burnt by the oxidizing substance. The rest, under the influence of the nuclei of the hepatic cells and the mural protoplasm of the latter, is converted into glycogen and collected in the adjoining alveoli.
But we must
also account for the elimination of the
waste-products that are found in
connected
with
these
fatty
acids
An
bile. is
m an y
interesting feature
that they
combine
can
synthetically with other bodies, even with proteids, while they
are simultaneously able to emulsify the
more insoluble soaps and other fatty acids and thus insure their elimination. Again, cholesterin, mainly derived from the white matter of the cerebro-spinal axis and nerves
(Flint), in which it occurs in abundance (Foster), was formerly considered as a fatty substance capable of undergoing saponiflcation, but it is now classed
among
the only alcohol that occurs in the
alcohols:
organism in a free
This body
state.
solutions of the biliary acids also, but
it is
connection
not only soluble in comhines with acids,
The importance
including glycocholic acid.
when
is it
of this fact appears
recalled that insufficiency of glycocholic acid in this
—and
main source
perhaps, of oxidizing substance
also,
The
of gall-stones.
constituent of bile,
present to take
it
when
up,
there
it is
is
—
is
the
cholesterin being a constant
not enough glycocholic acid
precipitated in the gall-bladder and
calculi of which it is the main component.Another body derived from nervous structures, but which, like cholesterin, is to be found in other fluids, especially bloodserum, is lecithin. This body, besides others not mentioned,
there forms the
only occurs, however, in very limited proportions. It
is
now
evident that glycocholic acid
acid should be looked
that
the}'^
upon
as functional
and taurocholic
acids, in tbe
sense
are not only vehicles for waste-products ‘of metabo-
lism, but are also capable of submitting
them
to
dissociating
reactions under the influence of the oxidizing substance.
They
are sources of energy precisely as myosinogen appears to be a
source of energ}% and capable of becoming factors of combustion
They to
phenomena when
in
contact
with
the latter substance.
are also truly physiological in the sense that they serve
recover or economize those
products which can
again be
GLYCOGEN AND
ITS
o51
FORMATION.
used by the organism. Indeed, they (or at least a part of their decomposition products) are again absorbed by the intestinal mucous membrane, and, passing through the venous channels, probably take up therein and transfer to the hepatic cells what waste-matter they are to carry to the intestinal tract.
We
thus have in the cellular canaliculi two acids endowed with powerful affinities and an active reagent, the oxidizing substance, to account for the processes of a chemical nature connected with the functions of the hepatic
Of
cell.
course, all this involves the necessity of showing, as a
controlling factor, that products of combustion are also present.
following lines by Professor Howell give this feature
The
“The secretion condue emphasis ; referring to bile, he says quantity variable, considerable, though tains also a of CO2 ga^, held in such loose combination that it can be extracted with a :
gas-pump without the addition of acid. The presence of this constituent serves as an indication of the extensive metabolic changes occurring in the liver-cells.”
Again, the element of nervous control implied when T referred to the oxidizing substance contributed artery
We
must be shown.
active nerve during functional activity of the
should likewise govern hepatic functions is
the case
Bernard, to his
greatest
almost
He
all
is
by the, hepatic
have seen that the vagus was the is
stomach; that
obvious.
it
That such
sustained by no less an authority than Claude
whom we owe achievements
sustained by
the discovery of glycogen
—and
all
—one
of
whose conceptions have been
the labor bestowed
upon them
since.
not only found that the vagus was the predominating nerve
in the liver, but that its section also suppressed its glycogenic
function.
The of
fate of glycogen, its conversion into sugar for the use
muscular and other
tissues,
may now
be
analyzed
with
greater facility.
My analysis of muscular functions led me to the deduction that the contractile elements contained a substance, myosinowhen brought into contact with the oxidizing substance of the plasma, became the source of the muscle’s work-
gen, which,
Ample evidence was afforded to show that we were dealing with an oxidation process, the intensity of which ing energy.
THE ADRENAL SYSTEM AND THE DIGESTIVE ORGANS.
352
was commensurate with the amount of blood that the arterioles suiiplied to the contractile tubular elements. There seems to be considerable analogy between tliis process and that which prevails in the hepatic lobule. Howell alludes to this in the following Avords, which well recall the fact that we referred to glycogen as the main constituent of myosinogen “The history :
of glycogen
not complete without some reference to its occurrence in the muscles. Glycogen is, in fact, found in various places in the body, and is widely distributed throughout the animal kingdom. It occurs, for example, in leucocytes, in the is
placenta, in the rapidly-growing tissues of the embrj-o, and in
considerable abundance in the oyster and other mollusks. in our bodies
But and in those of the mammals generally the most
significant occurrence of glycogen, outside the liver,
is
in the
voluntary muscles, of which glycogen forms a normal constituent.”
The energ}'
is
similarity between muscular
and hepatic sources of
further emphasized when, in the following paragraph,
Howell says: “In accordance with the view given above of the
—namely:
general' value of glycogen
that
is
it
a temporary
may
reserve-supply of carbohydrate material that
be rapidly
converted into sugar and oxidized,^^ with the liberation of en-
—
ergy
it is
found that the supply of glycogen
is
greatly affected
by conditions calling for increased metabolism in the body, kluscular exercise will quickly exliaust the supply of muscle and liver glycogen provided it is
not renewed
bj^
new
food.
In a
starving animal glycogen will finally disappear, except perhaps in traces; but this disappearance wilt occur much sooner if the animal
is
made
has been shown also has been
made
more sugar
to
to use its muscles at the
by Morat and Dufourt
contract vigorously,
"from an artificial
it
same time.
that, if a
will
take
It
muscle
up much
supply of blood sent through
it
than a similar muscle which has been resting; on the other hand, it has been found that, if the nerve of one leg is cut so as to paralyze the muscles of that side of the body, the
amount
of glycogen will increase rapidly in these muscles as compared
“ The
Italics are
our own.
GLYCOGEN AND with those of
tlie
353
FORMATION.
ITS
other leg, that have been contracting
mean-
time and using up their glycogen.^’
These facts clearly indicate that oxidation processes are not in order here, since glycogen
is
a source of energy, intended,
therefore, for subsequent oxidation wherever
it
is
distributed.
“It was
Indeed, Professor. Foster remarks, in this connection:
formerly believed that this sugar underwent an immediate and
...
It was circulating in the blood. is sufficient for us at the present to admit that the sugar is made use of in some way or other.” Peferring to the physiodirect oxidation as
it
logical uses of glycogen,
he also says:
“The main purpose
of
the deposition of glycogen is to afford a store, either general or local, of carbohydrate material, which can be packed
without
much
trouble so long as
it
away
remains glycogen, but which
can be drawn upon as a source of soluble circulating sugar
whenever the needs of
this or that tissue
demand
it.”
That
the oxidizing substance has nothing to do with the process
is
clear.
The conversion as
of glycogen into sugar in the liver appears
a wasted function, the carbohydrates having been
split into dextrose or
Why
tem.
already
dextrose and levulose in the portal sys-
they do not merely pass on to the several tissues
But it soon becomes evident that, were it sugar would accumulate, then be excreted by the kidneys, and lost, since there can only be a fixed and limited seems
strange.
otherwise,
(0.1 or 0.2 per cent.)
given time.
So useful
amount
of sugar in the circulation at a
a substance
is,
therefore, stored, after
dehydration, in the hepatic cell as glycogen, and converted into sugar according to the needs of the organism.
Conversion of the liver glycogen into dextrose is generally ascribed to a special ferment, thought to originate in the liver, but the nature of which has remained undetennined.
The
experiment of Claude Bernard, upon which this view based,
is
mainly
the following, as related by Stewart “A rabbit, after a large carbohydrate meal of carrots, for instance is killed is
:
—
and
—
rapidly excised, cut into small pieces, and thrown into acidulated boiling water. After being boiled for a few minutes the. pieces of liver are ruhbed up in a mortar and again boiled in the same water. The opalescent aqueous extract its liver
is
—
THE ADRENAL SYSTEM AND THE DIGESTIVE ORGANS.
Oo4 filtered
traces
—
from the coagulated proteids. No sugar, or only of it, is found in the extract, but another carbohydrate off
an isomer of starch, giving a port-wine color with
^glycogen,
iodine and capable of ready conversion into sugar by amylolytie
ferments
—
present in large amount.
is
Again, the
liver, after
the death of the animal, is
is left for a time in situ, or, if excised, kept at a temperature of 30° to 40° C. or for a longer period
at a lower temperature;
it
then treated exactly as before,
is
but no glycogen, or comparatively
from
it,
although sugar
ence plainly
is
little,
(dextrose)
is
now
can
The
abundant.
that after death the hepatic glycogen
verted into dextrose by some influence which
destroyed by boiling.
This influence
formed ferment or to the unformed ferments and at the
be obtained
may
inferis
con-
restrained or
is
be due to an un-
direct action of the liver-cells, for both
living
tissue-elements
destroyed
are
temperature of boiling water.”
Another explanation suggests
itself to
me
if,
instead of a
ferment of hepatic origin, we hypothetically use one of ex-
In the
ternal origin:
first
procedure immediate immersion in
boiling water destroyed the ferment which happened to be in
the blood-vessels, while, in the “second, the ferment was given
time to
act.
The
difference in the conclusions vouchsafed
is
no thought being given to the blood-vessels, the ferment could only be considered as of cellular origin. We simply this:
have seen how really
many
functions ascribed to the hepatic
cells
belonged to the intercellular blood-stream; this seems
an additional one. Admitting that we are dealing with a ferment of external origin, from which organ could we expect it to be derived? Can we attribute the process to ferments from the salivaiy
to be
glands or pancreas?
If it
is
produced only by digestive
fer-
amylolytie ferments poured out during digestion,
ments,
i.e.,
—why
does
glycosuria
process
when
the floor of the fourth ventricle
appear
irrespective
of is
any
digestive
punctured, as
shown by Claude Bernard ? He also found that conversion of glycogen into sugar was a continuous process, carried on to subserve the needs of the organism clusion
if
the liver
is
:
a perfectly logical con-
really a storehouse for this substance.
Again, the quantity of sugar in the blood, as
ive
have seen.
—
—
GLYCOGEN AND is
How
small, but constant.
ITS
:
355
FORMATION.
could
we account
for these feat-
ures of the problem with ferments transmitted digestive tract
thiough the
?
Finally, sugars thus produced
i.e.,
from amylolytic ferdo not seem to be
—
ments secreted by the digestive tract dextrose, the sugar produced by the supposed hepatic ferment. Thus, Professor Foster says: “In the case of the amylolytic saliva,
deed, of
other amylolytic animal
all
starch or glj'cogen
converted
is
is
fluids, the
dextrose.”
It is
is
and that
it
the intestinal
the sugar
dextrose, identical,
can at present be made out, with ordinary evident that a ferment other than the amy-
lopsin connected with the digestive process one,
sugar into which
Now,
maltose.
which appears in the liver after death as far at least as
and, in-
pancreatic juice, inte?:tinal juice,
ferment of
must reach the
tract,
the
liver etc.
villi,
must be the
active
by a channel other than Again,
it
must be very
nearly similar to the salivary and pancreatic amylolytic fer-
ments.
The
salivary glands are so remote anatomically that
they can hardly he considered;
we
are brought, therefore, to
the pancreas as the only organ which could act as source of a
ferment or diastase having for
its
main function
to
convert
glycogen into dextrin.
As shown by von Mehring, Minkowski, and de Dominicis, removal of the pancreas causes marked glycosuria, and this persists
whether the animal be given carbohydrates or not.
All the other
symptoms
of diabetes mellitus appear,
—namely
increased flow of urine, considerable urea, acetone, etc.
;
great
and hunger, emaciation, marked muscular weakness, followed by death in two to four weeks. Indeed, we are vividly reminded of the suprarenal glands, on ascertaining that graftthirst
ing of a piece of pancreas in the abdomen or sldn will arrest the glycosuria, and that, if a small portion of the organ is left, the
symptoms
will
are given as food
Again, whether carbohydrates
disappear.
or not, the glycogen
disappears from the from these experiments,” saj^s Howell, “that the pancreas produces a substance of some kind that is given off to the blood or lymph, and is either necessary for the normal consumption of sugar in the body or else, as is
liver.
“We may
believe,
held by some, normally restrains the output of sugar from the 23
—
THE ADRENAL SYSTEM AND THE DIGESTIVE ORGANS.
356
and other
liver
sugar-iirodiicing
satisfactorily.”
tion
is
tissues
What
the body.
of
and how it acts has not yet been determined That we are dealing with an internal secre-
this material is
clear, and,
such being the
case, the secretion
probably
passes out into the blood by the pancreatic vein, which “opens into the splenic
and mesenteric
veins.”
As
these open, in turn,
in the portal vein, the pancreas would then supply a special ferment for the conversion of glycogen into a functional sugar.
If the foregoing sjTnptoms are closely scrutinized, becomes apparent that the functions of the pancreas
it
—
be shown in the next chapter
For the
generally believed.
soon
as will
—are far more important than
present, however,
we
is
will limit our
inquiry to the subject in point.
The
fact
notwithstanding the ingestion of carbo-
that,
hydrates, the glycogen will totally disappear from the liver easily accounted for.
A
prominent fimction of the pancreas
during intestinal digestion
is
to transform starches into malt-
to insure absorption of this sugar.
ose,
removed, therefore, intestinal
its
contents,
amylopsin
starches
is
When
the organ
no longer furnished
are not properly converted,
production of glycogen, therefore, ceases.
we can
that
so easily account for this
is
to the
the portal vein carries no maltose to the hepatic lobule.
that
is
and
The
The fact, however, phenomenon suggests
:
is the organ upon which all the preliminary with the formation of glycogen depend. connected functions
1.
The pancreas
2. Its amrjlopsin converts starches in the intestine to pre-
pare them for the elaboration of glycogen in the hepatic cell. 3. Its internal secretion, supplied to the portal system hy
way
of the splenic vein, converts glycogen into dextrose. That we are on the right path is suggested by a series of
experiments by Croftan,”^ in which the conversion of glyc-
ogen into sugar was obtained by means of injections of supra“Incomplete as these experiments are,” says renal extract: the author, “they reveal the fact that the injection of suprarenal extract can cause the excretion of dextrose provided the
quantity injected
w
Croftan:
is sufficiently
American Medicine, Jan.
large.
18, 1902
Why
in the case of
one
GLYCOGEN AND
357
FORMATION.
ITS
animal more must be given than in the case of another to produce approximately the same excretion is undecided and remains to be determined.” Dwelling upon the presence in the adrenals of a diastatic ferment, he states that “two possibilities
may
present themselves, viz.
:
the
either
suprarenals
manu-
facture a diastatic ferment or they retain the diastatic ferment that is formed elsewhere in the body (pancreas, salivary glands)
when it is The author
in the blood- or lymjih- stream.”
them
carried to
also refers to the investigations of F.
Blum,°® who,
“testing the effects of suprarenal extract empirically,” discov-
ered “glycosuria in 22 out of 25 animals that he operated on.”
My
manner
interpretation of the
reached their results
is,
in which these investigators
of course, not that of Croftan, since,
as I view the process, the oxidizing substance constitutes the
compound
active suprarenal agency as a
of suprarenal secretion
and oxygen.
We where.
are dealing with enhanced physiological activity some-
Indeed, Croftan says:
“In order that hyperglycosuria
amount of sugar normally poured into the blood must be increased, or the amount nonnally destroyed must be decreased.” That excessive activity was either probe produced the
cured by the injected
by overstimulation of the insufficiency, is shown by the
extract or
adrenals, both leading to total
brief history of one of the animals
:
“The second
rabbit died
in one hour and ten minutes; here some spasmodic symptoms,
involving chiefly the posterior extremities, preceded the coma.”
Eeferring to two rabbits, including the latter, the
first
having
died in two hours and forty minutes and to “all others to be
spoken of presently”
(six,
all
told), he says;
“Dextrose was
by its cupric-reducing powers and the phenylhydrazin test; in one of the dogs in addition by circum-
identified in the urine
and yeast fermentation. The substance excreted was undoubtedly dextrose. The amount excreted would be far polarization
too large to be explainalile by a
substance mentioned sible for
above
;
it
splitting of the jecorin-like
would
not,
moreover, be pos-
consideralile f|uantities of dextrose derived
from
this
source to appear in the urine for several days after the injec-
,
“F. Blum:
Deutsche Archiv
f.
hlin. Med., Oct. 31, 1901.
;
THE ADRENAL SYSTEM AND THE DIGESTIVE ORGANS.
358 lion.”
Excessive stiiniilaiion hy a great increase of oxidizing the blood evidently occurred. As soon as the
substance in
extract was injected
individuality
it was carried to the lungs, and lost immediately therein by taking up oxygen.
its
It
could no longer, therefore, act as a diastase.
The
cjuestion
now
to decide is this
General stimulation
;
enhanced the production of an amylolytic ferment either by To which organ can we ascribe
the liver or by the pancreas. this function?
Since oxidation destroys sugar, a great excess
would burn sugar actively and produce the opposite of glycosuria i.e., excessive combustion and rapid disappearance of the liver glycogen through abnormal use of it in the other organs. But of oxidizing substance in the blood
on
all
here
sides
we
stance
:
have, as a result of a great increase of oxidizing
the
in
marked
blood,
without preliminary feeding, since this
As the oxidizing substance does not
by Croftan.
suli-
and that evidently fact is not mentioned
glycosuria,
cogen, that of the liver could not be converted by
it
affect gly-
into sugar
hence the excessive production of the latter can only be
ac-
counted for by an equally excessive j^roduetion of amylolytic ferment.
Claude Bernard showed that conversion of glj'cogen into sugar took place more rapidly when the blood was made to
Yet he attributed the it from pulp rubbed up and treated with glycerin, after the liver had been washed out so as to remove the vascular contents. But it traverse the liver with unusual speed.
formation of the ferment to the
liver,
having obtained
seems clear that injections by the portal vein will hardly deplete the liver of every particle of the ferment in its minute lobular pulp and a three
capillaries, while reduction of its substance to
days’ immersion in glycerin will dissolve
the latter.
When we
—even by — evident that
produced, Seegen,
consider
traces
it
is
of
how
all
that contained in
readily conversion can be
soluble
albumin,
upon the addition
glycerin solution the very small proportion that
mained imprisoned
in
some of the lobules
according to
of water to the
may
have
re-
will suffice for the
conversion of glycogen.
One
of Claude Bernard’s experiments seems to
me
to afford
proof that the amylolytic ferment reaches the liver through
—
—
FUNCTIONS OF THE LIVER, SPLEEN AND PANCREAS.
o59
he created a collateral circulation, and shifted the portal-blood stream into Ten or 12 grammes of sugar were the general circulation. then given to the animal, and sugar was soon found in the the portal vein.
By
ligating
tlie
vessel
latter
In a normal dog, on the other hand, 50 to 80 grammes had to be administered before this result was obtained (M. DuvaP®). The absence of sugar in the latter animal’s urine until a very large quantity of sugar had been ingested distinctly show's that conversion of its glycogen only occurred
uriue.
because
its
portal vein
was open; in the other dog urine,
converted gl3"cogen that passed into the intestinal starch
i.e.,
it
was not
but maltose,
which had been submitted to the action
of the pancreas’s intestinal ferment,
i.e.,
amylopsin.
we
If
now
couple the fact that conversion of liver-glycogen only oc-
curs
when
the portal vein
Claude Bernard’s ob-
free with
is
servation that increased speed of the portal blood through the liver causes the glycogen to
be converted more rapidly,
clear that the conversion process is not
ment, and that the pancreas
due
s^ipplies, as
to
it seems an hepatic fer-
an internal
secretion,
the ferment which converts glycogen into dextrose.
A ever.
perplexing feature of If,
as
we have
oxidizing substance,
why
all this
stated, is
of
Jaquet,
requires elucidation, how-
Armand Gautier”
which
an
blood-plasma contains
the sugar not oxidized on its
to the tissues of distribution?
investigations
the
demonstrated
way
refers to the
that
sugars
mixed with blood containing the oxidation ferment previously referred to, and which we found to be of suprarenal origin, did not become oxidized. He ascertained, however, that upon adding to the blood a small quantity of fine pulp of muscle, lung, or of any other organ, the oxygen
was absorbed.
This
obviously indicates that dextrose passes through the hlood with-
and it can only become oxidized after combining ivith bodies produced by the organs to which it is dis-
out being destroyed,
tributed.
—
General Functions of the Liver, Spleen, and Pancreas All the facts reviewed in this chapter suggest the following conclu.
sions as to the functions of the liver, spleen,
“ M. Duval: Loc, cit., p. 378. Armand Gautier: “La Chimle
de la Cellule Vivante,”
and pancreas
p. 98.
:
THE ADRENAL SYSTEM AND THE DIGESTIVE ORGANS.
3()0
1.
The hepatic
(adrenoxidase) that tribution
of
its
owing
artery,
to
oxidizing substance
the
plasma contains and the mode of
its
terminal
capillaries,
supplies
chemical energy which initiates and sustains hepatic lobule that require oxygen. 2.
The nervous supply
of the liver
is
dis-
exogenous
the
all reactions in the
composed,
first,
of
terminal subdivisions of the vagus, which enhance the activity of all its functions by causing dilation of the hepatic arterioles; and, second, of terminal subdivisions of the sympathetic,
which, by causing constriction of these arterioles, reduce the functional activity of the organ.
In the normal subject the liver from structures that come into contact 3.
is
anatomically isolated
luith bacteria,
and pro-
tected against their intrusion by the bactericidal products of the intestinal glands If.
The
mixture
and
follicles.
capillaries of the hepatic lobules,
therein
of
the
hepatic
artery’s
owing
to the
ad-
substance
oxidizing
(adrenoxidase) with the portal vein’s ivaste-ladcn blood, are the seat of several functions
now
ascribed to the hepatic
cell.
Blood-pigments and iron, derived from the intestine and spleen, simidtaneously penetrate the hepatic lobule, and com5.
bine with the adrenoxidase therein to form hccmoglobin.
v.ncombined pigment
is
The
eliminated with the bile as bilirubin.
end-product of three successive reactions, 6. viz., (1) nitrogenous bodies are reduced to amides in the afferent mesenteric and portal; (2) the amides are dissociated veins, into ammonia, carbonic acid, and water by the oxidizing sub-
Urea
is
the
—
stance (adrenoxidase) in the hepatic lobule; (3) urea
by synthesis in the efferent veins,
—
hepatic,
and vena
is
formed
cava.
The hepatic cell contains, besides its vacuoles and nuclei, numerous canaliculi (Schafer) and a vesicular vacuole which 7.
the opens into the hile-capinaries by a canaliculus (Kupffer); connected. canaliculi and the vesicular vacuole are probably 8.
and taurocholic acid arc functional acids, and, they dissociate and appropriate waste-products,
Glycocholic acid
inasmuch as into under the influence of the oxidizing substance, convert them
cells. excrementiiious products in the canaliculi of the hepatic and acids biliary the by 9. The waste-products so converted along themselves, constituting bile, arc transferred,
the latter
—
FUNCTIONS OF THE LIVER, SPLEEN AND PANCREAS. ivith other
products for which the latter
hilirubin, earthy salts, etc.,
—
may
361
serve as vehicle ,
to the vesicular vacuole of the cell
and eliminated by the canaliculus that opens into the
bile-
capillaries.
10.
The
biliary acids^, blood-pigments, iron,
or any of their components, that
may
ganism
are,
venules
and returned to the portal The sugars converted from
11.
entirely
and other bodies
prove useful to the or-
or in part, reabsorbed by the intestinal circulation.
intestinal foodstuffs in the
intestines are brought to the hepatic lobule with the portal blood,
and penetrate the dizing substance.
and with the oxiDuring the bile-forming reaction the sugars canaliculi with the latter
are dehydrated, and, probably with the assistance of the cellular
protoplasm, converted into glycogen. 12.
The
liver
glycogen
is
converted into dextrose by an
ferment supplied by the pancreas as an internal which enters the portal circulation by the splenic vein. 13. Dextrose is distributed to the organs in which it is
arnylolytic secretion,
used as a source of energy by the blood, and only becomes vulnerable to oxidation
when combined with products
lism furnished by those organs.
of metabo-
—
CHAPTEE
VIII.
THE INTERNAL SECRETIONS OF THE PANCREAS AND SPLEEN. Glycosuria and Overactivity of the Adrenal System. pancreas and spleen are considered together because
—The there
is
considerable evidence in favor of the view that they
are functionally associated; this question
and
and
it
is
to give the analysis of
relationship with the ferments furnished
its
by the pancreas to the portal blood due prominence that we
f:
V •
have, under other headings, considered the better-known functions of both organs.
To
sustain our belief that liver glycogen
dextrose by an
is
converted into
amylolytic ferment supplied by the pancreas
which penetrates the portal vein directly, i.e., by way of the splenic vein, we were fortunate in having at our disposal the experiments of Croftan, which showed that suprarenal over-
—
activity could so
augment the functional
activity of the fer-
i |
ment-producing organ as to induce a very great increase in
{
This feature requires further study,
t
will tend to elucidate other functions of the pancreas.
t
sugar eliminated.
the since
it
We
believe that
we
have conclusively
shown that
certain |
drugs and poisons increase the functional activity of the ad-
The uniformity
renal s.
of the
phenomena
traceable to these ^
glands under the influence of such agents seems to us to warrant the conclusion that,
if
we can demonstrate
t
that glycosuria
^
is j
also
subject to the latter,
its
fluctuations following those of
induced by them, a suprarenal overand direct connection between A^et we must bear in mind, in activity will have been shown. this connection, that all active drugs may have a primary the
suprarenal
activity
or
insufficiency
glycosuria
action upon tissues for which they possess a specific affinity before the suprarenal protective functions are fully awakened.
We
have seen that even
nic
is
wall
electrieal
stimulation of the splanch-
only followed by vermicular motions of the intestinal some time elapsed. But too much weight must
after (
362 )
363
GLYCOSURIA AND ADRENAL OVERACTIVITY.
not be given this feature, inasmuch as I have personally seen the typical symptoms of total suprarenal insufficiency occur
dog within twenty seconds after a fatal dose of hydrocyanide of potassium had been administered. Large quantities in a
of the less active drugs
which
for
potassium,
they
are
more
a
special
possess instance,
for
likely to
bromide
predilection,
such
than
reach the tissues
an
agent
While, therefore, .we cannot say that ex-
viously mentioned.
formation of sugar, when drugs are given,
cessive
pre-
that
as
of
is
due only
to overstimulation of the adrenals, we- can say that all drugs
can produce it when they stimulate suprarenal activity. Furthermore, if seems probable that some drugs not only do this, but they likewise, owing to their affinity for certain tissues, enhance the production of sugar by increasing the functional activity of the intimate structures of the organs concerned in its
—
production from ingested substances
different
organs
of
sets
stimulating two Such an agent we
^thus
simultaneously.
probably have in phloridzin.
In an able and exhaustive review of the subject of toxic glycosuria, F. Cartier,^ of Paris, says
phloridzin
is
...
true intoxication.
In
on glycosuria, and maintain to
it
man
“The symptomatology
:
very limited, seeing that
it
it is
even possible to bring
a long time, without giving rise
general disorders, provided a copious
We
sured.”
of
does not give rise to a
alimentation
is
in-
have evidence in the last sentence that the main
an excessive formation of sugar, and, more carbohydrates being required, it is to an excessive production
general result
is
we
of the converting agent that Still,
if
general
symptoms
suprarenal overactivity?
he says
“Yet
:
all
.must ascribe this phenomenon.
are absent,
authors
who have
if
tion
is
not overfed, rapidly wastes. insufficient,
grave
of
the
when
studied phloridzin unite
in saying that the animal experimented
and,
what becomes
Cartier answers this question
upon becomes
...
When
phenomena appear.
voracious,
alimenta-
Phloridzinic
glycosuria has been obtained in animals entirely deprived of
hydrocarbons; analogous
*
under
these
to those of diabetic
F. Cartier:
Th6se de Paris,
1891,
circumstances
general
s}'mptoms
coma have been observed.”
J INTERNAL SECRETIONS OE PANCREAS AND SPLEEN.
o()4
Osier-
states
that
Frerichs
recognized
three
groups
of
two of these are of special interest to us: (a) Those in which after exertion the patients were suddenly attacked with weakness, syncope, somnolence, and gradually deepencases;
ing unconsciousness, Cases
with
death
preliminary
occurring
gastric
few hours,
a
in.
disturbance,
such
as
(b)
nausea
and vomiting, or some local affection, as pharyngitis, phlegmon, or a pulmonary complication. In such cases the attack begins with headache, delirium, great distress, and dyspnoea, affecting both inspiration and expiration: a condition called by Kusamaul air-h unger. Cyanosis may or may not be present. If
it
is,
the pulse becomes rapid and weak and the patient
gradually sinks into coma, the attack lasting from one to
The need
days.
viously points
to
of
a
supply
copious
increased
of
carbohydrates
Indeed,
oxidation.
ob-
complete ab-
sence of glycogen in the liver and muscles has been
The
five
noted.
voracious appetite and rapid wasting further sustain this
—and
simultaneously,
therefore,
tlie
presence
of
suprarenal
The italicized words in the list of terminal symptoms, on the other hand, as prominently point to the gradually deepening suprarenal exhaustion. Alluding to the effects of acids in the production of overactivity.
the experiments
of Pavy® with was noted in twenty .minutes; fifteen minutes later a large quantity was present. In another strong, but fasting, dog the sugar was markedly Ilasmorrhagic infiltration of the reduced by a smaller dose. gastric and intestinal tissues and hivmaturia were also noted. These are all familiar landmarks of suprarenal origin. Strik-
glycosuria,
Cartier
phosphoric acid.
ing,
refers
An
to
increase of sugar
in this connection, arc the observations of
who found
that the production of
CO„ decreased
Stadelmann,^ in the rabbit
during acid intoxications as it does in diabetic coma. In a “Voit and Pettenkofer and Gaethgens
foot-note Cartier says:
have peremptorily shown, by means of most precise experiments, that (1) the oxygen absorbed by a diabetic is much less than by a normal man, and that
it
decreases progressively until
“Practice of Medicine,” third edition.
“
Osier:
’
Pavy: Guy's Hospital Reports, vol. of 1861. Stadelmann: Deutsche med. Wochenschrift, Nov.
*
4,
1890.
—
366
GLYCOSURIA AND ADRENAL OVBRACTIVITY. the end of the disease,
when
hardly equal to half of the exhaled is likewise reduced.”
it is
normal quantity; (3) that the CO 2 That this is essentially due to suprarenal insufficiency i.e., reduced oxidation is shown by the fact that, in a case of coma due to meningitis witnessed by Stadelmann, the proportion of
—
was 28.3 per cent.; while in diabetic coma the gradual decline is that observed in Minkowski’s rabbits, which, from the
CO 2
dropped to 16, 8.8, then 3.9 per cent. have seen that tetanus was partly due to adrenal overCartier refers to the experiments of Claude Bernard,
normal 25 per
We activity.
cent., steadily
which showed that strychnine produced glycosuria in dogs. “It is unnecessary to reproduce here,” says Cartier, “the symp.
toms of poisoning produced by say that nothing recalls tetanus intoxication by it.”
We
this alkaloid;
we
will simply
such a high degree as does
to
have another proof that
is
it
due to
an excessive production of a ferment or some other agency possessed of converting powers since Langendorll found that
“glycosuria only occurs in frogs
...
cogen.
when
the liver contains gly-
In the summer, when their
liver contains none,
strychnine does not cause diabetes in these animals.”
We are reminded of the disorganization of haemoglobin produced by advanced suprarenal insufficieney when, referring to
curare glycosuria, Cartier says
:
“Others account for this
glycosuria by an insufficiency of the respiration and by slowing of combustions. cates
The dark coloration of curarized blood Even tlie nervous distribution,
asphyxia.”
this
indi-
as
I
including the basospinal conneetion between the body and the adrenals, finds itself sustained in a
interpret
it,
pituitary
remarkable manner by the following lines of Cartier’s in referenee fact
to
that
morphine glycosuria: all
these
investigations
“An
extremely
indicate
interesting
one can produce with a toxic substance exactly similar phenomena to those recorded by Claude Bernard in his lessons at the College is
that
of France,
and obtained by puncture of the medulla, and that in most cases be arrested, as are glycosurias of nervous origin, by severing the centrifugal nervethese toxic glycosurias can
impulse
conductors.
Indeed, section of the pneumogastric does not prevent glycosuria caused either by Bernard s puncture or by morphine but, on the contrary. ; (centripetal nerve)
INTERNAL SECRETIONS OF PANCREAS AND SPLEEN.
366
section of the splanchnic nerves (centrifugal nerves)
and
of the
medulla above the origin of these nerves prevents both the experimental diabetes of Claude Bernard and the toxic diabetes caused by morjdiine.”
The
of drugs that are able to produce glycosuria could
list
be indefinitely prolonged:
suprarenal overactivity.
includes all those that produce
it
But
this does not
mean
that the fer-
ment-producing organ is alone stimulated; glycosuria is but one of the manifestations of the exaggerated general metabolism
induced,
and oxidation processes are enhanced accord-
Toxic glycosuria, therefore,
ingly.
the
repre.sents
onl}'
sur-
plus of sugar which oxidation processes have not consumed; excess of sugar actually produced
tlie
is
proliably far greater
which the urine shows. Again, certain drugs phosphorus, for instance do not produce glycosuria to any
tlian the surplus
—
—
marked degree;
as soon as the dose capable of causing
reached, the adrenals lapse into insufficiency, and,
it
is
the dose
if
pushed to any extent, even tlie normal ratio is reduced. Antipyrin is now considerably employed in diabetes; we have seen that this drug and acetanilid readily produced suprarenal is
and
insufficiency
This
dissociation
sufficiently
is
methaemoglobinuria
seem
facts
due
to
me
of
the
luemoglobin
extensive sometimes to or
molecule.
manifest
even ha'inatoporphyrinuria.
to indicate that toxic glycosuria
itself
as
All these is
primarily
to overstimulation of the adrenal system, the excessive func-
tional activity ivhich increased oxidation produces giving rise to
an inordinate production of an agency that converts glycogen All these features will again be reviewed.
into sugar.
That the agency which converts glycogen
into
sugar
is
the amylolytic ferment produced by the pancreas to which I
have referred cially
is
further sustained by the foregoing facts, espe-
in view of the
secretion
in
the
amylolytic properties of the pancreatic
intestine.
Since the conversion
into
sugar
occurs during fasting as well as during digestion under the effects
of
toxics,
the
reaction
can
only
include
the
hepatic
glycogen and pancreatic ferment; and, there being nothing in the intestine to convert during fasting, the ferment must necessarily reach the glycogen
he the
more
by another channel,
d/ay this not
direct route afforded hy the splenic vein?
367
RELATIONSHIP BETWEEN SPLEEN AND PANCREAS.
Yet there is a possibility that the flow of amylopsin in the intestine, which the enhanced activity of the pancreas must undoubtedly increase, may he reabsorbed by the venules, and, being carried into the portal system, produce conversion of the glycogen precisely as if it had entered the portal vein by the
way
But we have seen
of the splenic vein.
of the pancreas
is
tions of the gland can be safely removed.
while removal
Admitting that the the pan-
may have left the portions related with duct, how could we account for the effects
operators creatic
that,-
rapidly followed by death, very large por-
of trans-
planted fragments in arresting the glycosuria caused by re-
moval of the pancreas, recorded by Minkowski® and Hedon?" As long as fragments transplanted subcutaneously remained normal no glycosuria occurred; it reappeared, however, when these fragments tJiat
became histologically impaired.
could be the blood. trated the liver by
Thus way of
intercellular capillaries
penetrated the organ by
was evidently
to
convert
the
amount
the normal blood,
of
of
previously shown.
as
liver, it
glycogen
Croftan’s animals
Again, we have is
maltose, while
when stimulated with
renal extract gave dextrose in very great quantities:
denoting successive processes.
duced appear to
then pene-
up the very limited proportion of sugar found
seen that the product of intestinal reduction the urine
it
ferment could thus reach the
sufficient
required to build
carried to the heart,
the hepatic artery, and reached the
and the glycogen precisely as if it had way of the portal vein. Although but
a small quantity of the
in
It is evident
the only channel here for the amjdolytic ferment produced
me
to
supra-
a feature
This and the other facts ad-
contribute additional evidence to
my
view that the dextrose-forming ferment enters the portal system
hy
way
of the splenic vein.
THE FUNCTIOXAL RELATIONSHIP BETWEEN THE PANCREAS
AND SPLEEN. The
internal
secretion of the pancreas and that of the perhaps be best studied by submitting to a careful analysis the hypothesis advanced b}^ Schiff, sustained by
spleen
may
Iledon.
Congr. far Inn. Medicin, Wiesbaden. Archives do Physiologic norm, et path., vol. iv, 1900.
1892.
INTERNAL SECRETIONS OF PANCREAS AND SPLEEN.
3fi8
Ilerzon/ and defended by Lepine’* and others that the spleen supplies a ferment which, when added to pancreatie juice, greatly increases
its digestive energy. JSchilf believed that the splenic snhstance played an important part in the genesis of the pancreatic proteolytic ferment, but Herzen attributed to
function
the
it
converting trypsinogen
of
albumin-solving
constituent
of
the
into
pancreatic
trypsin, juice.
the
This
subject was
more recently studied e.xperimentally by Gachet and Pachon,® who were led to conclude, as previously suggested by Laguesse (1893) and Schiifer (1895), that the spleen furnishes
true
a
internal
affinity for the pancreas,
secretion
udiich
into trypsin, as suggested by Herzen.
properties at the boiling-point; solution,
by alcohol
;
and
possesses
the protrypsin of which
is,
is
it
a
This substance
precipitated,
when
special
transfonns loses its
in aqueous
therefore, of the nature of a fer-
ment.
Lepine
also
confirmed Schifi’s and Herzen’s view by ex-
He found that a mixture of pancreas and spleen-pulp in glycerin possessed far periments in vitro and by blood-analyses.
more
On
active properties than pancreas alone similarly prepared.
the other hand, the blood of an animal deprived of
its
spleen proved almost inert as a tryptic, while the blood of a
normal dog possessed
digestive
distinct
Analysis of
powers.
experiments of these various authors distinctly indicates
the
that
some function
tomical
relations
The anahowever, make it
of the kind mentioned exists.
of the
organs
involved,
impossible for the internal secretion referred to to jienetrate the circulation without
first
passing through the liver with
the blood of the splenic vein, which collects the jjancreatic inter-
nal secretion
suggest
to
and that,
carries it to the portal vein.
besides
the
amylolytic
This fact seems
ferment,
the
portal
carries a ferment to the liver calculated to insure the trvjitic If we consider that action u])on albumins and kindred bodies.
we have
in
of digestion
tbe blood of tbe portal channels
and that trypsin
is
“ajiplied
all
the products
solely to
albuminoid
Revue G6n6rale dcs Sciences pures et appl., vol., 1S95. Lupine: Soci6t6 des Sciences Medicates dc Lyon, July, 1895. ‘'Gachet and Pachon: Archives de Physiologic, April, 1898. *
®
Herzen:
SHO
RELATIONSHIP BETWEEN SPLEEN AND PANCREAS. conversions
cliangos’’
iiml
(Charles),
the
importance
the
of
spleen’s internal secretion will appear.
Albuminoids, especially those ingested with food, are not the inoffensive bodies that they appear to be; indeed, they constitute the foundation of some of the most dangerous sub-
when
stances that enter the organism
undergoes certain
changes.
their molecular structure
Apart from any function of the
spleen in the direction mentioned, the pancreatic trypsin sup-
we can judge by
plied to the intestine— if a
small
remnant
manner
in a state of
is
in which
prevent glycosuria
will
when the pancreas
persist even
—^must
advanced
dis-
area
saw that one-eleventh of the functional
^Ye
ease.
pancreas
of
the
of
the adrenals sufficed to sustain the general oxidation processes.
That the pancreas area than strated.
it
absolutely
With proper
mal organism armed against .
ingesta
may
more functional needs has been experimentally demon-
possesses at least four times
is
—
—
uneontaminated
fresh,
practically invulnerable,
an}^
ehemico-physical
But
undergo.
so
food,
a
splendidly
decomposition
these physiological
noi’is
that
defenses
it
the
may
be weakened through general or local adynamia, he., lowered oxidation processes,
and peptones, capable of )delding toxal-
—
humins, leucomaincs, ptomaines,
all
albuminoids,
dergo further splitting in the intestinal
canal.
—
fail to
un-
Again, and
under the same circumstances, notwithstanding the destructive action of the gasti-ic and intestinal secretions, bacteria and their toxins circulation.
may
and the portal The blood-stream, furthermore, may be invaded penetrate the debilitated
villi
through
peripheral organs not only by baeteria and their but also by vegetable poisons and venoms all albuminoid substances, as previously emphasized. Even these do not reptoxins,
:
resent all the sources of danger that a protective function, such as that represented by the pancreatic and splenic secretions,
would have to meet, were they, as to fulfill such a mission. It toxic
I believe,
mainly intended
allmminoids reach the portal vein by way of the and the mesenteric veins, all conditions therein
intestinal villi
most advantageous for the action Avhich ti’ypsin is knoAvn to exercise upon tliem It acts with groat energy in alkaline media, and the presence of oxyg(>n does not iidiiliit its action;
are
:
INTERNAL SECRETIONS OF PANCREAS AND SPLEEN.
370 if,
tlierefore, the
happen
venous blood of the alUerent channels should
to contain
an unusual amount of oxidizing substance
through suprarenal overactivity, the tryptic disruption of peptones would not, to say the least, be prevented; in laboratory
experiments the need of an antiseptic when pancreatic juice is
used
sels,
is
well
known; we have
seen that, in the afferent ves-
the fluids derived from the intestines had been saturated
therein with the antiseptic secretion of the glands of Brunner
and Lieberkiihn, and
it
is
evident that their influence would
normally continue in the venous channels; of trypsin does not cease it
when
finally,
the peptone stage
the action is
converts these into leucin, tyrosin, aspartic acid,
fate
which derivatives
of
I
reached; etc.,
the
have traced down to urea, the
end-product eliminated in the urine.
The
by the spleen in the pancreatic digestion of proteids, and to which I add a prophylactic function, has been so ably reviewed by H. F. Bellamy in a comparatively recent
role played
number
of the
London Lancei^^
that I will utilize the
greater part of his paper to illustrate the various features that appear to me to furnish a solid foundation, not only for the
views of
SchiflP
and Herzen, but
also for mjf
own.
The author reviews the history of the question as follows: “Corvisart found that in dogs in full digestion there was for a
certain time a constant rise to
power of the pancreatic fall
to
minimum.
maximum
juice, succeeded
in
the digestive
by an equally constant attained during the
The maximum was
eighth hour after the ingestion of a meal; the minimum from ]\Ieissner announced the thirteenth to the eighteenth hours. that in fasting animals the pancreatic juice possessed little or no peptonizing power. Schiff, after a number of experiments
on such animals as
rats, guinea-pigs, rabbits,
and young dogs
found that during fast the pancreas albumin really possessed almost no peptonizing power; the imprisoned in the duodenum remained there for whole hours
or dogs of small breed,
without dissolving, the infusion of the gland giving results On the other hand, in the case of ravens equally negative. and adult dogs of large breed the pancreas preserved during condition fast a certain digestive power, even in animals in a 10 II.
F. Bellamy:
London Lancet,
Oct. 27, 1900.
371
RELATIONSHIP BETWEEN SPLEEN AND PANCREAS. of complete fast
which had digested a copious meal the day
before; under these circumstances, indeed, the infusion of the whole pancreas of a large dog was capable of digesting from
In such dogs this condition until toward the fourth hour maintained of weak digestion was after the meal, after which time digestion proceeded very much more rapidly, so that at the time of maximum the panDO to GO
grammes
of albumin.
was capable of digesting from 50 to 60 grammes As regard cats and small dogs, he was able to
creatic infusion
of albumin.
By
confirm the results of Corvisart.
above-mentioned
the
these experiments, then,
succeeded
observers
in
establishing
the
that the activity of the pancreatic
following two facts: (1) juice or of an infusion of the gland is not continuous,
but
in-
and (2) that maximal activity appears regularly during the culmen of gastric digestion (from six to eight hours after a meal), at which time it is very considerable.” Passing now, for the moment, from the pancreas to the spleen, he proceeds briefly to examine the behavior of this organ in relation to digestive phases. “Lauret and Lassaigne termittent,
in
1825 discovered that the spleen began to become congested
at the
mo.ment when the stomach discharged chyle abundantly
duodenum; that this is, however, merely a coincidence shown by the fact that the congestion also occurs after ligature of the pylorus. Dobson in 1847 discovered that in a dog three hours after a meal the spleen is still as small and as anaemic as during fast; that it commences to dilate in the fourth hour after a meal; that five hours after it has attained its maximal turgescence, decreasing afterward from the sevinto the is
enth hour to attain toward the twelfth
its
minimal volume.
Landois in the same year found that in the rabbit the relative weight of the spleen to the body-weight of the animal was the same two hours after a meal as after forty-eight hours of fast; that it increased considerably from the fifth hour, remaining high until the twelfth hour “The striking synchronism in the splenic congestion and
the
presence of trypsin
in
large
juice or in air infusion of the gland
quantity in the pancreatic
was observed by Schiff and former experiments on the tryptic digestion of albumins, this time on animals in wliieh tlie spleen
caused him to repeat
all his
24
—
—
INTERNAL SECRETIONS OF PANCREAS AND SPLEEN.
372
had been for sonic time removed and on others in which it was prevented from dilating by ligature of its hilum at the
He
time of the e.xperiment.
number
a very large
experimented in this way upon
of dogs and cats
ments were double i.e., performed the same manner on two animals :
one another as the
much
all
his experi-
the same time and in
selected
so
as
to
resemble
and in only one of wbich had
as possible,
been extirpated
spleen
at
nearly
;
These experiments were of two kinds; (1) those conducted with pancreatic infusions, and (8) those carried out in the living duodenum, the or
ligatured.
following being typical examples “I. Infusions.
:
Ligature of the Ililvm of the Sj)leen.
—Two
much meat as they hour afterward they were etherized, and the spleens, which were found to be in a state of contraction, were brought out through a ivound in the abdomen and their hila were encircled by strong thread; in one of the animals the eats, after fasting for 19 h.ours, received as
would eat;
1
hilum was firmly tied, but in the other it was simply encircled and a knot was tied, leaving the splenic circulation perfectly free (this
was done in the endeavor
ditions as
much
in
as possible).
The
to equalize traumatic con-
spleens were then replaced
abdominal cavity and the wound was sutured.
the
On
recovering from the amesthesia the animals did not appear to suffer. They were killed G hours later. Gastric digestion was found to be more advanced in the animal in which the splenic
vessels
were
tied
;
the pancreas of both was cut
up
into small
fragments and infused with fOO cubic centimeters of Avater for an hour at 35° C. ; the liquid was afterward decanted and returned to the warm chamber together Avith cubes of albumin. “Result.
—In
7 hours the pancreatic infusion of the cat in
Avhich the hilum Avas not ligatured digested 17 grammes of albumin ; that of the other did not digest at all even at the end of 12 hours. “This experiment Avas performed on a large number of In spite, Iioaa"cats and dogs and ahvays gave the same result. ever,
of
of the perfection
animals,
it
gastric
digestion
Avas possible to lay at the
in
the
operated
door of traumatism the
absence of duodenal digestion; to correct this the experiment Avas repeated as folloAvs
:
373
RELATIONSHIP BETWEEN SPLEEN AND PANCREAS.
“ExtirpalUm of the 5'pZeen.— Two dogs— one normal, the other having nndcrgonc splenectomy a month previously, but were operated at the time of the experiment in perfect health
—
ufion, while fasting, as follows
pylorus, injection into the
:
Etherization, ligature of the
stomach, per oesophagus laid bare
and opened, of 50 grammes of peptone and 2 grammes of dextrin; to allow drainage of swallowed saliva the oesophagus was Both animals were killed live ligatured below the opening.
and each pancreas was infused for three-fourths of an hour in 100 cubic centimeters of water at 35° C. Although death had occurred before the most favorable moment for the experiment,—i.e., in advance of the summit of the splenic curve, the infusion coming from the dog Avith the spleen intact digested 17 grammes of albumin in 17 hours, while the
hours
later,
—
iSTumerous experi-
other digested nothing even in 18 hours.
ments made in
this
manner ahvays gave the same
spleenless dogs
had
in
many
cases
result.
undergone splenectomy
The sca'-
eral months before the experiment, and the determination in them of perfect conditions of health was ahvays a matter of
great care. “II.
the
Experiments in the Living Duodenum. Ligature of ^Two dogs after fasting for 17 at Both Ends
Duodenum
.
hours received as
—
much meat
ately aftei'Avard were operated
would eat and immedi-
as they
upon
as folloAvs:
Etherization,
laparotomy, ligature of the pylorus and of the bile-duct, introduction into the
duodenum
of
from 30
min, and ligature of the jejunal end. the splenic hilum Avas also ligatured.
to 40
grammes
of albu-
In one of the animals Both were killed 7 hours
later.
“Besidt
min
Avas
.
—In the dog
Avitb the splenic
found to be intact;
it
hilum
tied the albu-
had, hoAvever, disappeared in the
other.
“This experiment was also several times repeated on animals Avhich had undergone splenectomy a long time previously, and ahvays yielded the same result; it is, of course, capable of being comliined Avith the preceding
by making an infusion
of the pancreas after the death of the animals. Such infusions give results in harmony Avith those furnished by tlie duodenum itself.
Further,
it
Avill
be remembered that in the pancreatic
:
INTERNAL SECRETIONS OE PANCREAS AND SPLEEN.
374
juice of dogs of large breed Sehiff generally found, even -while fasting,
a
quantity of trypsin;
certain
spleenless, however,
he was unahle to find any.
Duodenum Provided
“Digestion in the Normal
ula.
—A duodenal
jilote
when the same were
was established
fistula
with a FistAfter com-
in a dog.
recovery a measured and constant quantity of albumin
was introduced every day into the duodenum inclosed
in
membrane thread some centimeters long. The
by a
small envelope of fibrous
fixed to the cannula
progress of digestion was
then observed, the following results being obtained: the animal was fasting the albumin took from to
hecome
into the
dissolved.
2.
When
duodenum during the
the
3.
When
1.
When
G
hours
5 to
albumin was introduced
2 to 3 houi-s immediately fol-
lowing the ingestion of a meal hy the animal changed.
remained un-
it
introduced 4 hours after a meal
appeared very quickl}q
—
a
it
dis-
in about half the time, in fact, occu-
These facts having been duly noted, the spleen was then extirpated, and after complete recovery the same experiment was repeated; very different results were now obtained. Whether fasting or in full digestion the time
pied
during
fast.
taken for the digestion of the albumin was exactly the same, The acceleration in the peptonization viz.: from 5 to G hours.
which had formerly appeared after the fourth hour of digestion,
and Avhich coincided both with the appearance of trvpsin in the pancreatic juice and with the dilation of the spleen, was
now
absent.
The slow
(from 5
digestion
to 6 hours)
in this
experiment was probably entirely due to the secretion of the duodenal glands, which possess
power; the
onl}'
was due
active, rapid digestion
in large quantity, of trypsin
nomenon wanting
in
the
in
a ver}"
digestive
feeble
to the appearimce,
the pancreatic juice:
spleenless
animal;
.
.
a phe-
Schiff
.
by the following theory endeavored to interpret During the congestion of the spleen a substance is produced within it which, carried away hy the blood, gives to the panthe
creas the wherewithal to
facts
fonn
its
peptonizing ferment.
.
.
.
In 1872, however, the theory of Schiff received a rude shock through the great discovery of the zymogens by TTeidenhain
and
his pupils.
From
the researches of this observer
peared that, as the gastric
mucous membrane
fo'rms
it
ap-
at
the
0/5
relationship between spleen and pancreas.
outset hardly any active pepsin, but a zymogen accumulating does in its glands in the intervals of digestion, so the pancreas
not at once elaborate active trypsin but a substance destined certain to become trj'psin under certain conditions and in a
phase of the digestive act, this substance being, of course, the pancreatic zymogen trypsinogen, or protrypsin. The researches of Ileidenhain are well known, and it suffices to recall here
more
only one or
essential points
Thus from them we know
:
that the pancreas of a fasting dog contains little or no trypsin,
but
merely
trypsinogen;
consequently
infusion
glycerin
its
no digestive power; the infusion, howevei\ of a dog in full digestion digests rapidly and copiously, because If the pancreas of a fasting dog be divided it contains trypsin.
possesses little or
two equal portions, one of which is infused at once and the other only after an exposure of 24 hours to the air, the first is found to be inactive, while the other is immediately and into
from which it is clear that the inert trypcontains becomes spontaneously transformed
energetically active,
sinogen which into
active
it
trypsin; indeed,
suffices
it
to
pass
a
cuiwent of
oxygen through a pancreatic infusion, rich in trypsinogen and poor in trypsin (an active infusion), to transform infusion possessing
a
into an
This transformation,
power.
digestive
it
an oxidation, trypsin being oxidized trypsinogen. “The fact observed by Heidenhain of the continuous for-
then,
is
mation and storing up of trypsinogen in the pancreas and
its
subsequent transformation into trypsin during the culmen of gastric digestion proved that the
former substance at any rate
enjoyed an origin quite independent of the pancreas
itself,
all
influence
and the hypothesis of Schiff
outside
as to the inter-
vention of the spleen seemed, in consequence, to be at fault.
But new
it
was only the theory of Schiff which suffered by these
revelations; as far as the experimental results of the
two
observers were concerned, physiologists were face to face with
two
series
of
apparently
contradictory
facts
—apparently
be-
cause facts properly observed can never stand in contradiction
with one another, and
when they appear
beeause the interpretation of them plete.
It fell to the lot of
hypotheses.
It appeared to
l\f.
is
Herzen
him
that,
to do so it is
either
false
merely
or incom-
to unravel the tangled
by modifying the hy-
INTERNAL SECRETIONS OF PANCREAS AND SPLEEN.
370
pothesis of Schiff as to the
manner
which the spleen
in
a tryptogcne, a fusion of the respective facts of
Heidenhain could be brought about, and antagonistic, they could be
lie argued thus
tive.
tomized animals,
is
:
shown
that, far
acts as
Schiff and from being
to be reciprocally corrobora-
since the zymogen, even in splenec-
being continuously elaborated, and there-
fore independently of the spleen and its periodical congestion,
and that it accumulates in the gland-cells during fast, but that it becomes rapidly and copiously transformed into trypsin only in the presence of the spleen and in direct proportion to its dilation, it would seem feasible that the spleen produces, by ‘internal secretion’ during its congestion, an unknown substance, which, carried away by the circulating blood, transforms the inert zymogen already deposited in the pancreas into active trypsin destined to pass into the secretion of the gland,
and that the influence exercised upon the zymogen by this product of the spleen seemed to be a condition sine qua non for the transformation of the former into trypsin, at least in the living pancreas, since in the dead organ or its infusion it is
so
transformed by
dii’ect
oxidation.
This hypothesis of
Herzen would seem to be further confirmed by the fact gleaned from the researches of both Schiff and Heidenhain, to wit: that the holding in zymogen of the pancreas at a given moment cither of fast or digestion is always in inverse ratio to its hold-
ing in trvpsin, and vice versa, while the latter
is
always in
direct proportion to the spleen dilation.
“So
far so good.
But Herzen reasoned
spleen really produces, during
its
further.
If the
congestion, a substance which
about the transformation of the pancreatic zymogen upon this subinto trypsin, it would then be possible to seize condition stance in the spleen itself while in its turgescent an making once by at and (from 6 to 7 hours after a meal),
brings
infusion of
it
and mixing a certain
infusion with pancreatic infusion a fasting animal (very rich in
.quantity of this .splenic
made from
the pancreas of
zymogen and very poor
in tnpsin,
in and consequently nearly inactive) there could be obtained recognizeasily vitro a rajiid and copious foniiation of trvpsin
Ihe by the amount of proteid digested in a given time. merely consisting simple, control experiment would also be very alile
—
377
RELATIONSHIP BETWEEN SPLEEN AND PANCREAS.
same pancreatic infusion that of a contracted and anemic spleen, in order to observe whether it would have the same effect as that of the spleen dilated and engorged with in mi.xing with tne
blood.
infusions
gave enormous differences
out with
carried
actually
digestions
Artificial
these
whereas the pancreatic
:
infusion alone, or that mixed with infusion of contracted spleen digested nothing or almost nothing, the same pancreatic in-
fusion to which had been added infusion of engorged spleen digested rapidly and copiously; indeed, digested
had often completely
it
dose of proteid by the time that the other two,
its
digesting at
all,
The mixed
had barely commenced.
thus behaved in the same
way
if
infusions
as a pancreatic infusion taken at
the culmen of digestion.
“A
large
number
of similar experiments were
made with
aqueous boric and glycerin infusions, each being double:
performed in two separate
series of vessels, the
i.e.,
one containing
and the other equal-sized cubes of coagu-
finely divided fibrin
The results were always the same. “At the German Congress of Medicine held at Strasburg
lated albumin.
.
.
.
in 1886 Herzen exhibited several graduated flasks containing the residua of fibrin
and albumin
in a
number
of his digestions,
and replaced by alcohol. The physiologists who examined them all recognized that the difference between the residua left by the pancreatic infusions alone and those of the mixture of the pancreatic and splenic infusions were very obvious. In a private conversation the
digesting
having been
liquid
decanted
with Herzen, however, Ileidenhain made the following criticism It is well Icnown that the pancreatic zymogen is very greedy of oxygen; on the other hand, the spleen during its :
dilation
is
engorged with blood.
hibited were intensely colored
the undoubted and
The
splenic
infusions ex-
by dissolved haemoglobin
considerable acceleration in
tained by adding such a liquid to
ergo,
digestion
ob-
another containing tryp-
sinogen could be quite simply explained by the rapid oxidation of the zymogen at the expense of the haemoglobin. This objection disconcerted Herzen in no inconsiderable degree,
he
lost
quiry.
no time
He
in
making
it
the subject of experimental in-
at length succeeded in disproving it
excellent experiment:
and
The pancreas
of a
by the following normal fasting dog
INTERNAL SECRETIONS OF PANCREAS AND SPLEEN.
378
was infused in pure glycerin and the infusion was divided into eight equal portions. These eight portions were mixed with eight samples of, blood received directly into a double volume of glycerin, of which four came from a fasting dog and four from a dog in full digestion with the spleen greatly dilated.
The four samples were taken
in both animals from (1) the femoral artery, (2) the femoral vein, (3) the splenic artery, and (4) a large sjilenic vein. The eight portions were then given the usual dose of fibrin and placed at a temperature of
40° C. rial
Now,
it
is
evident that the femoral and splenic arte-
blood of the two animals contained more oxygen than
their venous blood; the former, then, according to Heidenhain,
should exercise a powerful influence on the digestion, equal
On
in the two dogs.
the other hand, according to Herzen, the
splenic venous blood alone should exercise this influence especially
that
of
the
digesting animal.
experiment was as follows
The
result
of
and the
After one hour there was still no trace of digestion under the influence of the femoral blood, arterial or venous, nor of the splenic arterial blood of the fasting dog; first traces of digestion were beginning to manifest :
themselves under the influence of the splenic venous blood of this animal.
Digestion was rather advanced in the case of the
femoral arterial and venous blood and splenic arterial blood of the digesting dog; the fibrin
had almost
entirely disappeared
under the influence of the splenic venous blood of the same animal.
“The answer could not be
clearer:
the product of the
internal secretion of the spleen, borne therefrom by the cir-
culating blood,
is
present during the period of the dilation
of the spleen in feeble, but appreciable, quantity in the blood
and abundantly in the splenic venous The venous blood returning from the contracted spleen blood. This experiment, only contains it in very small quantities. same result, showing gave the times repeated, always several of the general circulation
that
it
is
not the blood as such which favors the transformazymogen into trypsin, but that, by picking
tion of pancreatic
up from the spleen the unknown substance possessing this its vehicle and means of commu-
property, the blood becomes nication with the pancreas.
KELATIONSI-IIP
‘Trom
379
BETWEEN SPLEEN AND PANCREAS.
the bulk of evidence collected by Herzen there thus
seems to be very
little
room for doubt
that, apart
from hasma-
topoietic, and possibly allied, functions possessed by the spleen,
the
organ furnishes a product of ‘internal secretion’ which
zymogen
causes in the pancreas the transfoiTuation of its inert into active trypsin.”
Bellamy
closes his article
with a review of the criticisms
which the researches of Schiff and Herzen have been subIn the experiments of Lussana, in 1868, the spleens of three dogs were removed and the animals were subsequently killed to ascertain whether the extract of their pancreas would to
mitted.
coagulated
digest
The pancreatic
albumin.
glands of two of the dogs digested 0.25
infusion
gramme
of
the
of
albumin in
24 hours; that of the third digested 1.10 grammes in the same period of time.
“The
latter
three hours after a meal: it
been in possession of
its
animal had, however, been killed
i.e.,
at a
moment when, even had
spleen, that organ
have commenced to become congested.
would not yet
The experiment,
gave the result which might be expected,
—
there-
viz. no dinobody would accept seriously the digestion of 1.10 gi’ammes, knowing that the pancreas of a dog when digesting can dissolve from 50 to 60 grammes of albumin. .”
fore,
gestion,
—
:
^for
.
.
Indeed, the experiments of Lussana appear to ns to be confirmatory of Schiff’s and Herzen’s views. Carvallo and Pachon also reported negatively, but, errors in their experimental procedures having been brought to their
attention by
Herzen, subsequent experiments caused
Pachon
and a new collaborator, Gachet, to reach the conclusions sustaining the views of SchifE and Herzen to which we have referred on page 368. “Hay, they did more,” says Bellamy; “they invented an entirely new experiment, at once original and ingenious, which consisted in realizing in vivo what Herzen had hitherto only done in vitro. This experiment was as follows: A dog, which a long time previously had undergone splenectomy, was anesthetized and half its pancreas was removed and immediately infused; at the same time a normal dog, in the height of digestion, was killed and its congested spleen was infused in Avater, and this infusion AA'as injected into the venous system of the spleenless dog; from 15 to 20
—
—
INTERNAL SECRETIONS OF PANCREAS AND SPLEEN.
O(S0
minutes afterward the remaining half of the pancreas of the latter dog was infused exactly like the first; of the two infusions udien given fibrin and albumin, the second only digested rapidly and copiously.” T1i 6
investigations
of
are next reviewed.
Popelski
‘‘In
both normal and splenectomized cats,” says Bellamy, “he lected the pancreatic juice by
means
col-
of a cannula introduced
into the duct of the gland, and was unable to find any differ-
ence
in
digestive
As, however, his cats had
activity.
side the
digestive period during which
congested, furnishes abundantly
its
been
made
fasting since the day before, his experiments were
out-
the spleen, becoming
product of internal secre-
zymogen into “But Popelski also performed some analogous experiments on a dog with a permanent pancreatic fistThe pancreatic ula, made according to the method of Pawloff. and examined collected juice of this animal was several times before and after splenectomy without any difference in activity tion which transforms rapidly and copiously the
trypsin.”
.
.
.
being demonstrable.
This
result,
however,
in view of the fact that in both instances collected immediately after a meal
i.e .,
no surprise
elicits
tlie
juice
—again
was always
to repeat it
advance of that digestive jieriod during which the spleen enters into function and the pancreas abounds in trypsin; so in
that as well in this experiment as in that with his cats, Popelski
was placed in that position in which the presence or absence .” of the spleen was a matter of perfect indifference. .
The
discussion
of the
.
various features in point have led to
considerable acrimony, but the impartial obseiwer cannot fail to consider that the position of Herzen, of those reviewed, is
the only tenable one. Bellamy’s review was published I’opelski“ reiterates his views, and states that since it has been demonstrated that there exist in the organism bodies in
In an
article written since
the nature of ferments possessing oxidizing properties, which he believes to be derived mainly from leucocytes, the results
obtained by Schiff,
Herzen, Pachon and
explained by their action.
Popelski:
Vratch, Feb.
3.
1901.
Gachet can
During the height
of
all
be
digestion
FUNCTIONAL MECHANISM OF THE PANCREAS.
381
an accompanying destrucmore oxidizing bodies, the latter,
digestive leucocytosis prevails, and, tion of these
cells
yielding
he thinks, are the source of conversion of protrypsin or trypsinogen into trypsin, which thus becomes a function of the blood.
Thus, the spleen would have nothing to do with the
process, the
hyperamia and dilation of
during the
this organ,
formation of trypsin being regarded merely
as
concomitant
phenomena. feature of interest to us in Popelski’s last paper
The only is
the fact that his experiments were performed in accordance
That he should be driven thereby to ascribe all the phenomena witnessed to the action of ‘^oxidizing bodies” adds materially to the data contributed by Schmiedeberg, Jaquet, Abelous and Biarnes, and Salkowski, proving experimentally the existence of an oxidizing substance, and is suggestive. Indeed, when, in addition to this, we realize the strength of Heidenhain’s position, the manner in which with the directions of Schilf.
it
shook to
its
very foundation the equally strong position of
by Herzen, by pointing to the inoxygen another as agency through which trypsin of could be developed from trypsinogen, “trypsin being oxidized Schitf’s views as developed
fluence
trypsinogen,” the following (piery suggests itself:
Are we not
dealing with two processes working in sequence, a part of the
trypsinogen secreted in the splenic vein being converted by
and the rest are reached, by the oxidiz-
the splenic secretion for use in the portal vein,
being converted,
when
the arteries
ing substance?
To determine whether
such a deduction
is
at all warranted
t
or whether
it
is
subject to modifications through which
various views submitted and our find
it
the
own can be conciliated, we manner in which the
necessary to closely analyze the
pancreas and the spleen are functionally governed.
The Functional Mechanism pancreas will
first receive
gan, Howell says:
of the Pancreas.
our attention.
Pef erring
—The
to this or-
“Until reeently little direct evidence had been obtained of the existence of secretory nerves. Stimulation of the medulla was known to increase the flow of pancreatic juice and to alter its composition as regards the organic constituents, but direct stimulation of the vagus and the sympathetic
INTERNAL SECRETIONS OF PANCREAS AND SPLEEN.
382
nerves gave only negative results.
Lately,
however, Pawlow
and some of his students have been able to overcome the and have given what seems
technical difficulties in the way,
to be perfectly satisfactory proof of the existence of distinct
secretory fibers comparable in their nature to those described
The
for the salivary glands.
may
have obtained
results that they
be briefly stated as follows: Stimulation of either the vagus
nerve or the sympathetic causes, after a considerable latent
marked flow
period, a
The
of j^ancreatic secretion.
failure of
other experimenters to get this result was due apparently to the sensitiveness of the gland to variations in
its
hlood-supphj}-
Either direct or reflex vasoconstriction of the pancreas pre-
upon
vents the action of the secretory nerves
ulation of the sympathetic gives usually no
Thus, stim-
it.
effect
upon the
secretion, because vasoconstrictor libers are stimulated
same time; but
if
the sympathetic nerve
is
at the
cut five or six days
previously, so as to give the vasoconstrictor fibers time to degenerate, stimulation will cause, after a
long latent period, a dis-
tinct secretion of the pancreatic juice.”
The
quotation almost suffices to show that the SAunpathetic
are
fibers
and
views,
vasoconstrictors
as
elseivliere,
that the secretory nerve
is
in
the
light
the vagus.
of
our
This view
conclusively supported, however, by evidence from other direcAs to the vagus, Franqois-Franck and Hallion^^ in additions.
is
tion to the dilator effects produced on the liver state that “this
vasodilator action
is
also
found in the pancreas.”
Stimulation
of the peripheral ends of both vagi, after section, between the
cardiac plexus and the diaphragm caused a wide dilation of the pancreatic vessels, which persisted soiue time, entailing a Ioav-
ering of the aortic pressure.
They
also
obtained dilation of
by stimulating the central end of the e nerve after it had been cut on a leA’cl Avith the msophagus. have also in the experiments of Alette*'* and IxudrcAA’etzkv*® evidence of the direct action of vagal stimuli upon muscular these
vessels
fiber.
reflexly,
Having observed
that the secretion caused by stimulating
Italics are our own. Frangols-Franck and Halllon: T,oc. rit. Mette: Archlv f. Physiol., Suppl. Bd., 1894.
All
“ Kudrewetzky
:
Ibid.
383
FUNCTIONAL MECHANISM OF THE PANCREAS.
one vagus could often be arrested by exciting the other vagus, he concluded that this nerve contained antagonistic fibers. This dual
becomes unnecessary, however,
set
accepted
mechanism
the
as
the
of
Frangois-Franck and Hallion.
stricto-dilation
if
vasodilation
is
observed by
Indeed, vagal stimuli capable
of causing contraction of the vascular muscles to which strictodilation is due, can as well induce contraction of the muscular
coats of Wirsung’s duct,
and thus
arrest the flow of secretion
of pancreatic juice precisely as it does that of bile.
sjmipathetic supply Frangois-Franck
As the
and Hallion^®
obtained plethj'^smographically vasoconstrictor effects on stimulating the splanchnic, and traced the constrictor fibers to the
The
cord.
were su]iplied through the
fibers
fifth thoracic
com-
mamunicating branches to the second lumbar jority of them reaching the solar plexus by w^ay of the greater splanchnic. The fibers then formed, they contend, “a secondary inclusive, the
They
plexus enveloping the pancreatic artery.”
also state that
“this arterial path seems to be tbe only one, since the destruc-
accompany the artery suppress the pancreatic vasoconstrictor effects of any sympathetic branch stimulated.” Again, Popelski^^ refers to various ways in which
tion of the fibers that
inhibition of the flow of secretion
may
be caused.
Stimulation of the vasoconstrictor
are:
of “secretion-inhibiting” fibers supposed
The mode
special set.
fibers,
Among
these
and stimulation
by him to represent a
of termination of the sympathetic fibers
on tbe pancreatic artery as given by Frangois-Franck and Hallion readily accounts for the inhibition caused by excessive excitation of the nerves.
evolved nerves
from the
—a
These (sympathetic)
suppositious
special
fibers are thus
“secretion-inhibiting”
rather incongruous combination, since by arresting
the flow of blood to the organ, they prevent
and
may
arrest the
secretory process. It is evident that these vasoconstrictor fibers are distinct
from the true secretory fibers, for Paw’ow'® saj's, alluding to Popelski’s work ^Tly a careful preparation of the nerves. :
Frangois-Franck and Hallion:
Archives de physiol, norm, et pathol., T.
Ix, p. 6G1, 1897.
"Popelski;
Centralbl.
“Pawlow:
"The Work
f.
Physiol., Bd. x, S. 405, 189G.
of the Digestive Glands,”
Eng. Trans., London,
1902.
INTERNAL SECRETIONS OP PANCREAS AND SPLEEN.
3R4
some brandies were discovered whose excitation caused a secretion witlioiit any latent period almost as promptly as the chorda expels saliva. From the latter fact we must conclude that in the branches mentioned,
secretory
the
libers
the
of
pancreas have been anatomically separated from the inhibitory.” Finally, a proof that
we
are dealing with exaggerated constric-
tion ending in experimental
nerve
secretory
Kudrewetzki’s'”
is
and not with a true
inhibition
hy the following observation
all’orded
of
“If tbe sympathetic nerve be excited hy means
:
of an induced current, a gentle intermittent advance of the secretion
observed, hut only during the first few seconds;
is
during the
later stages of the excitation,
the secretion
is
and
We
completely arrested.”
after its stoppage,
have here, obviously,
the identical result observed in the submaxillary gland the cervical sympathetic
stimulated
is
—a
when
exacerbation of
lirief
due to the propulsion of a small quantity of blood into
activity
the secretory elements
—and
simultaneously additional evidence
sympathetic in the pancreas
that the
vasoconstrictor
fulfills
functions.
This involves the conclusion that as elsewhere the bloodplasma laden with oxidizing substance is able to reach the
—
—
is shown by a brief review of the relationnervous and vascular structures of the organ. ship between the
glandular
This
cells.
lleferring to the blood-vessels, Piersol says
sending
off
the glandular parenchyma with twigs. lobules
and form net-works which
within the capillary reticulum.
basement membrane '
thelium.
:
“The
larger
nm
within the interlobular connective tissue, vessels which pass between the lobules and supply
arterial branches
The
veins
These
latter enter the
inclose the individual acini
The
capillaries lie beneath the
in close relation Avith the glandular epi-
accompany the
A
arterial trunks witliin the
arrangement prevails in the According to Eamon y distribution of the nerve-terminals.
connective
and C.
Cajal
and
tissue.”
Sala,
fibers of llemak.
similar
the
pancreas
Some
contains
nerve-cells
others are in contact with the intrinsic vascular their finer prolonyations surround the glandular
spaces;
and
many
cells are found in the interacinous
Kudrewetzkl:
Quoted by Pawlow;
Loc.
cit.
Avails, cells.
—
FUNCTIONAL MECHANISM OP THE SPLEEN.
385
Those connected witli the vessels form a plexus around them, and send extremely tine filaments to tlie muscular elements. Alluding to the nerve-cells, Eamon y Cajal says: “We may consider this cell as a special
almost
all
cell,
all
the prolongations, of which possess the
nervous prolongations contrary to the chain, that have two fiber of
Remak,
parable
to
the
destined
celhs,
the prolongations, or
neighboring
protoplasmic
cells
establish
of
a
meaning of sympathetic
along one, or
kinds of prolongations:
and short jirolongations com-
for the viscera,
to
cells of the
prolongations
relations
ganglion.”
of
cerebro-spinal
by contact between the Berdal,
who
quotes
the
above, therefore recognizes two varieties of nerve-fiber in the
pancreas:
“1.
The
formed by the cellular proand perivascular derived from the sympathetic
nerve-fibers
longations and which supply the periaeinous plexuses.
2.
The
nerve-fibers
nerves which penetrate into the pancreas with the vessels.
On
the whole the functions of the pancreas appear to be
governed as follows:
The nervous supply of the pancreas vagus and the sympathetic systems. 1.
is
derived from the
2. When the secretory functions of 'the organ are to he enhanced, the vagal terminals cause vasodilation of its arterioles, thus increasing the arterial hlood circulating through it. S.
When
diminished
the functional activity of the pancreas is to he
its
pathetic nerves,
arterioles are
and
caused to contract hy the sym-
the hlood circulating through the organ is
reduced.
Functional Mechanism of the Spleen. tion
of the spleen includes,
—The
innerva-
as a
predominating feature, the distribution of a fair proportion of the terminal fibers to the muscular elements, which, in man, are mainly supplied to the
“Wq have evidence,” says Professor Poster, “that the muscular activity of the spleen, whether of the muscular capsule and trabeculae and arteries combined, or of the latter alone, is under the dominion of the nervous system. A rapid
trabeeulae.
contraction of the spleen
may he brought about in a direct manner by stimulation of the splanchnic or vagus nerves,” “it may also be caused by stimulation of the medulla ohlongata with a galvanic current or by means of asphyxia. Though the
— ;
INTERNAL SECRETIONS OF PANCREAS AND SPLEEN.
386
matter has not yet been fully worked out, we have already indications that the flow of blood through through the agency of the nervous system, varied to meet changing needs. At one time a small quantity of sufficiently
the spleen
blood
clear
is,
passing through or
is
is
the metabolic changes which
being held by the organ and
undergoes in the transit are
it
At another time a larger quantity of blood enters the organ and is let loose, so to speak, into the splenic pulp, there to undergo more profound changes, and comparatively slight.
afterward to be ejected by rhythmic contractions of the muscular trabecula}.”
That rapid contraction
of the spleen should occur under
stimulation of the splanchnic nerve the role of sympathetic nerves is
—
is easily
^those
it
accounted for when
supplies the organ
considered to be that I have attributed to them in the fore-
going chapters:
that of vasoconstrictor.
Indeed,
it
plain
is
that under stimulation these nerves, should reduce the caliber of the arterioles, and, therefore, the volume of blood admitted into
the organ, and that
tinued depletion of
is
should contract rapidly owing to con-
its veins.
lation of the medulla as this is
it
on the
The
constrictive effect of stimu-
we have
arteries
due to contraction of their muscular
evidently influenced in a
manner
repeatedly seen coats, the spleen
similar to that following
stimulation of the splanchnic, the smallest arteries being the flrst
obstructed under violent vasoconstriction.
But why should stimulation splenic
contraction?
distribution
of
This requires
of the nerve-terminals.
the
an
vagus
also
examination
The innervation
induce cff
the
of the
spleen was studied by Kolliker in various animals,^® and his
when viewed in the light of my conception of the functional mechanism of glandular organs, are suggestive. “The vasomotor nerves enter the organ with the large arteries. In the walls of the large arteries the main trunks form a wellmarked superficial plexus with oblong meshes in the adventitia, and a deep, more quadrate net-worlc in the tunica media; some The end in the little branched arborizations in this coat. observations,
smaller arteries and the trabecula} receive their nerves from
2®
Kolliker:
Sitzungsberlcbt
d.
WUrsb. Phys. med. Gesellschaft, No,
2,
1893.
FUNCTIONAL MECHANISM OF THE SPLEEN. the rich
maze of
387
fibers in the pulp, consisting of axis-cylinders,
Other
which, however, do not anastomose.
on the surface of the
and from
trabecula3,
fibers
form a plexus
this fibrils
into the interior of the trabeculie (which contain
muscle) and end by
free arborizations.”
Kblliker regards as sensory
fibers,
penetrate
much smooth
Free terminals, which
When we
were also found.
consider that the trabeculie penetrate deeply into the interior of the organ
from the inner surface of the capsule in every
thus forming a spongy frame-work, and that the
direction,
muscular capsule overlying the organ and this spongy frameis also supplied with vagal nerves, its contraction under
work,
the influence of the latter under stimulation also becomes self-
evident in the light of our views dilator allows
an excess of blood
elements, causing
them
acting as a vaso-
to penetrate into the
to contract
Indeed
size of the organ.
The vagus
:
Boy^’-
and thus
who
first
to
muscular
diminish the
called attention to
the rhythmic contractions of the spleen, ascribed
them
im-
to
pulses received by way. of the vagus.
A
feature of the experimental
work upon
this
organ which
tends greatly to produce confusion in the interpretation of function,
is
the belief that
it is
its
supplied with inhibitory fibers.
Thus, according to Schafer^- these fibers are contained in the splanchnic nerves and their stimulation ‘^produces a dilatation of the spleen.” It is plain, in the light of our interpretation of “inhibition,” that
phenomenon due
we
are merely dealing with an experimental
to the excessive vasoconstriction
which
elec-
produces when applied to sympathetic vasoconstrictors, and that the organ does not receive “inhibitory fibers” as text-
tricity
books call them.
The interpretation of the splenic functional mechanism in accordance with our views is greatly facilitated when the microscopical anatomy of the organ is considered in the light of P. P. Mali’s^® researches. The organ is divided, as is the liver, into lobules,
trabeculaj:
each of which
those to
is bounded by “interlobular” which we have already referred. Each
Physiol., vol.
ill,
p. 203, 1880-2.
“ Schafer; “Proceedings of Royal Society,” London, 1890, vol. lix. No. 305; and^ Journal of Physiology, 1890, vol. xx. F. P. Mall: Johns Hopkins Hospital nulletin. Sept., Oct., 1S98»
— INTERNAL SECRETIONS OF PANCREAS AND SPLEEN.
388 lobule
is
about 1 millimeter in diameter,
is
partitioned into
about ten compartments by intralobular trabeculai, and receives
an artery which sends minute branches to each compartment. There is also considerable analogy between each one of these
compartments and the hepatic lobule, the hepatic cells being represented by masses of pulp separated by venules, which back to the veins leading to the greater splenic The pulp vein the various elements transferred to the liver. vessels carry
itself is
made up
of
an extremely
delicate reticulum, in
which
are found red corpuscles, lymphocytes, remains of corpuscles
with or without pigment,
etc.
—
the organ oxidizing substance
The
arteries
—which
bring to
soon after entering the organ
assume an unusual shape: their outer coat becomes l}miphoid, forming nodules similar to the solitary follicles of the intesin which lymphocytes tine, i.e., the Malpighian corpuscles, When, after numerous subdivisions, their diamare formed. eter becomes greatly reduced, the arteries resume their normal adventitia and on reaching the pulp in the compartments break up into minute capillaries. The arrangement is, after all, an
—
uncomplicated one, and similar, in general plan, to that of other organs reviewed.
The connection between
the nervous supply of the spleen
and that of the other digestive organs liecomes evident when the distribution of the coeliac-plexus branches is recalled. splenic plexus,” say Pick and Howden,"^ “is formed by branches from the coeliac plexus, the left semilunar ganglia,
“The
and from the right pneumogastric nerve. It accompanies the splenic artery and its branches to the substance of the spleen, giving
off,
in its course, filaments to the pancreas (pancreatic
plexus) and the left gastro-epiploic ple.xus, which accompanies the gastro-epiploica sinistra artery along the convex border of If we append to this Kolliker’s description of the stomach.” the intrinsic nervous supply and the
manner
in which
it
is
connected with the blood-vessels, it will become apparent that we have a counterpart of the vasculo-nervous mechanism of have studied, all the other organs of the digestive system we viz.,
to a system of vagal fibers capable of inciting the spleen
Pick and Howden:
‘‘Gray's
Anatomy,”
p. 80G.
—
FUNCTIONAL MECHANISM OP THE SPLEEN.
389
increased functional activity by causing an excess of blood to
and sympatlietic
enter the organ,
fibers to
reduce
its
functional
by causing the vessels to resume their normal caliber. The functions of the Malpighian corjjuscles around the
activity
would thus be insured by
vessels
The pulp
fibers
from the vagus.
traced nervous filaments
Fusari-°
deed,
is also
of axis-cylinders”
possessed of a “rich
—doubtless
In-
within these bodies.
maze
of fibers consisting
sensory structures.
But here an
independent motor supply must also be present, since we also
form “a plexus on the surface of the trabecfrom which penetrate into the trabecuhn. These, we have seen, contain much smooth muscle, and the nervefilaments are connected with them by “swellings” (Fusari), have
fibers that
ula3,” filaments
evidently end-plates. is
recalled
by
a
Kupffer’s bile-alveolus, with
similar receptable:
i.e.,
its canaliculi,
Mali’s “intralobular
venous spaces,” whicli form the starting-point of the venules that ultimately end in the large trunks leading to the splenic vein.
On
The nerves
1.
omous
the whole,
we may conclude
as follows;
of the spleen are derived
sources, the vagus, or pneumogastric,
from tivo autonand the sympathetic
system. 2.
The functional
activity of the spleen is incited
vagal nerves distribtited to
its
arterioles:
hy the hy causing dilation
of these vessels, they admit an excess of blood into all the structures of the organ, causing the latter to dilate.
The
vasoconstrictor functions of the sympathetic are as evident here as in other organs studied. “The spleen,” says
Howell, “is supplied richly with nerve-fibers which, when stimulated either directly or reflexly cause the organ to diminish in size.
According to Schiifer these fibers are contained in the which carry also inhibitory fibers whose
splanchnic nerves,
stimulation produces a dilatation of the spleen.” pathetic supply of the spleen has been clearly shown.
The
s}Tn-
Bulgak"‘'“
obtained vasoconstrictor effects, the organ becoming pale and shrunken, by stimulating fibers which ]ie traced to the semilunar ganglion and thence to the left splanchnic. Tarchanoff Fusari: “
Bulgak;
Archives Ttallennes de Blologie, Turin, vol. xlx, Virchow’s Archiv, Dd. Ixlx, p. 181, 1877.
p. 288, 1894.
— INTERNAL SECRETIONS OF PANCREAS AND SPLEEN.
390
reached similar results but by stimulating cither splanchnic. Schafer and l\loore studied the same subject by means of a plethysmograph specially constructed to avoid any obstruction to the circulation in the organ’s extrinsic vessels.
They found
the spleen extremely responsive to blood-pressure fluctuations,
and obtained constriction by stimulating either splanchnic, the left, however, giving more marked results than the right. The constrictor flbers were found to raise from the third thoracic to the first lumbar inclusive, the most active arising from the sixth, seventh, and eighth thoracic. This evidence clearly shows that the role of the spleen’s sympathetic supply constrictor. S.
Hence
When
diminished,
the functional activity of the organ
the
arterioles, thus
purely vaso-
is
:
sympathetic
fibers
came
to
is
constriction
of
he the
reducing the volume of blood admitted into the
organ and passive contraction of its capsule. The role of the spleen has not been so far clearly estabHowell, in the second edition of his text-book (1907) writes in this connection: “As to the theories of the splenic
lished.
functions, the following
may
be mentioned
:
1.
The
spleen has
been supposed to give rise to new red corpuscles. doubtedly does during foetal
life
some animals throughout
life,
in
dence that the function
most of the mammals.
retained in adult life in
is
2.
This it unand shortly after birth, and but there is no reliable evior in
It has been supposed to be an organ
for the destruction of red corpuscles. chiefly
man
This view
is
founded
on microscopical evidence according to which certain
large amoeboid cells in the spleen ingest and destroy the old
red corpuscles, and partly upon the fact that the spleen tissue
seems to be rich in an iron-containing compound.
This theory
cannot be considered at present as satisfactorily demonstrated. 3. It has been suggested that the spleen is concerned in the production of uric acid. as stated above,
and
it
This substance is found in the spleen, was shown by Horbaezewskv' that the
spleen contains substances from which uric acid or xanthin readily be formed by the action of the spleen-tissue
itself.
may More
recent investigations-® have shown that the spleen, like the liver “Consult Jones and Austrian: 1906.
Zelt.
f.
physiol.
Chem,” Bd.
xlviil,
S. 110,
;
FUNCTIONAL MECHANISM OF THE SPLEEN.
391
and some other organs, contains special enzymes (adenase, giianase, and xanthin oxydase), by whose action the split products of the nucleins may be converted to uric acid, and it is
probable, therefore, that this latter substance is constantly
formed in the spleen. 4. Lastly, a theory has been supported by SchifE and Herzen, according to which the spleen produces something (an enzyme) which, when carried in the blood to the
upon the trypsinogen contained in
pancreas, acts
converting
it
into trypsin.”
The
this
gland,
treated at length
latter is
under the next heading.
The statement
that the spleen contains, as do other organs,
such ferments as adenase, guanase, and xanthin oxydase gestive, in
This fact is
view of the fact that they are is all
all
sug-
is
oxidizing ferments.
the more interesting in that, as shown below,
the plasma alone,
i.e.,
plasma deprived of
its
it
red corpuscles
which circulates in the intercellular spaces of the pulp-cords.
An
incidental
remark of Professor
bution previously referred that
I
to,
Mall’s, in the contri-
goes far toward demonstrating
have not erred so far in ascribing to the blood-plasma
per se the active part in the blood’s function.
This constitutes
such a far-reaching feature of this entire work that the follow-
“The microscopical anatomy
ing lines appear to us as timely:
shows that the ampullae and venous plexus have very porous walls which permit fluids to pass through with great ease
granules only with difficulty.
In
and
the plasma constantly
life
flows through the intercellular spaces of the pulp-cords, while
the
hlood-corpuscles
Iceep
within
-fixed
physiological experiments which I have
view.”
If this can occur in the spleen
elsewhere in the organism, especially red
corpuscles average
channels.
made it
is
Numerous
corroborate this
doubtless possible
when we
consider that
diameter about Vaooo of an inch, while the lumen of the majority of functional capillaries is less than one-half that size. Of course, corpuscles adjust themselves
but
to
it is
laries
the
in
dimensions of the
apparent that in
many
of pericellular net-works,
structures
for
surround them
—the tortuous instance— such a system
instances
capil-
could but compromise the free circulation of the fluids, and, simultaneously, the functional efficiency of the organ itself.
392
INTERNAL SECRETIONS OP PANCREAS AND SPLEEN.
THE SPLEXU-PANCREAT[C INTERNAL SECRETION. From the data already submitted as to the functions and the tunctional
relationsliip
between
tlie
of,
spleen and pancreas,
evident that each possesses its own complete mechanism, and that in both organs, as elsewhere in the economy, the oxidizit is
ing substance (adrcnoxidase) or the blood containing source of functional activity.
it
is
the
have we any reason to believe, with Popelski, that through oxidation that the intrapancreatic trypsinogen becomes converted into trypsin ? Can we say, for instance the Still,
it
is
:
intrapancreatic conversion of trypsinogen into trypsin
not
is
by the splenic ferment, but by the oxidizing substance, when the efferent vagus nerves transmit appropriate impulses? We think not, much as such a process would coincide with the effected
multiple functions that we have already ascribed to the oxidiz-
ing substance.
We ally
have seen that when the pancreas becomes fimction-
active
its
arterioles
are caused to
dilate
by their vagal
nerve terminals, and that the speed of the blood-flow through the organ
increased.
is
very rich, these close relation
is
and, though in
with the glandular epithelium beneath the base-
ment membrane, they into
Yet, while the net-work of capillaries
eticircle the secreting lobules,
reticulated
tissue
in
no way, as in the
wherein their blood
spleen, break is
poured;
up
they
merely lapse, as elsewhere in the organism, into venules, which ultimately
carry
the
blood
to
the
larger
venous
channels.
Blood and trypsinogen do not come into contact, therefore, that which text-
in the ducts of the typical pancreatic lobule:
books employ to illustrate the origin, centripetal migration,
and functional elimination of the zymogen granules. These are lost in the lobular lumina and ultimately reach the greater duct on its way to the intestine, without apparently having
come
into contact with the oxidizing substance.
But, this being the case,
how can we account
for the
e.x-
perimental evidence adduced by Schiff and Herzen and other physiologists
who have confirmed
their
explain, for instance, the digestion of 17 in 7 hours with pancreas obtained
work?
ITow
grammes
c
423
THE ADRENAL SECRETION AND THE HEART.
were most consioicuous on the papillary muscles and in the neighborhood of the great vessels, being less easily seen in the region of the apex, where they were obscured by the trabecular
net-work.”
Very suggestive in connection with .my own views are also the observations of Gad® on the vessels of Thebesius in the “In the ox, and to which Pratt refers in the following words of the action the method which he describes for demonstrating valves of the left heart, wherein water under pressure is made :
to
fill
the ventricle and aorta, he noticed that water flowed
from the foramina Thebesii. On illuminatleft ventricle he was enabled to see fine, blood-stained streams issuing from the endocardial wall into Finally he the clear water with which the cavity was filled.” “working Kennedy,® who, Magrath and labors of reviews the with artificial circulations of defibrinated blood on the isolated into the right heart
ing the interior of the
heart of the cat, observed that a small portion of the coronary
blood found
way
its
from the
leakage past the aortic valves.
manometer-record
The only
into the left ventride.
source of access other than
aortic
of
possible
was shown by a
vessels of Thebesius
Tliis leakage,
pressure,
did
as
The
not occur.”
author closes his review of the literature of the subject with
statement
the
that
“notwithstanding
servations, the vessels of Thebesius still
painstaking
these
ob-
occupy a very obscure
ferred to as constant in
Foramina Thebesii are rethe right auricle, forming in part the
mouths of small
Their occurrence in the
position in anatomical literature.
veins.
occasionally mentioned. sius
open into
as auricles
—
is
all
But the
left auricle is
fact that the vessels of
the chambers of the heart
—
^\''entricles
Thebeas well
hardly recognized.”’'
In the author’s own experiments, various agents were injected at a constant pressure, through the coronaries of fresh,
often
living, hearts of the rabbit and dog. They showed that liquids in these vessels penetrate into the heart cavities still
through the endocardial foramina, thus verifying the foregoing
"Gad:
Archiv
fiir
Physlologie, p. 380, 1886.
Kennedy: ISO?” ^
All Italics are our own.
Journal of Experimental Medicine, vol.
11,
p.
13,
TUB DYNAMICS OF CARDIAC ACTION.
424
As the cannula was tied directly into the artery, the liquid could only reach the cavities through the foramina, while in all experiments care was taken to avoid high pressures. In data.
the heart of the ox the endocardial depressions were found ‘h’egularly larger in the auricles than in the ventricles,” while
in the right auricle “they
may,” he
states,
“be provided with
thin, single valves, especially about the origin of the great veins/'
In the
left
auricle the depressions are fewer in
number and
unprovided with valves.
“Iforamina Thebesii are never absent from the ventricles" says Dr. Pratt. “In the right ventricle,
which
especially well provided with them, the larger number upon the septal wall. It is often much more difficult them in the left ventricle, although a diligent search is
is
are seen to find
never
without
a
reward”
.
.
these ventricular foramina, which office
of valves I have not seen.”
“structures,
.
.
of the vessels of Thebesius with air by
applied
to
foramina,
the
ramifications,
accessory
might in any way .
.
“On
means
characteristic,
to
serve the
the injection
of the blow-pipe
fine,
which very frequently conduct the
subendocardial air into other
Thebesian systems, or even into the great coronary veins will seldom
fail to
appear.”
The
latter point is also sustained
by
experimental evidence.
The fact that the right side of the heart is endowed with a more perfect system of canalization than the left is suggested by the following remarks: “The ease with which injections of air and blood could be made to demonstrate the connection between the vessels of Thebesius and the coronary veins caused me to doubt the opinion expressed by Danger that the foramina Thebesii in the ventricles communicate tvith the veins by capvlTo settle this point, I injected the coronary veins laries alone. of the ox with starch and celloidin masses, both too thick to pass the capillaries, and found that even these emerged from So intimate a the foramina Thebesii of the right ventricle. connection, however, betv'een the coronary veins and the ves-
I have not yet been able to, demon“By means of a very successful strate.’’ 4’he author also says corrosion preparation, made bj’^ injecting the veins of an oxsels
entering the
left ventricle
:
heart with celloidin, I was able to traee the communication. In this preparation the position of some of the foramina
425
THE ADRENAL SECRETION AND THE HEART. Thebesii was
marked by small
disks
of
hardened mass
the
formed by the oozing out of the celloidin upon the endocardium. These foramina were shown to be connected with the
The
smaller coronary veins by fine branches.
still
finer
rami-
Langer has demonstrated, lead from the
which, as foramina and branch directly into capillaries were here uninjected; they would appear only when injected from the forafications
mina themselves.” The only connection between the the coronary arteries that
attempts,
peated
was by
he could
vessels of find,
capillaries.
Thebesius and
notwithstanding re-
Bochdalek having ob-
served that the foramina of one auricle communicated with those of the other, he was able by blow-pipe injection to verify the correctness of this view, the air of one auricle having passed
out through a similar exit into the other.
To
sustain his view that the nutrition of the heart
be carried through the vessels
the coronary arteries are absolutely obliterated, a
experiments are related. tricle of
may
of Thebesius some time after
number
of
Thus, fiuid introduced into the ven-
an isolated heart, by means of a cannula passed down
and tightly held in
by a ligature passed around the auriculo-ventricular groove, only found its way through the vessels of Thebesius. Defibrinated blood, inserted into the organ through this cannula, brought on, often within one minute, “strongly marked, co-ordinated contraction of the ventricle.” As the blood thus introduced would become venous, the action would become gradually reduced, but renewal of the blood would at once cause the heart to resume its normal action. “With a periodic supply of blood,” says the author, “and with favorable temperature and moisture this may conto this cavity,
tinue
s-itu
That mere mechanical stimulation by phenomena witnessed is demonby the alternate use of Einger’s solution and defibrin-
several
hours.”
distension did not cause the strated
ated blood.
While the solution failed to sustain contractions, blood always succeeded. Another experiment served to demonstrate that a true circulation could take place between the vessels of Thebesius
and the coronary veins. The organ being disposed as stated above, two of the coronary veins were incised; “a small, but
THE DYNAMICS OF CARDIAC ACTION.
42G
steady, stream of venous blood issued
from them.” Under the same conditions the descending branch of the left coronary artery was opened. “No flow of blood occurred from the artery, although there was a free escape from an incision in an accompanying vein.” In still another experiment the trunks of both coronary arteries were ligated and the ligature around “The supply-cannula was tied into the ventricle through the oarta. On the introduction of blood
the ventricles omitted.
the left ventricle alone began to beat strongly and regularly the blood found its way in part into the right ven.
.
.
coming of necessity through the walls. . .” The blood from the left ventricle had thus found its W'ay into the tricle,
.
right one.
Finally, he refers to the striking analogy which
this nutritional system presents to that of the frog
and cat. In the frog the heart is almost entirely nourished “through the branching passages that carry tlie blood from the interior of the heart nearly to the pericardial surface.”
On
the strength of
all
this evidence. Dr.
Pratt concludes
(giving only the features that bear directly upon the question
we
are analyzing)
“1.
that:
The
vessels
of Thebesius open
from the ventricles and auricles into a system of fine branches commimicate with the coronary arteries and veins by means of capillaries, and with the veins but not with the arteries by passages of somewhat larger size. 2. These vessels are capable of bringing from the ventricular cavities to the that
—
—
heart-muscle sufficient nutriment to maintain long-continued,
rhythmic contractions.
3.
The heart may
also
nourished by means of a flow of blood from into
the
coronary sinus and
trition
auricle back
The author
veins.”
with the very appropriate remark:
tlie
be effeetively
“It
is
concludes
evident that the nu-
through the vessels of Thebesius and the coronary veins
must modify
no slight degree the existing views of the nutrition of the mammalian heart, and of the manner in which in
infarction of the heart takes place.”
The
clinical features of
this question will be considered elsewhere.
Viewed from my standpoint, the more concerned with the dynamics of nutrition
t>f
this organ,
though the
vessels of Thehesins are
the heart than with the
latter function is not to be
ignored, particularly in the sense emphasized by Pratt:
i.e.,
—
—
THE ADRENAL SECRETION AND THE HEART.
427
as a source of compensation.
auricle result
That nutrition
of the left heart,
and ventricle, constantly filled with arterial blood, can from a flow of the latter through the Thebesian vessels
but nutrition can hardly be associated with a similar process in the right heart, with nothing but venous That nublood to propel through the Thebesian channels. seems
clear,
the recognized prerogative of arterial blood, owing to
trition, its
oxygen, cannot be the active factor here
is
evident.
The right heart seems, judging from the anatomical arrangement of the parts concerned in the process, to play a physiological function of a special kind.
While the Thebesian
openings are larger in the auricles than in the ventricles, in the left auricle they are also fewer than in the right; but even
more suggestive
the fact that, while some openings in the
is
right auricle are supplied with valves, none have been
foramina
;
the right ventricle
them, while they are septal wall should
found
Again, both ventricles are supplied with
in those of the left.
is
particularly well provided with
difficult to find in
the left one.
That the
show them most clearly on the right side
is
Evidently a similar eondition exists between as suggested by Bochdalek and confirmed by
also suggestive.
the
auricles,
Pratt; but the fact that limited information supplied by works
on
anatomy usually covers only those of the right auricle to greater prominence of the latter. Thus, Gray'*
points states
that the venae Thebesii open “on the inner surface of
the right auricle.”
Finally, the openings supplied with valves
are in the right auricle, as stated
to
be most
great vessels; hence
we have seen; but they
conspicuous it
in
the
neighborhood
are also of
tlie
must only be the Thebesian openings
—
around the great vessels of the right auricle ^the venae cavae and the pulmonary artery that are provided with valves.
—
If
we can now
ascertain whether the current
which enters the Thebesian vessels from the right auricle is shut out in this location, or secured within the channels, according to the manner in which the valves close, i.e., inwardly or outwardly,
we
will be able to decide
Gray;
“Anatomy;”
whether venous blood from the venae
edition, 1901, p. 622.
— THE DYNAMICS OF CARDIAC ACTION.
42-
sizes
this fact.
Haller,
stances flowed out freely
who had
observed that injected sub-
from the surfaces of both states that “the passage from the arteries into the the left side is more difficult.”
ventricles,
cavities of
THE DYNAMICS OF CARDIAC ACTION.
430
All these features seem fully to supply the needs of the
function with which the secretion of
the
suprarenal glands
must be connected, if the phenomena witnessed in many disorders and after the use of most remedies have been correctly interpreted. That we are in the presence of a dual process of which the suprarenal secretion, operating in the right heart, and the arterialized blood in the left heart are active factors seems probable. Again, the marked power of arterial blood
—or
— used—
rather of plasma
through cotton was
when only poured tainly
deiibrinated
blood
to sustain functional
into the ventricles, as
filtered
even
activit}',
shoMm by
must alone be
that the blood
indicates
life, to
the
since
Pratt, cer-
able,
during
compensate, in case of need, for insufficiency of blood
furnished by the coronary arteries.
The assisted
contractions of the left heart seem to
by the
blood that enters
arterial
it,
me
to be greatly
and mainly by
The experiments
that Avhich enters the cavities themselves.
shown that contraction could be produced by
of Pratt having
contact with arterialized blood, the arrival into the auricle of a normal quantity of this fluid
must be
fully capable, there-
The
fore, of causing contraction of the walls of that cavity.
and the .mechanism involved The main structures upon which are in all probability as follows the arterial blood reacts are (1) the musculi pectinati and (2) the sinus venosus and appendix auriculie, all of which are so relations of the several structures :
disposed as to offer as
much
I’he walls of the cavities
surface as possible to the blood.
mentioned are provided with numer-
ous channels, the Thebesian “veins,” to satisfy this purpose.
The blood which
enters the auricle
when
it
is
dilated pene-
trates all the circuitous areas around the musculi pectinati
and
into the Thebesian vessels, and the ensuing contraction forces
the blood-plasma into the smaller subdivisions of these vessels,
from which they
find their
way
into the auricular veins.
When
the arterial blood reaches the ventricle, a process similar to the
preceding occurs. offer
The columnas
carneiu are disposed so as to
considerable surface to the blood, while the ventricular
walls are permeated with Thebesian channels, into which the
blood
penetrates
closes the
during
diastole.
The
contraction
induced
apertures of these channels, and forces the blood-
431
THE ADRENAL SECRETION AND THE HEART. plasma into their smaller ramifications and
The
veins.
the latter.
finally
into
the
larger channels carry the corpuscular elements to The role of the coronary arteries will be referred
to later on.
The activity cavities
right heart, as I view the process, owes its frmctional mainly to the suprarenal secretion brought to the I have sufficiently emphasized by the vena cava.
the power of this agent to restore cardiac action it
when
even
manner
in which it exercises its powers
On
the arterial blood on the left side.
The
similar to that of
is
penetrating the auricle
the contractile structures are submitted to fects;
and sustain
the entire spinal cord has been obliterated.
but the
orifices of the
more numerous and
its
immediate
ef-
Thebesian vessels or channels are
larger than in the left auricle.
The mem-
branous edges previously referred to as valves by the investigators quoted do not appear to
me
to merit being considered
such after careful examination of these structures in the
as
The
'ox-heart.
aperture being closed by the least squeezing of
the tissues containing them, it seems evident that' they should as readily close
larger
under the powerful contraction of the auric-
The
ular tissues.
number
of
right ventricle also presents a very
Thebesian
orifices
than the
left,
much
while
its
though thinner, plainly show the ramifications of these channels. That the venous blood charged with suprarenal se-
walls,
when the
cretion should at once penetrate the latter
begins to contract
is
self-evident.
circulation is effected in the left
heart
but,
:
i.e.,
The whole as we shall
Eetum
same way
ventricle
of the blood to the
as in the case of the
through the coronary veins. process
is
an exceedingly uncomplicated one,
see later on, it simplifies
many
obscure prob-
lems, while affording, in connection with the coronary arterial blood, a supply in keeping' with the vital importance of the
organ
itself.
Again, Dr. Pratt’s experiment, in which blood
injected into the left auricle flowed freely tricle,
need.
from the right ven-
emphasized the possibility of compensation in case of Thus, while under normal conditions, the pressure in
both
—
ventricles must be equal, reduced contraction of the right ventricle, for example through insufficiency of the adrenals would automatically cause the arrival into it, through
—
THE DYNAMICS OF CARDIAC ACTION.
432
the Thebesian foramina of the seiitum, of at least some arterial
That
blood.
does not alwaj's suffiee to maintain inter-
this
ventricular equilibrium, however,
is illustrated by the dicrotic and kindred phenomena. connection are the remarks of Professor
pulse, the pulsus paradoxus,
Suggestive in this
Porter in his review of the subject of cardiac innervation in the “American Text-book of Physiology”®:
“A
positive
dem-
onstration that the nerve-cells in the heart are not essential to its contractions,” says this observer, “is secured
by removing the tip of the ventricle of the dog’s heart and supplying it with warm defibrinated blood through a cannula tied into nutrient artery.
its
Long-continued, rhythmical, spontaneous
contractions are thus obtained (Porter'®).
contains
no
arise in the
nerve-cells,
muscular
assumption
safe
pulses
the
the
the part removed
can
contractions
only
provided we make the (at present)
tissue,
that
observed
As
do
nerve-fibers
not
originate
im-
capable of inducing rhythmic muscular contractions.”
apply —and may be elements including those the muscular and — cardiac muscle endowed
In other words,
said to
this
muscular
coats of the stomach
of
intestines,
to all
the
is
with the in-
herent power to contract, even small detached pieces, when placed in appropriate media being capable of doing body, indeed, this contractile power active,
and Porter remarks
of our views:
—almost
“The demonstration
is
In the
so.
merely, so to say, kept
prophetically in the light
that the nerve-cells are not
essential to contraction places us one step nearer the true cause
of contraction. stance.^^
It
Evidence
is
some agency acting on the
is
contractile sub-
accumulating that this agent
ical substance, or substances,
is
a chem-
brought to the contractile matter
by the the blood.”
That the “chemical substance brought
to the
contractile
matter b)^ the blood” is represented by the adrenal secretion and the oxidizing substance seems clear. Brown-Sequard over fifty so7tie
years ago urged that the inferior vena cava contained undetermined substance which contributed to the heart’s
d'V'namism.
“
of Physiology.” second edition, 1900. Journal of Experimental Medicine, vol. 11, p. 391, 1897. All Italics are our own.
Porter: Porter:
“American Text-book
THE ADRENAL SECRETION AND THE HEART.
433
THE ACTION OF THE ADEENAL SECRETION AND THE OXIDIZING SUBSTANCE UPON THE CARDIAC MUSCLE. The
histology of the
conjecture,
for
which
it
of
Its
these:
briefly
tissue is
projections.
lateral
broad
field
to
investigations
The known composed, in man, of observers.
of striated fibers, possessed
fasciculi, or bundles,
round
thick
many
the
notwithstanding
offers a
still
has been submitted by modern
facts .are short,
niyocardmm
The
directly
latter
connecting
with a similar projection of the adjoining bundles and being cemented to it, a thick close-meshed net-work is formed: a
But
characteristic of the heart-muscle.
muscles in several other particulars; smaller and their
sarcolemma and of
any
the
fluid that
contractile
peculiar:
strise
are
much more
are, therefore,
each bundle
is
are
differs
fibers
faint;
from other
are one-third
they possess no
exposed to the immediate action
may surround
structures
it
its
them.
The manner
combined in bundles
made up
which
in
is
also
of central prismatic fasciculi
round fibers, in which nuclei (one or two) with their surrounding protoplasmic area are imbedded, the whole being surrounded with flat or ribbon-like columns of muscle-fibers. The perinuclear protoplasm referred to generally contains fatdroplets and minute pigment-granules which resemble hremoglobin, and sends projections between the surrounding musof
cular fibers so that each of the latter
is
connected with and
only separated from
its neighbor by a layer of protoplasm. This arrangement does not in any way modify the manner in which the sarcous elements are disposed, while the disks, clear is
spaces, etc., are precisely as they are elsewhere in the organ-
These muscular “primary” bundles form, by their union with one or two of their neighbors, columns, or chains or “secondary” bundles, which are covered, as shown by Eanvier, ism.
—
with a sheath of loose connective-tissue cells, which cells, in turn, connect with one another by numerous projections, or extensions.
The primary
tissue sheaths
fasciculi
also
contain
connective-
which invest the muscle-fibers and are likewise supplied with connective-tissue cells. All this forms a close, though permeable, net-work, which makes it possible for a liquid to penetrate the muscular columns or chains and come into direct contact with the bare, or exposed, muscle-fiber.
— THE DYNAMICS OP CARDIAC ACTION.
434 Indeed,
the
intimate
structure
of
the
cisely supplies the required structure for the
myocardium preequable and free
distribution of such an agency as the suprarenal secretion rep-
Fluids can penetrate through the maze of cellular
resents.
muscular
tissue to the bare
the sheaths that include
fibers;
the columns or chains of muscular bundles afford a peculiar
system of canalization through which the liquids can easily gain access to them.
These canals
—the
lacunae of Henle
are the intervals between the columns of secondary bundles, or their sheaths, rather, which are placed in longitudinal apposiSell weigger- Seidel
tion.
injections
interstitial
lymphatic
and Eanvier having observed that colored
of
vessels, the lacunas
substances
penetrated
the
have been considered as adjuncts,
or extensions, of the latter.
Eenaut,^' however, concluded that the penetration of the colored
weak
fluids
the lymphatics merely
into
demonstrated the
resistance of the endothelial coat of the latter,
and the
Henle being unprovided with endothelial ground for the prevailing belief that they walls, there was no He found that all the lymrepresented lymphatic vessels. phatic capillaries of the myocardium are located on the surface They are large and of the heart underneath the pericardium. bosselated and form a mesh-work which covers the whole cardiac surface, and send smaller blind pouches into the muscular spaces, or lacunae, of
The
interstices.
spaces
of
Henle should be considered, he
thinks, “not as true lymphatic cavities analogous to those ob-
served aroimd the pulmonaiy lobules of certain animals, but as mere connective-tissue spaces, which represent, in fact,
pathways for lymph.” In a foot-note Berdal spaces of Henle are crossed by “vessels,” and
states that the
in the text the
following remark as to the identity of this lymph appears: “The muscular fibers of the heart are thus bathed in conspaces
nective-tissue this luit
plasma.
to
lymph
easily
circulates;
but
is
state
Still,
"Renaut: 825.
which
not that of the l^unphatic vessels or capillaries, It is that of loose connective-tissue spaces (Eenaut).”
lymph
needless
p.
in
we
that
this
suggests
the
presence
of
blood-
can only consider this deduction as tentative.
Traitfi d'HistoIogie pratique, p. T19;
quoted by Dcrdal,
lor.
cU.,
THE ADRENAL SECRETION AND THE HEART.
The manner or arterial,
is
in which the blood-plasnxa, whether venous
distributed by the Thebesian channels
The
Meigs.^*
is
well
by Arthur Y.
in a study of the vessels of the heart
shown
435
extreme paucity of literature on the Thebesian
channels has caused them to be overlooked by practically
all
histologists; that they should be treated as capillaries in the
author^s paper to
do
so.
is,
“The
therefore, as capillaries
normal
of the
as it is for text-books
human
heart,” says
Dr.
Meigs, “differ in two ways from those of other parts of the
and some of them are larger than those found elsewhere, and of different arrangement. The accompanying illustrations are drawings which were made with the camera lucida. They are from sections of two human hearts. The first is from the heart of body:
they penetrate the muscular
.
a negro
.
fibers,
.
woman, 40 years
old,
who
died of burns.
Some
pieces
were preserved in Fleming’s solution, and others in 70-per-cent, alcohol, and they were stained in bulk with of the organ
borax-carmine and imbedded in paraffin. that of a man, 30 years old,
When still
who
The second heart
is
died of lead encephalopathy.
the post-mortem examination was made, the heart being
was injected through each of the two much as the blood-vessels would easily
quite fresh, there
coronary arteries as
receive of a solution of 3
grammes
in 600 cubic centimeters of water.
of Berlin blue (Grubler’s)
Pieces of the organ of
suitable size were at once placed in preservative fluid,
70-per-cent, alcohol,
and others in formaldehyde
some in
solution.
The
was afterward stained in bulk with borax-carmine and imbedded in paraffin.
tissue
“The penetration of the muscular fibers by the capillaries made perfectly clear by the illustrations; it is shown as well by the injected -as by the uninjected heart. The two methods
is
of demonstration
supplement one another, because, in injected which has been stained, the blood-vessels and their situation are made very obvious by the contrast of color, but the
tissue
details of the structure of the walls are obscured by the injection material, while, on the other hand, in the uninjeeted tissue,
the structure of the blood-vessels can be seen with the utmost distinctness.
” Arthur
In Figs.
V. Meigs:
1 to 4 the capillaries are easily recog-
Journal of Anatomy and Physiology, Jan., 28
1899.
—
THE DYNAMICS OF CARDIAC ACTION.
436
Their situations in relation to the muscular
nized.
very
varied.
Some
are
in
the
intermuscular
slightly indent the sides of the fibers;
still
fibers are
fibers,
others
others are within
the fibers close to their periplieries, and sometimes the capillaries are in the very centers of the fibers. This penetration of the muscular fibers of the
human
DESCRIPTION OF
DR.
heart in the adult
is
a
most
MEICS’S PLATE.
The amplification has been reduced about one-third
in the reproduc-
tion herein presented. “Fig. 1.—X 420. From a man, 30 years old, who died of lead encephalopA section of papiilary muscle of the heart cut across the fibers, bb are Injected capillaries, the one partially and the other entirely within the muscular fibers, c, A capillary which remains unlnjected; its nucleus is included. “Fig. 2.— X 420. From the same tissue as Fig. 1. v, A vein stained by the injection material, bb. Capillaries whose precise situation cannot be defined. They cannot be said to be intermuscular spaces, nor to be entirely within fibers. The effect is as if the fibers were coalescing. “Fig. 3. X 420. From the same tissue as Fig. 1. in a f. A capillary fiber, This is perhaps the g, A capillary in the center of a very small fiber. most convincing instance of the penetration of a muscular fiber by a capillary. “Fig. 4. X 420. A section of heart cut transversely to the muscular fibers, from a negro woman, 40 years old, who died of burns. The muscular fibers are of irregular shape, d, A capillary within a muscular fiber, its nucleus upon one side producing a resemblance to a seal ring, e, A capillary within a muscular fiber, its nucleus being Included, It f, A capillary in an intermuscular space; resembles a seal ring, g, A capillary in an intermuscular space; its endothelial wall appears as a simple circle. “Fig. 5. X 115. From the same tissue as Fig. 4. A large capillary, receiving many branches and surrounded by muscular tissue. The capillary and its branches are almost filled with blood-corpuscles. The capillary walls are distinctly visible, containing many flattened endothelial nuclei. Not printed in two “Fig. 6. X 42. From the same tissue as Fig. 1. colors, because the essentials show equally well in black, m, Muscular tissue. a. An arteriole; the solid black within its caliber is injection material, v, The accompanying vein to the arteriole, a; it also contained a little of the Injection material; these two vessels are in a connective-tissue interspace, c, A large capillary; it contains a good deal of the blue injection material, which Is repathy.
resented by the heavily-shaded portions. These three vessels— arteriole, vein, and capillary— give a good idea of the character of such vessels in the heart The great size of the capillary is the most striking feature.”
striking
and curious phenomenon, and
it
docs not exist at an
early embryological stage.
Tlie condition
later development,
not yet Icnown at
it
but
it is
is.
therefore, one of
how
early an age
does exist
“Very
large capillaries are found in the
such vessels are shown by find
minute veins
in
Figs. 5
and
company with the
G.
human
It is not
heart, and
common
to
arterioles in the deepest
Fig. 1 Fig: S.
Fig.
Fig.
3
Fig.
CIRCULATIDN
DP'
THE HUMAN HEART,
[Journal of Analomi/ and Physiology.']
g.
6.
[Arthur U, MBigs.]
f
>
V < i
1
437
THE ADRENAL SECRETION AND THE HEART.
is portions of the muscular substance of the heart, although it connective-tissue the and in well known that, upon the surface
found with their vena; comites, just as they are in other organs and tissues. The arrangement of the in marked vessels upon the surface and in the interstices is contrast with that found in the muscular substance proper. Here, when an arteriole is accompanied by an efferent vessel, interstices, arteries are
and composed of endothelium, being exactly like the smallest capillaries, except in size. These peculiar large capillaries are found not only in company with arterioles, and, therefore, when carrying on the function usually
this vessel is single coated
performed by veins, but also alone. When they are alone, it is impossible rto be certain whether their function was afferent oi-
It
efferent.
may
well be that arterioles are less
numerous
and that their place is taken numerous and they perform the fimction of
in the heart than in other tissues,
by the large
These
capillaries.
capillaries are so
of such size that it seems likely
The presence
reservoirs. •
of the large capillaries and the pene-
tration of the .muscular fibers
by the
capillaries indicate a pro-
vision for the blood-supply of the heart even
more bountiful
than that of the other organs.”
That
these vessels are the Thebesian channels is evident;
mode
and the peculiar endings of their subdivisions is particularly well shown in Fig. G, while the outpouring of plasma for absorption by the muscle-elements is
their
of distribution
suggested by Fig.
The is
5.
fact that the distribution of the Thebesian channels
analogous to that observed in the heart of the frog has,
have seen, been noted by Pratt.
by Lannelongue, but
This had
also
been noticed
this author considered the channels of the
human myocardium as dal, who alludes to the
vestiges of the batrachian system. latter, states that
penetrates
intercejit
and
Ber-
in the frog and in the
batrachian nrodda there are no ordinary blood-vessels.
muscular fasciculi
we
“The
cavernous spaces into which the blood
fmm
which they are only separated frog’s heart is thus a true sponge the structures of xohich, formed of muscular fibers, nourish themselves hy inihihiUort,. In mammals, on the contrary, the myocardium contains distinct vessels. The capillaries form a net-work the directly
by endothelium.
The
THE DYNAMICS OF CARDIAC ACTION.
438
meshes of which, elongated and parallel to the muscular fasciculi, are connected by short branches, which give each mesh the appearance of a parallelogram. When these vessels cross the spaces of Henle, they are covered, on the external surface, with flat connective-tissue plates.” Pratt’s observation not only includes the analogy between the
human lung and that of the mammal. Under these
frog, but also with that of the cat, a
becomes clear that in man, also, the heart-muscle he regarded as a sponge-like structure, the contractile ele-
conditions,
may
it
ments
of which are nourished and supplied with working energy by substances in the blood-plasma.
What
is
the role of the blood of the coronary arteries in
the functions of the heart?
This
may
perhaps be traced by
analyzing the effects of ligation of those arteries upon these functions.
Porter^^ refers as follows to the experimental
in this connection
“The frequency
:
work
of arrest after ligation
is
in proportion to the size of the artery ligated, and hence to the size of the area
made amemic, and
is
not in proportion to the
injury done in the preparation of the artery.
The
and descendens may be prepared without injuring cle-fiber,
circumflex
q single
mus-
yet their ligation frequently arrests the heart, while
the ligation of the arteria septi, which cannot be prepared with-
out injuring the muscle-substance, does not arrest the heart. It
is,
moreover, possible to close a coronary artery without me-
chanical
Lycopodium-spores mixed with defibrinated
injury.
blood are injected into the arch of the aorta during the mo-
mentary closure of that arteries
:
the only
spores plug
way
up the
and are carried into the coronary open for the blood. The lycopodium-
vessel
left
finer branches of the coronary vessels.
The
coronary arteries are thus closed without the operator having Prompt arrest, with tumultuous fibrillary touched the heart. contraction, follows.”
If the plasma that reaches the heart by sian channels can sustain both
its
way
of the Thebe-
nutrition and its contractions,
accounted for? The sudden the coronary arteries plugging arrest of the heart’s action by certainly points to a predominating function, and, more than
how can such
tliis,
results as these
to a function of Porter:
Loc.
cit.
lie
which they are alone the sources of blood-
THE ADRENAL SECRETION AND THE HEART. Tliat the role of the coronary blood
supply.
is
439
precisely that
which obtains elsewhere in the organism is forcibly suggested by the experiments of Langendorff, who was able, according to Porter, “by circulating warmed oxygenated dcfibrinated blood through the coronary
and dogs in
cats,
vessels, to
maintain the hearts of rabbits,
activity after their total extirpation
from the
It is clear that the blood-plasma can incite functional
body.”
when introduced through the coronaries as well as when introduced into the ventricles. “Even pieces removed from the activity
ventricle will contract for hours,” continues the author, “if fed
with blood through a cannula in the branch of the coronary artery which supplies
them (PorteP®).
It is evident, therefore,
that the cause of the rhythmic beat of the heart lies within the
and not within the central nervous system.” words represent precisely the factor of the problem which must be eliminated .to enable us to differentiate the role of the coronary plasma from that of the Thebesian heart
itself,
The
italicized
plasma, for blood will not alone induce contraction of the cardiac walls; almost any irritant will under appropriate conditions.
Indeed, in the latter case
it will sometimes undergo conwithout any external irritation; thus, “a strip of muscle cut from the apex of the tortoise ventricle and suspended in a moist chamber begins in a few hours to beat apparently
tractions
own accord with a regular, but slow, rhythm, which has been seen to continue as long as thirty hours. If the strip is of its
cut into pieces and placed on moistened glass slides, each piece will contract rhythmically. Yet in the apex of the heart no '
nerve-cells have been
contract
is
inherent
found” (Porter). in.
the contractile
Hence the power tissues, and subject,
to
as
elsewhere in the organism, to exacerbations of activity under appropriate stimulus. This fact being now established, our in-
quiry
is
simplified, since
of the processes through
we need only which
to inquire into the
nature
it is utilized.
Analysis of the requirements of the right heart soon reveals the fact that the muscle-fibers require the same bloodsupply that any muscle of the body does. Indeed, we then realize that the coronary arteries are their only source of oxy-
Porter:
Journal of Experimental Medicine, vol.
il,
p. 391,
1897.
— THE DYNAMICS OF CARDIAC ACTION.
440
The venous blood
gen.
roaches
tliat
through the Thebesian
it
cliannols has been dejileted of this gas
by the rest of the organism, and the suprarenal secretion, owing to its marked avidity for it, must, while in transit through the inferior vena cava, have deprived it of the little that might have remained
We
in loose combination.
have reviewed the ultimate distribu-
tion of the coronary arteries as given by Berdal.
from that of other text-books.
differ
It does not
These generally concur
in stating that the larger branches are distributed to the con-
nective tissue between the
large
fasciculi,
and once
tlierein
divide into arterioles, which, in turn, subdivide into capillaries
“The capillaries myocardium are very numerous,” say Bblim and von Uavidotf, “and so closely placed around the muscle-bundles that that entwine the primary muscle-fasciculi. of the
each muscular fiber comes in contact with one or .more capil-
Do
laries.”
with
fiber
its
they serve here, as elsewhere, to supply the musclesource of energy
—
i.e.,
the carbohydrates that enter
into the formation of the myosinogen
cisely
furnishing the
^besides
which sustains the combustion processes
substance
oxidizing
when brought
—
into contact with this- myosinogen
This
?
is
pre-
where a difference between the muscular functions of the
heart and those of other muscular structures appears to us to exist.
There
when we
is jiractically
consider that
fourths of a sound
;
no passive period in the
its
heart’s action
stage of octMtij recurs every three-
and the formation of mj'osinogen
contractile elements, were
it to
proceed as slowlj' as
it
in its
does else-
Still, if the coronary where, would seem totally inadequate. blood is not endowed with the mission of supplying the heart-
muscle with
its
source of energy,
are relegated to the venous
we
blood of the Thebesian vessels and
its
the myosinogen-forming products.
ergy
suggests
known
to react
present in the
itself
when we
under the hepatic
A
suprarenal secretion for source
possible
consider
that
a
of
en-
carbohydrate
effects of the oxidizing substance is
veins,
i.e.,
dextrose,
—and
that
this
sugar must pass through the right heart. As is well known, That these veins carry their sugar to the inferior vena cava. it is not used by the heart, however, was shown by a careful analysis of the whole question.
This
is
submitted in the twelfth
— 441
THE SOURCES OF THE HEART'S ENERGY.
For reasons submitted in the second volume I was on page 433 led to conclude that the minute granules referred to intermediary the through were actually supplied to the heart the liver of leucocytes. These cells were found to migrate from where cava, vena inferior the veins) to (also through the hepatic cliapter.
they meet the adrenal secretion and proceed with it to the The evidence seems incontrovertible. The right ventricle. subject is so far-reaching, however, that it had to be considered separately.
I
for the present only, refer to these
shall,
granulations as “granules (3” (Ehrlich). to
We now
have,
it
seems
me, the elements necessary to account for the functional phewitnessed, namely
nomena
:
The adrenal secretion, to contract the right auricle and ventricle and thus insure the penetration of the Thehesian Mood 1.
into the cardiac walls
(which contraction venous blood or
its
would not cause).
contained granules
account for the unusual and continuous production of energy which the heart converts into worh. 3. A continuous supply of oxidizirig substance via the coro2.
The granules
nary arteries
to
to insure the
combustion processes through which
this energy is liberated.
The annexed
colored plate shows the
adrenal secretion and the granules
f3
manner
in
which the
simultaneously reach the
right auricle.
We
can
now understand why plugging
of
the coronary
by Porter, arrest cardiac action. Referring to the effects of embolism and thrombosis of these “That part of the heartarteries, this investigator also says: wall supplied by the stopped artery speedily decays. The bloodless area is of a dull-white color, often faintly tinged with
arteries should, as stated
yellow; rarely
it is
red, being stained l)y hcemoglobin
neighboring capillaries.
The The
The
from the
cross-section is coarsely granular.
power of staining. and connective tissue soon replaces of funetion and rapid decay of cardiac tissue
nuclei of the muscle-cells have lost their muscle-cells are dead,
tliem.
This
loss
would not take place did anastomosis permit the estaldishment of collateral circulation between the artery going to the part and neighboring arteries. The objection that one of .
.
.
the coronary arteries can be injected
from another, and
that.
— THE DYNAMICS OF CARDIAC
442 tlicrefore,
they are
not
terminal,
is
ACTION.
based on the incorrect
in-emise that terminal arteries cannot be thus injected, and has no weight against the positive evidence of the complete failure of nutrition following closure.” As 1 interpret the process, the absence of anastomosis further suggests the exist-
ence of an additional source of energy; but the cardiac arrest after ligation of the coronary also indicates that compensation
from the opposite heart can only be gradually
On
established.
the whole, the coronaries of the right side are as important as if they alone supplied the needs of the functions of that
The granules ji and the adrenal secretion are furnished to compensate for the absence of arterial blood in the right auriculo-ventricular cavities and in their Thebesian channels; but, side.
the right coronaries being the only source of one of the three necessary factors
much
of the process,
We
why
can also understand
the primary fasciculi are bare. in
their obliteration
means
as
as that &f the left coronaries does to the left heart.
the contractile elements of
They
are
constantly bathed
from which they obtain the granules /? that the formation of their myosinogen. The absence
the plasma
enter into
of oxygen in this fluid renders delicate structures
perfectly harmless to the
it
that surround the primary and secondary
bundles of muscle-flber, and to the net-works of arterial capillaries that
hug the bare
—which
tion,
fibers.
The
latter,
by a rapid absorp-
the presence of sarcolemma would counteract, i.e., forming their products of metabolism The arterial capillaries, “coated, on their exter-
constantly
are
myosinogen.
:
nal surface, with
flat
connective-tissue cells”
(Berdal),
when
they cross the spaces of Henle, being the only carriers of oxygen, normally become the active factors of nutrition and function.
Their blood
is
—
the normal excitant
venous blood brings the granules
P
contracting the cardiac walls, forces nels; the bare muscle-fibers
them
into their
own
absorb
;
it
into the Thebesian chan-
the granules and convert
particular kind of fuel, myosinogen; the
capillary blood supplies the energy for this metabolism
gen
—and
The
as elsewhere.
the adrenal secretions, by
simultaneously sustains, again with
its
—
o.xy-
oxygon, the
combustion processes ujion whicb the continuous work of the Here, as elsewhere, the potential energy of organ depends.
443
THE SOURCES OP THE HEART’S ENERGY.
chemical agencies present becomes converted into mechanical energy, which manifests itself as visible motion. tlie
The
—the coronaries —presents anatomical
of which are larger than
heart
left
features which modify,
those of the right
manner in which its physiological functions Both its auricle and ventricle containing arte-
in a measure, the
are performed.
blood fresh from the heart, the Thebesian circulation does
rial
not appear to
fulfill
the primary role
does in the right heart.
it
Indeed, the various experiments of Pratt and his predecessors
and my own careful examination of the ox-heart distinctly show that the Thebesian circulation of the left heart, as regards intraventricular orifices, is much less important than that of the right heart.
Still,
the evident permeability of the inter-
myocardium material aid from the
ventricular sei)tum and the histology of the left
must
suggest that the left heart
adrenal secretion and
its
receive
granules p.
This feature will again
be referred to in the twelfth chapter.
A
may
feature that
common
be considered as demonstrated, and
to both sides, is the return of the blood,
source be the Thebesian or coronary systems, by
coronary veins.
We
whether
way
its
of the
have seen that Langer expressed the opin-
ion “that the foramina Thebesii in the ventricles communicate
with the veins by capillaries alone.”
My
conception of the
process involved would necessitate such an arrangement as re-
gards the right heart.
Indeed, so direct is this connection that even such viscid substances as starch and celloidin were found by Pratt, when introduced into the coronary veins of the ox,
emerge from the foramina Thebesii. Still, we could hardly expect such a free transit on the left side of the organ, inasmuch as the presence here of arterial blood only would suggest the presence of a structural organization similar to that of ordito
nary muscles.
Indeed, referring to the vascular connections
of the left heart, Pratt says;
“So intimate
a connection,
how-
between the coronary veins and the vessels entering the ventricle I have not yet been able to demonstrate.” Again,
ever, left
on the right
side the connection with coronarj'’ veins must evidently be a physiological one, since “a small, but steady, stream
of venous blood issued
from them” when the veins were incised had been filled with defibrinated blood.
after the right ventriele
:
THE DYNAMICS OF CARDIAC ACTION.
444
But “no flow of blood occurred from the artery, although there was a free escape from an incision in an accompanying vein” in an experiment similar to that previously referred to, also performed by Dr, Pratt. In fact, it appears to me very doubtful whether even the capillary communication between coronary arteries and the Thebesian vessels, referred to by the latter observer in his conclusions, at of
tlie
all exists
—
at least in tlie walls
my
Even disregarding
right heart.
views,
seems
it
evi-
dent that the admixture of venous blood with tlie arterial blood would greatly reduce and perhaps annul the functional efficacy of the latter as an oxidizing agent.
We
can now understand how the
An
greatly influences cardiac activity.
adrenal
secretion
increase of
it
so
augments
the force of the contraction, but the heart does not dilate as
promptly nor perhaps as completely; hence its action is slower, but more forcible ; we have seen that this represents the primary effect of all
A
drugs sufficiently active to stimulate the adrenals.
greater quantity of adrenal secretion increases the vio-
still
lence of cardiac action;
luematuria, epistaxis,
the vessels are tense, and ecchymoses,
etc.,
however, in the sense that tinuous
cardiac
may
ensue.
The
its diastole is
stimulation
through
heart acts normallj',
Con-
almost complete.
excessive
production
of
adrenal secretion, due in turn to excessive production of iodothyrin, as in exophthalmic goiter, causes the heart to contract
before
it
has
exhausted
within a narrower
field.
its
complete
diastole
involves increase of oxidizing substance;
correspondingly stimulated.
ciency occurs, the
to
work
Increase of adrenal activity
the type of the “cramped heart.”
is
and
Its contractions are sharp, but rapid
hence the
left heart
When, however, adrenal
phenomena follow an
opposite course;
insuffi-
when
total inhibition of the adrenal system ensues, the vascular walls, the adrenal secretion, the losing all their functional stimuli,
—
and contractions and lapse into
granules
the oxidizing substance,
—gradually
cease their
diastole.
THE INNERVATION OF THE HEART.
We
are again brought, by analysis, to the realization that
the efferent nerves distributed to the heart incite and govern functional activity but contribute nothing to the continuation
MECHANISM
CF CAREIAC ACTICN,
[SaJous.J
1, Inferior Yena Cava, th.e blood of which, contains Hdrenal Secretion. 2, Hepatic Veins, the blood of which contains granules /3 derived from the Liver. 3, Right ilurlole. 4, Cne of the Coronary Arteries. B, Cne S, Cne of the Coronary Veins. of the Foramina ThebesU.
i
— THE INNERVATION OF THE HEART. of vital processes per
445
Indeed, in the heart they do naught
se.
One set of nerves than in other parts of the organism. distributed to the cardiac arteries provokes dilation to increase else
another set causes constriction of these vessels
cardiac activity;
when
cardiac activity
of the heart
is
is
“The
to be reduced.
rich nervous supply
derived from the coronary plexuses"’ says Piersol,
“and includes numerous medullated
fibers
coming from the
pneuniogastric as well as the non-medullated sympathetic fibers
Numerous microscopical
proceeding from the cervical ganglia.
ganglia are found along the course of the large nerve-trunks
accompanying the branches of the coronary arteries, especially in the longitudinal interventricular and in the auriculo-ventricular furrows. cells
Many
additional small groups of ganglion-
occur within the muscular tissue associated with the fibers
supplying the intimate structure.” vailing teachings
the vagus
Briefly, according to pre-
and sympathetic are the nerves
which govern the functions of the heart. Is this true? In the light of my own views, to doubt;
and, precisely as I have shown
the kidneys,
all
it
it is
subject
to be the case
with
the nerves supplied to the heart belong to the
sympathetic system.
Acceleration.
—
Legallois, early last century (1812)
urged
that the nerves which increased the beats of the heart in a given time belonged to the sympathetic system. Although
vigorously attacked by Bezold
and others, this doctrine has and most investigators, including Heidenhain, Langley and Gaskell have accepted Legallois’s view. It becomes a question, however, in the light of my views, whether acceleration represents the motor phase of cardiac steadily gained ground,
—
action,
and therefore, whether or not
sympathetic
That
it
does
fulfills is
the role of motor,
as
i.e.,
in the kidney, the of vasodilator nerve.
shown by the experiments of E. and M. Cyon^®
who found
that occlusion of cardiac vessels did not cause acceleration in other words that it was not by reducing the blood supplied to the heart walls that the accelerators acted
—
upon the
heart. On the other hand, as will be shown under the next heading, constriction of the cardiac arteries, f.e., dimi-
^“E. and M. Cyon:
Archiv
f.
Physiol., 1867.
:
THE DYNAMICS OF CARDIAC ACTION.
44G nution
ol‘
the blood supplied to the cardiac muscle, slows the
Indeed, Eaxt^^ observed a distinct antagonism
heart’s action.
between the vagi in the neck
—owing
shown below
as
to the
—and the
presence of cardiac vasoconstrictor fibers in this nerve accelerators,
when stimulated simultaneously.
The
vagi sup-
pressed the accelerators invariably, in fact, and irrespective of the strength of the current. celeration
is
It is evident, therefore, that ac-
not due to constriction of the cardiac arteries, and
that the S3'mpathetic accelerators
producing dilation of these
The
must
act
upon the heart by
vessels.
vasodilator properties of the accelerators have, in fact,
so legitimate a claim to recognition that in his recently pub-
lished review of our knowledge
“The
marks: to
first
on the subject Carvallo*®
contain vasodilator fibers which almost always cause aug-
mentation of speed.”
He
forcibly illustrates this fact by a
table demonstrating that the vessels so influenced
creased hlood-flow in a given time, are stimulated,
“We may
and
when
closes his review
in-
the accelerator nerves
conclude therefore that the heart possesses a eomplete
essentially
by the
show an
with the following words
vasomotor apparatus the vasoconstrictor it
re-
thoracic ganglion, or stellate ganglion seems
stellate
fibers of
which reach
by way of the vagus, and the vasodilator nerves ganglia [first thoracic] and the annuli of Vieus-
sens.” Briefly,
“acceleration” represents
an exacerbation of ac-
and just as we found such increased activity produced by vasodilation and the admission of an excess of tivity of the heart,
blood, in other organs, so do
Inhibition.
—In
phenomenon should
we
the light of foregoing statements, this
assert itself as a result of excessive con-
striction of the cardiac arteries
plied to the cardiac muscle. itself
from various
The
find it here.
and diminution of the blood supThat such is the case suggests
directions.
inhibitory etfect of excessive constriction of the coro-
beyond question. Chirac'® found that the beats of a dog’s heart were soon arrested when one of the coronaries was
naries
is
”
Baxt: Arb. a. d. phys. Anst., Leipzig. 1875. •“Carvallo: Rlchet’a Dlctlonnalre de Physiol., “Chirac: “De Motu Cordis,” p. 121, 1698.
p.
347,
THE INNERVATION OF THE HEART.
447
Erichsen-® observed a similar result after tying these Leonard Hill-^ referring to the investigations of Cohnvessels. tied.
heim and Schulthess-Eechberg,-- McWilliams,-® Bettelheim,®'* and others, also states that “ligaturing one of the large branches only
frequently
is
to
sufficient
cause
Again,
arrest.'”
See,
Bochefontaine and Eoussy®® observed that substances capable of
plugging the coronaries caused cardiac arrest.
—lycopodium
—
spores, for instance
also
Porter®® plugged the left coronary artery
and says that “the closure of the artery was always promptly followed by arrest.” As the result of closure by ligation in sixty-seven dogs, he reached the deduction that in nineteen dogs
“the frequency of arrest artery
ligated.”
As
is
proportion to the size of the
in
impulses
cardio-inhibitory
transmitted
through the vasoconstrictors of both vagal trunks probably influence all the cardiac arterioles simultaneously,
the
ease
with
which the heart’s action can be arrested by exciting the bulbar center is easily accounted for. Finally Kolster,®^ Porter,®® and others have
shown experimentally that the part of the heart
supplied by an infarcted coronary artery degenerates. Yet,
if
the vasomotor impulses inhibit the heart by causing
excessive constriction of the coronaries effects
and
their offshoots, the
on the heart wall must coincide with those resulting
from deprivation of blood.
Such is undoubtedly the case: E. Weber®® observed that during partial inhibition the cardiac contractions were weakened, while
Schiff®®
found that the mus-
cular elements of the entire organ responded less or not at all to
Prangois-Eranck,
stimuli.
Pischel,®’
and others observed
that the cardiac walls were softer than usual.
Foster®® states
“Erlchsen:
London Hospital Gazette, vol. ii, p. 561. 1842. ^Leonard Hill: Schafer’s “T. B. of Physiol.,” vol. il, p. 1, 1900. “ Cohnheim and Schulthess-Rechberg; Virchow’s Archlv, Bd.
3,
Ixxxv,
H.
S. 503. 1881.
“McWilliam:
“ “
Jour, of Physiol., vol.
vlll, p.
296, 1887.
Bettelhelm; Zeit. f. kiln. Med., Bd. xx. S. 436, 1892. Sde, Bochefontaine and Roussy: C. R. de I’Acad. des
scl.,
T. xcli, p. 86.
1881.
“ Porter; Jour, of Exper. Med., vol. I, p. 46, 1896. ” Kolster: Skandlnav. Archlv f. Physiol., Bd. iv, p. 1, 1883. ® Porter: PnUger’s Archlv, Bd. Iv, Hft. 7 u. 8, S. 366, 1894. “ E. Weber: "Handworterbuch d. Physiol., Bd. 11, S. 42, 1846. “ Schlff: Archlv f. Physiol. Hellk., 9ter Jahrgang, S. 1850-51. 22,
Pharm., Bd. xxxvill, Hft.
3 u.
“T. B. of Physiol.,*’ sixth American edition, Phila.,
1895.
P1897.
“ Foster:
4,
S.
228,
THE DYNAMICS OF CARDIAC ACTION.
448
when the interrupted current
that
vagal trunk,
tlie
is used to stimulate the heart remains in diastole, motionless and flac-
When, however, the current is weak, the beats are only slowed and weakened. Coats®^ ascertained manometrically that cid.
the contractions were markedly reduced in force.
GaskelP^
and Stefani^® found that the ventricular tonicity was reduced. IVfuskens®® also found that stimulation of the vagus lessened the force of the contraction in the frog. GaskelP'^
characterizes
“most striking” the attending
as
depression of activity. Still, there is no loss of inherent muscular irritability, since, according to Foster,®* a pin prick in the heart during inhibition heats;
the morbid
may
phenomena
cause the organ to resume
deficient supply of the nutrient
components of the blood.
a
Por-
knovTi as to the constituents of
ter®® states that ‘Tint little is
the blood which are essential to the
life
of the
heart,” and that .“an abundant supply of oxygen
highly important.”
its
are, therefore, the result of
The manner
these blood constituents causes the inhibitory effects :
certainly
is
which the deficiency of
in
in the following lines of Langley’s*®
mammalian
“The
is
suggested
decrease of rigidity
in the inhibited muscular tissue shows that inhibition
is
not
caused by the development of a contractile force acting in a direction opposed to the normal one and overpowering
it.
We
are then brought to the conclusion that certain nerve impulses
—the
inhibitory nerve impulses
—are
able to lessen or to stop
the chemical change in the tissue which leads to contraction.”
The ered
(now generally considform part of the nerve bundles
role of the “inhibitory” fibers
as vagal, because they
which have been known as the vagi, or pneumogastric nerves) thus corresponds with that of the sympathetic vasoconstrictors we have found, elsewhere, to restore the arterioles to their nor-
mal
caliber after these vessels
secreto-motor
“
Coats:
nerve
Berlcht
d. k.
to
incite
had been dilated by a motor or an exacerbation of functional
Sachs. Gesellsch.
d.
Wisscnsch.,
MGaskell: Phllosoph. Trans., p. 1019, 1882. “Stefanl: Archives Itallennes de biologie, T. ** Muskens: PflUger's Archlv, Bd. Ixvl, Hft. 5
S. 360, 1869.
xxlll, p. 172,
189,'i.
u. 6, S. 328, 1897. Schafer’s “T. B. of Physiol.,” vol. II, p. 169, 1900. "T. B. of Physiol.,” sixth American edition, 1895.
!"Gaskell: “ Poster: ™ Porter: “Amer. T. B. of Physiol.,” vol. 1, second edition', p. Langley: Schafer’s ”T. B. of Physiol.,” vol. II, p. 616, 1900.
1I8,
1900.
—
44 !)
THE INNERVATION OF THE HEART.
Langley’s observation gives precision to .my view in connection; interpreted from my standpoint, it is the
activity. tliis
diminution of blood in the cellular elements which serves “to lessen or to stop the chemical change in the tissue which leads
Can we
to contraction.”
ascribed by admit that in the heart role
view of the secreto-motor
logicalljf, in
physiologists its
the vagus in other organs,
to
action
the opposite?
is
That the
composed of sympathetic fibers which carry on the same functions they do in other organs, so-called “inhibitory” nerve is
is
therefore evident.
Should we under these conditions consider the sympathetic as
“inhibitory”?
of
excessive
I
have shown that inhibition is the result “Excessive” here of the arterioles.
constriction
obviously portrays a morbid or pathological condition, one of
Indeed, as I will show in the
grave importance clinically. second volume,
many
toxins and toxics are fatal owing to their
vasoconstrictor infiuence on the cardiac vessels,
phenomena awakened
and the morbid
—
are precisely those described above
those
which the physiologist deems normal because they are expressions of a so-called physiological function he has termed “inhibition.” In my opinion the older term “moderator nerve” should replace the pernicious term
now
used,
and “inhibition” be
re-
served for the expression of the morbid process which excessive constriction of the arterioles represents.
AucaiENTATiON. contractile power,
its
of acclerator nerves.
number
i.e.,
increase of
must bo due to an action other than that Thus, von Bezold and Bevei"*^ and later
found that stimulation
Cyon^the
This action of the heart,
of
the
accelerator
increased
of beats of the heart, but not its power.
This was Again the mode of action of the augmentor nerve differs strikingly from that of other cardiac nerves; Foster,'*^ for instance, writes: “In contrast with the case of the vagus fibers, a somewhat strong stimulation is confirmed by other investigators.
required to produce an effect; the time required for the maxi-
mum *'
effect to
be produced
Bezold and Bever:
“Cyon:
Untersuch.
hoc. r(f. “Foster: Loc. clt., p. 203.
is
a.
also
d.
remarkably long.”
physiol. Lab.
These
zu Wurzburg, Bd.
11,
450
.THE DYNAMICS OF CARDIAC ACTION.
and augmentation are separate functions. Indeed, the delay in the augmentation of power, as compared witli the acceleration, is explained when, as I urged a few years ago,'*'* the adrenal secretion is regarded as the source of the increased cardiac power. This is sustained by many facts. Thus, while Noel Paton'*'* refers to the “augmentors and accelerators” as small medullated, i.e., sympathetic, fibers “which leave the spinal cord by the anterior roots of the second, third, and fourth dorsal nerves passing to the stellate ganglion,” I facts suggest that acceleration
have shounr that the three above-mentioned roots are
through which the nerves which pass to
cisely those
pathetic chain
and thence down
resell the adrenals.
On
also pretlie
sym-
to the splanchnic, to finally
stimulating these nerves, therefore, an
experimenter not only excites the accelerators which pass to the heart via the annulus of Vieussens, but also the nerve-paths to the adrenals.
This -accounts for the fact that while a large group of investigators including Cyon, Bezold, Schmiedeberg, Boehm and Bowditch observed acceleration without increase of power, others, equally competent, including Heidenhain, drills, Eoy and Adami, and Bayliss and Starling observed both phenomena. Indeed
Schmiedeberg and Bowditch both urged the presence of two different sets of nerves to account for these specific effects, the
influencing the cardiac beats, the other “acting upon Now, the the blood-pressure without influencing frequency.” blood-presupon the secretion marked influence of the adrenal
one
set
well-known, and the delay in the appearance of “augmentation” is explained when it is borne in mind that the activity of secretory organs had to be awakened before the “aug-
sure
is
mentation” and the Biedl,-*®
fest.
rise of blood-pressure could
in fact, found
become mani-
that stimulation of the divided
splanchnic only caused an increased production of adrenal secretion after 7 to 9 seconds.
submitted in the two preceding sections, the reasons which had led me to conclude that the adrenal secretion conwhich tributed to the contractile power of the right ventricle I
“
Sajous:
Jour. Amer. Med. Assoc., Feb. 4, 1905. ‘‘Essential of Human Physiol.,” p.
“Noel Paton:
«
Biedl:
Lor.
rll.
243,
1905.
451
THE INNERVATION OF THE HEART. it
reaches with the venous blood of the
Now, Brown-Sequard'*'^ had many years
vena cava. (1853) urged
inferior
earlier
the predominating influence of the blood of this vein
upon
cardiac dynamism, a view sustained by Eadcliffe (1855)
;
Castell having
but
found that a frog’s heart when detached failed
with increased vigor in carbonic acid gas, and overlooking the fact that some other substance in the venous blood to beat
might have acted on the heart, physiologists disregarded BrownAdditional evidence to this elfect
Sequard’s observation.
is
submitted in the second volume.
The
presence of “augmentor” and ‘^pressor” fibers in the
sympathetic splanchnic accounts for the fact long ago recorded
by von Bezold and Bensen,*® that section of both splanchnics lowered the blood-jiressure as
much
as
section of the
spinal
cord in the cervical region, while Strehl and Weiss found that,
removing one adrenal, the blood-pressure could be lowered by clamping the suprarenal vein of the remaining organ, thus after
depriving the blood
of
any adrenal
releasing this vein the blood-pressure
As
previous level.
secretion,
and that by
was soon restored
to its
I view the process, however, excitation of
the lower segment of the upper sympathetic cord after dividing it
should raise the blood-pressure.
Bezold found that this pro-
cedure raised the blood-pressure as level;
initial
same
much
as
seven limes
its
Ludwig and Thiry showed, moreover, that the
result could be obtained after severing all the nerves to
the heart.
Augmentor
may
also
effects
attended by a rise of the blood-pressure
be produced through the intermediary of another
Cyon and Aladoff'*” found that stimulation of the annulus of Vieussens (which also contains pure accelerator fibers) organ.
Cyon had already found in 1867 that when the cervical sympathetic was divided on a level with the inferior cervical ganglion, and its upper segment was exraised
the blood-pressure.
cited the strength of the heart-beats
was markedly increased.
" Brown-Sgquard: Exper. Researches applied to Phys. and Path., N. Y.. London, and Paris, 1853. ‘®Von Bezold and Bensen: Neue Wiirzberger Zeitung, 1866: Verb. d. Phys. med. Gesells., Wurzburg, January, 1867. and Aladoft: Bull, de I’Acad. des Scl. de St. Petersburg, vol. vii, 29
—
— THE DYNAMICS OF CARDIAC ACTION.
452
A
—
(1898)"® by the same physi-
recent study of the question
ologist
showed that these “reenforced pulsations” which he had
at first ascribed to reflex action, were in reality due
that the nerves which evolve these to the vessels of the thyroid gland
the fact
tri
phenomena were distributed it was the secretion
and that
which had produced the cardiac “augmentation.” The manner in which the thyroid secretion could produce this of this organ
effect is readily explained
by the fact that, as I have shown,
this secretion serves to sustain the functional efficiency of the
adrenal
center.
Briefly,
—that
it
is
through the adrenals
also
Cyon produced “reenforced pulsations”
though indirectly of the heart.
The following
conclusions seem to me, in the light of the
foregoing facts, to summarize the functional mechanism of the
heart
;
The nervous supply of the heart is derived from the sympathetic system and is composed of two sets of nerves' the accelerator and the moderator ( or inhibitory) nerves. 2. The accelerator nerves increase the rapidity of the con1.
tractions of the heart, by causing dilation of its arterioles
thus increasing the volume of blood admitted to
its
and
muscidar
ele-
ments. 3.
The moderator
(or inhibitory) nerves diminish the ra-
pidity of the heart’s contractions, by causing constriction, of arterioles and thus reducing the volume of blood admitted to
its its
muscular elements. “Augmentation,” Jf.
i.e., increased poiver of the heart’s conactivity of the adrenals, whose increased tractions is due to secretion traverses the heart on its way. to the lungs. As to the physico-chemical process involved hearing in
—
mind that the muscular elements are inherently contractile they are, pending additional data, as follows; 5.
The mechanical energy
depends
is
of
Uvo hinds:
adrenal secretion brought to
(1) it
up07i
the
which
the
contractile
heart
right
action
of
the
by the inferior vena cava; (2)
coionaty the continuous action of the oxidizing substance of the the arterial blood upon myosinogen foi'med from granules 3) latter baing granulations derived “>.Cyon:
from
Arch, de physiol, norm, et path.,
leucocytes. vol. x,
No.
5,
p.
618,
1898.
ADRENAL SECRETION
453
IN RESPIRATION.
The. adrenal secretion and the granulations
6.
right auricle
^
enter the
the right ventricle with the blood of the vena
and
cava.
The adrenal
7.
secretion,
owing
direct
its
to
action
on
muscular tissue, causes the walls of these cavities to contract
upon
alternately
their venous
contents
and
to
force a small
quantity of the latter into the Thebesian foramen and channels. S. This blood then penetrates the interfibrillary spaces of
—
—
around the bare muscle-cells, and its granules fS are used by the lattei' to build up their myosinogen. 9. /Is the plasma of the coronary arteries and their ter-
Ilenle ,
i.e.,
minals, the pericellular capillaries of the muscle-elements, contains
oxidizing
muscle-cells 10.
is
substance
induced as
The adrenal
(adrenoxidase)
secretion
contraction
of
the
elsewhere in the organism.
it is
and the granules
f} ,
which do not
enter the Thebesian channeds, are carried to the lungs with the
venous blood of the right ventricle. 11. The mechanical energy of the
left heart is supplied (1) by the oxidizing substance of the arterial blood, which penetrates
muscular structures and its cavities by the coronaries and the pulmonary veins, and (2) by an additional supply of granulations and perhaps of adrenal secretion, which find their way f3 , to its myocardium through the Thebesian channels that connect its
it
with the right heart. 12.
The manner
on in the walls of the
in
which the contractile process
left
heart
is
is
carried
similar to that which prevails
in the right heart.
THE ADRENAL SECRETION IN ITS RELATIONS TO RESPIRATORY FUNCTIONS. The
role
of
the
adrenal
particularly the jirocess through
the blood,
was reviewed
secretion
in
and taken up by
respiration,
which oxygen
is
in the second chapter.
I believe that the succeeding chapters, by affirming the importance of the oxidizing substance in every part of the organism, have but confirmed the conclusions reached concerning the process in ciuostion. he fact that the interchange of oxygen and carbonic acid between the alveolar air and the blood fi.
difTusion
by mere was inadequate to account for the experimental results
:
THE RESPIRATORY MECHANISM.
454 of
various
Smith,
must
investigators,
has
therefore
particularly
been
Bohr and Haldane and
correspondingly
emphasized.
also refer to the fact, however, that the belief of
I
Ludwig,
Bohr, and others, that the alveolar tissues might be the seat of functions capable of fulfilling the missing requirements of
the process, has not been sustained by
my
inquiry.
On
the
other hand, the role of the adrenal secretion in the lungs as I have defined
it
has adequately met these requirements, not-
withstanding the severe
which
tests to
it
has been submitted in
previous chapters.
We
have seen that the adrenal secretion, conveyed to the
lungs with the venous blood,
is
not only able to take up oxy-
gen, but to form an oxidizing substance,
i.e.,
adrenoxidase, with
which ha3inoglobin can, in the lungs, become replenished with oxygen. The entire set of analyses submitted in this work so far, however, i.e.,
has served further to emphasize another fact
that the plasma, and not the corpuscle,
is
the dispenser of
oxygen, the corpuscle being a mere carrier from which the
becomes replenished as needed. As already stated, this precisely coincides with the conclusion to which Jaquet was led by chemical methods after Salkowski ( 1881 ) had obtained oxidations from blood alone, which he attributed, how-
plasma
itself
ever, to the blood-corpuscles.
Abelous and Biarnes having ob-
tained oxidation of salicylic aldehyde by means of blood-serum, Salkowski modified his former view and experimentally con-
firmed the results of the other investigators; Finally, we have seen how closely connected the adrenal secretion
is
with the integrity of the blood, and how readily the
haemoglobin molecule becomes dissociated in proportion as the efficienc}^ of the adrenals becomes weakened. The next important question to analyze is one fraught with considerable confusion, process
is
viz.,
the
manner in which the
respiratory
governed, and the identity of the respiratory center.
THE NERVO-VASCULAR MECHANISM OF THE LUNGS.
is is
According to prevailing teachings the respiratory center But there located in the medulla oblongata, i.e., the b,ulb. bulbar the considerable evidence on record indicating that
—
THE NERVO-VASCULAR MECHANISM OF THE LUNGS. center
is
not supreme in the control of respiration, although the
fact that it forms part of the controlling
mechanism cannot be
Thus, division of the cord below the seventh cervical
denied.
nerve
455
arrests
respiration;
costal
causes all thoracic
movements
section
below the medulla
removal of the brain
to cease;
above the medulla, the seat of the supposed center, does not stop respiration, while cessation, of this function occurs
when
the medulla is removed or extensively injured, save in exceptional cases.
After reviewing this evidence Professor Poster
“Nay, more;
adds:
if
only a small portion of the medulla
a traet whose limits have not been clearly defined,
but which
may be described as lying below the vasomotor center in the immediate neighborhood of the nuclei of the vagus nerves ^be removed or injured, respiration ceases, and death at once ensues.
—
Hence
this portion of the nervous system
the vital knot, or ganglion of life of
it as
:
was called by Flourens
nccud vital.
We
shall speak
the respiratory center.''
Yet,
how account
for the facts recited in the following
quotation from Noel Paton’s text®^:
“Both parts of the
re-
spiratory center are under the control of higher nerve centers,
and through these they may be throum into action at any time, or even prevented from acting for the space of a minute or so. But, after the lapse of this period, the respiratory mechanism proceeds to act in spite of the most powerful attempts to prevent
it.
“To determine
its
nerves upon the center
“Vagus. tract
— Since
mode
of action the influence of afferent
must be considered.
the vagus
we should expect
it
is
to have
the nerve of the respiratory
an important influence on the
center.
“Section of one vagus causes the respiration to become slower and deeper ; but, after a time, the effect wears off, and the previous rate
and depth of respiration
is
regained.
'Section of both vagi causes a very
marked slowing and deepening of the respiration, which persists for some time, and passes off slowly and incompletely. Now, if after the vagi have been cut, the connection of the center with the upper brain The italics are mine. “Noel Paton: hoc. cit.,
p. ?,9l.
THE RESPIRATORY MECHANISM.
456
tracts is severed, the
mode
of action of the center totally changes.
Instead of discharging rhythmically
it
remains for a long period
at rest, then the inspiratory center discharges violently, causing
a strong and prolonged contraction of the muscles of inspiraThis passes off, and again a period of rest of variable tion. duration sets less
to be again interrupted by another
in,
more or
long and strong discharge.
“Separation of the respiratory center from
upper brain tracts brings about a hut does not stop
nature of
its
pulses reach
its
activity.
loss of its
The
tlie
vagi and
rhythmic action,
center owes the rhythmic
These afferent im-
action to afferent impulses.
normally through the vagi, but when these are
it
cut the upper brain takes upon itself the function of maintain-
ing the rhythm.”
HowelP®
also says, referring to the “midbrain, at the level
of the posterior colliculi” (the corpora quadrigemina) a region
above the medulla oblongata;
“Martin and
that stimulations in this region caused a rate of inspiratory
ration
—that
movements and
found
increase in the
finally a standstill in inspi-
a complete tetanic contraction of the inspiratory
is,
Lewandowsky®® has
muscles lasting during the stimulation.
shown that
Booker'''*
marked
section of the brain stem at or below the inferior
colliculi causes an alteration in the respiratory rhythm similar
After cutting through
to that following section of both vagi.
the inferior colliculi further sections
add to the
He
effect.
more
considers that there
hibitory center in the midbrain which
posteriorly do not is
an automatic in-
infiuences continually
Again, OtP®
the automatic activity of the medullary center.” writes:
“I have
made numerous
e.xperiments to determine the
exact seat of the polypnceic center.
things are necessary:
nomena
to
disappear;
—
(1)
(2) causes the
that
its
To
establish a center three
abolition causes the phe-
that irritation
—mechanical,
chem-
phenomena to be present, and (3)
or electrical that the part of the nervous system exhibiting these peculiarities After numerous observations and be circumscribed in extent.
ical
"T. B. of Physiol.,” second edition, p. 640, 1907. Martin and Booker: Jour, of Physiol,, 1, 370, 1878. Lewandowsky Archiv f. Physiol., 489, 1896. Ott: “T. B. of Physiol.,” second edition, p. 451, 1907.'
“Howell;
^
*
:
“
THE NERVO-VASCULAR MECHANISM OF THE LUNGS. experiments
457
was found that pressure upon the tuber cinereum
it
with a pledget of cotton, or even slight puncture, increased the normal respirations to the point of polypnoea. Complete puncture in a normal animal was followed by a rise to
106° F.
within two hours, even though the animal was found
down
and had been subjected to considerable shock. '^f now the animal whose tuber is punctured be heated, there will result no polypnoea, even though a temperature of 107° P. be reached. I am convinced that the tuher cinereum is
a center of 'polypnoea
A
and
tliermotaxis.”
suggestive feature asserts itself in this connection:
As
and as will be further shown in the second volume the tuber cinereum is precisely the region through which the nerve path from the pituitary body to the adrenals passes to the medulla oblongata, and thence, via the spinal cord and the sympathetic nerves and ganglia, to the adrenals, whose secretion, we have seen, serves to take up the oxygen of the air and I have pointed out,
to
distribute
to
it
the
tissues,
i.e.,
to
sustain
oxygenation.
emphasized by considerable evidence submitted in the second volume, the walls and floor (of which the tuber cinereum forms part) of the third ventricle, are the pathways of a vast array of sympathetic fibers which likewise pass from Moreover,
as
the posterior or neural lobe of the pituitary
magnus
(via the nucleus
medulla and cord and thence to be distributed through the sjnnpathetic chain and its offshoots to all parts of the body including the lungs. We have here the grisei)
to the
explanation of the presence of so-called heat and respiratory centers in this region, i.e., irritation phenomena following the
—
experimental lesions in the course of these nerve-paths, a fact further sustained by the observation of many experimenters that removal of the pituitary body the seat of the heat and
—
—
main respiratory centers in the light of my views is followed by marked lowering of the temperature and dyspnoea.
How
does the respiratory center
the bulbar center
—or
centers, for as stated,
—
endowed with important functions influence the respiratory mechanism? Before this feature of the subject can be analyzed, a brief review of the circulation and is
innervation of the lungs
The pulmonary
may
prove advantageous.
circulation
as
regards vascular distribu-
THE RESPIRATORY MECHANISM.
458 tion
is
portrayed in the following description by
succinctly
Miller,” as given by
monary artery
An
length. its
Bohm
and von Davidolf^*:
“The pulmo-
follows closely the bronchi through their entire
arterial
branch enters each lobule of the lung at
apex, in close proximity to the bronchus.
After entering the
lobule the artery divides quite abruptly, a branch going to each
from these branches the small arterioles arise which supply the alveoli of the lung. ‘On reaching the air-sac the artery breaks up into small radicles, which pass to the central side of the sac in the sulci between the air-cells, and infundibulum;
are finally lost in the rich system of capillaries to which they
This net-work surrounds the whole air-sac and com-
give rise.
municates freely with that of the surrounding capillary net-work
is
exceedingly
fine,
and
is
This
sacs.’
shrunken into the
epithelium of the air-sacs; so that between the epithelium and the capillary there
mem-
only the extremely delicate basement
is
brane.
The
and the
alveoli of the respiratory bronchioles are supplied
similar
capillary
infundibula, the alveolar ducts and their alveoli,
from the lobules
The
net-ivorl's. lie
veins
collecting
with
the blood
at the periphery of the lobules in the inter-
lobular connective tissue, and are as far distant from the in-
form the and small, The bronchi, both large larger pulmonary veins. as well as the bronchioles, derive their blood-supply from the bronchial arteries, which also partly supply the lung itself. Capillaries derived from these arteries surround the bronchial These veins unite
tralobular arteries as possible.
to
system, their caliber varying according to the structure they
supply
:
finer
and more
closely arranged in the
brane, and coarser in the connective-tissue walls.
borhood of the terminal
bronchial
tubes
the
mucous memIn the neighcapillary
anastomose freely with those of the respiratory capillary tem.'’
To
avoid confusion I
may
recall the
nets sys-
fact that, while
the pvlmonnry artery and its branches contain venous blood,
and the bronchial arteries and their branches carry hlood, the pulmonary veins, on the contrary, contain Iilood.
When,
Miller:
arterial arterial
therefore, bronchial capillaries are said to
Journal of Morphology, vol.
“ Bohm and von
Davidoff:
Loe.
clt.
vlil, p. 165, 1893.
empty
— THE NERVO-VASCULAR MECHANISM OF THE LUNGS. into the is
459
veins, it is not used, or venous, blood that
pulmonary
transferred to the latter, but arterial blood originally derived
from the thoracic aorta or
The
lungs, as
is
its
primary branches.
well known, are innervated by the vagus
and the sympathetic system. These unite to form plexuses, the anterior and posterior, which enter the organs with the bronchial tubes and accompany them along their ramifications. The anterior pulmonary plexus, made up of vagal and sympathetic filaments, overlies the pulmonary artery, while the richer posterior pulmonary plexus, composed also of vagal filaments, intermixed with sympathetic fibers from the second, third, and fourth thoracic ganglia, follows the bronchi to their ultimate subdivisions.
—
According to prevailing views, the vagus both its sensory and motor fibers is alone regarded as the intermediary between
—
the respiratory center and the organs of respiration, but as
shown also
in the second volume, the neural lobe of the pituitary
contains the sjunpathetic center.
This proximity to the
respiratory center and the important role the sympathetic plays in
respiration pointedly
suggest that both centers are func-
tionally united.
Indeed, there
good ground for the belief that the experimental phenomena now ascribed to the vagus are partly of sympathetic origin sympathetic in the sense that they are is
—
essentially
vasoconstrictor as in other organs previously reSappey, for instance, writes®® “Section of both pneumogastrics in the median portion of the neck not only abolishes
viewed.
:
the sensibility of the respiratoiy lyzes the internal respiratory
mucous membrane and para-
muscles;
it also involves as consequence a mucous effnsion into the bronchi, engorgement of -
emphysema of diminution in the number the
lungs,
these organs,
and a very sensible
of inspirations.”
We
have in the
pulmonar}'^ engorgement an evident result of variation of vascular caliber, and inasmuch as we are dealing with a division of the nerve, the effect on the vessel must have been one of relaxation. On the other hand, we have in the paralysis of the internal respiratory muscles evidence that a motor nerve
“
Sappey:
“Traltfi cl'Anatomle Descriptive,” vol.
Ill,
p. 397.
THE RESPIRATORY MECHANISM.
460
—was
a vasodilator, or stricto-dilator, in onr sense
also severed.
we have
Tliese dual plienoinena indicate that the vagus, as in the case of the heart, i.e.,
sympathetic
The
must have contained
fibers.
presence of vasoconstrictor fibers
recognized.
seen
vasoconstrictor,
is,
in fact, generally
Trangois-Franck, in 1881 , showed that the sym-
pathetic nerves distributed to the lungs, caused vasoconstriction, these fibers being stimulated at the entrance into the lungs.
Bradford and Dean““ also demonstrated the presence of vasomotor nerves in these organs after a series of exhaustive experiments.
In a subsequent study of the subject Frangois-Franck®'
noted the paradoxical fact that vasoconstriction of the pulmo-
nary vessels caused the lungs to in volume.
This
is
swell, instead of
readily accounted for
being reduced
when
is
it
to the arterioles.
recalled
my
that the vasoconstriction applies only, in the light of
views,
These small pre-capillary vessels being con-
stricted, the arterial
blood was
dammed up behind
the seat of
obstruction in Frangois-Franck’s experiment, thus causing the larger portions of the vessel, which are not governed by the
sympathetic, to dilate.
A ever,
source of confusion asserts itself in this connection, how-
which we have
The experiments
also encountered while stud}dng the heart.
of Bose Bradford and Dean®^ are thus referred
“They carefully sought the points of by Frangois-Franck emergence, from the cord, of the filaments which cause elevation of pulmonary pressure and lowering of aortic pressure: that is to say, pulmonary vasoconstriction. These were located to
:
from the second
to sixth dorsal, and, in respect to
maximum
with the third, fourth, and fifth nerves. The pulmonary vasoconstrictors ascend the chain up to the first effects,
on a
level
thoracic ganglion, where they become detached, to reach the pulmonary plexuses.” The salient feature of the topography of
that the lower limit of the ganglionic chain through which they pass happens to he the upper limit of the ganglia from which the splanchnic nerves that ultimately carry these nerves
is
impulses to the adrenals are given “»
off.
While the pulmonary
Bradford and Dean: Jour, of Physiol., vol. xvl, Frangois-Franck: Arch, de Physiol., T. vlii, p. Rose, Bradford and Dean: Journal of Physiol.,
p. 31, 1894. 184, 189&. p. 57.
1894.
THE NBRVO-VASCULAR MECHANISM OP THE LUNGS. vasoconstrictors which pass directly to the lungs
thoracic
to
the pulmonary plexuses are,
from
as generally
true vasoeonstrictors, the presence in the
second,
461 tlie
first
taught,
third,
and
fourth ganglia of the sympathetic chain, of the nerves to the adrenals suggests that
many
vasoconstrictor phenomena^attrib-
uted to the direct action of nerves, should be ascribed to an increase of adrenal
seeretion
in
the blood.
Indeed Jacobi““
found that intense vasoconstriction of the intestinal vessels produced by
(inhibition)
by
replaced
ordinary
exeitation
the
of
vasoconstriction
after
splanchnic the
was
suprarenal
nerves had been cut.
The
fact,
moreover, that the introduction of adrenal extract
into the circulation produces general vasoconstriction is well
knoivn.
Mankowsky,®'* for example, noted “a great increase in
blood-pressure and stimulation of the cardiac and respiratory
This occurred “even when the animals (dogs) were under the influence of chloroform, morphine, or chloral hycenters.”
drate.”
“In
able feature
cats, says Swale Vincent,®” ‘Ty far the most noticewas an enormous rapidity of the respiratory move-
—
—
ments in the early stage.” The two now familiar stages that occur under the influence of toxic doses of suprarenal extract, as well as under that of other poisons, are well illustrated in the following observation
by the same investigator: “In the early stage of poisoning respiration is quick and shallow and the heart is excited. Subsequently the breathing and heartbeats become feeble, and Anally the respiration is deep and infrequent.”
Finally, the fact that all these
phenomena
are
independent of the cord has been shown by Biedl,®® who, as we have seen, obtained marked increase of blood-pressure after injections of suprarenal e.xtract, notwithstanding the fact that all the spinal structures had been removed.
This does not mean that the adrenal secretion fulfllls any particular function in the lungs other than that of taking up o.xygen therein; it is only intended to show that excitation of the splanchnic nerve may suggest the presence of pulmonary “Jacobi;
Archiv f. exper. Path. u. Pharm., vol. xxix, p. 171, 1892. Russian Archives of Pathology, etc.. Mar, 1898
“*Mankowsky:
“ Swale Vincent: “ Biedl: Wiener
Jour, of Physiol., Feb. kiln.
Wochen.,
lx, 1896.
17,
1898.
THE RESPIRATORY MECHANISM.
462
vasoconstrictor nerves in this great nerve-iiath,
when
the vaso-
constrictor effects witnessed in the lungs are in reality due to
the jiresence in the blood, as a result of siilanchnic stimulation, of an excess of adrenal secretion.
As
to the role of the vagus in the respiratory organs, our
views differ from those at present taught only in that they explain, as was the case with other organs, ical
phenomena
how
the physiolog-
are ^iroduced.
I have briefly referred to the fibers are distributed in the lungs.
manner
in
which the vagal
Sappey®^ also studied the
mammals, including man, the ox, and horse, and reached the “1. They follow the subdivisions of the following conclusions distribution of vagal nerves in the lungs of
particularly those of
:
air-tree to their terminal extremities;
they do not leave these
them to the lobules. 2. All those that leave tli3 anterior pulmonary plexus and the much greater number given off by the posterior pulmonary plexus preserve subdivisions and follow
their plexiform
arrangement throughout their entire distribu-
meshes are elongated only in the line of their axis, each thus constituting an elongated ellipse. 3. Their ramifications, essentially destined for the muscular coat of the bronchi and respiratory mucous membrane, have no connection with tion;
their
Berdal, on the other hand, confirms this,
the blood-vessels.”
and indicates the lowing lines
:
role of the sympathetic terminals in the fol-
“The branches
for the bronchi;
of the penumogastric are destined
the branches of the great sympathetic are
lost in the walls of the arteries.”
The statement
of Sappey that the vagal ramifications of
the vagus have no connection with the blood-vessels, introduces a feature of importance which applies to all other organs reviewed, viz.:
that besides the
vasodilator and
vasoconstrictor
nerves
which govern the function of any organ, there are sensory terminals which, as such, transmit afferent impulses to the centers (primary or subsidiary) which govern the Indeed, we have seen that section
of
the
caused loss of sensation in the respiratory
local blood supply.
vagi
in
the neck
mucous membrane,
paralyzed the bronchial muscles, and gave rise to effusion of
Sappoy:
Loc.
eit., p. 391.
THE NERVO-VASCULAR MECHANISM OF THE LUNGS.
4G3
and engorgement of the lungs.
How
mucus
into the bronchi
can
these iihenomena be accounted for without granting sen-
all
sory as well as motor and vasomotor functions to the vagal
Loss of sensation points to inhibited function, and not
supply?
engorgement of the bronchial mucous membrane. And yet we may have engorgement without functional erethism, if it is due, not to the presence of blood fully charged with oxygen, to
'
dammed
but to blood which, through the very fact of being
up in the vascular channels,
reduced therein to practically
is
The
the condition of venous blood.
effusion of
mucus
into the
bronchi and pulmonary engorgement would occur as normal consequences of such a state of things.
But how account for
this vascular dilation without granting such attributes to the
vagal plexuses?
Again, the fact that cutting of both nerves in the neck gave rise to paralysis of these muscles points to another suggestive feature,
namely
that the vagus
must
these muscles,
besides
:
the motor impulses to
the functional variations
now add
to
of
caliber
of
these manifestations of
those of afferent
incite
their
and govern
presiding over vessels.
If
we
efferent nervous activity
suggested by the loss of sensation
activity
mucous membrane, it seems clear that we vagal nerves referred to an autonomous supply espe-
over the bronchial
have in the cially
devoted to the function of the bronchial tubes and their
ramifications lobule.
doivn
— but
to
The importance
of
not including this
realize that it accounts for the
affections
from those
of the
fact
—
asserts
pulmonary
the itself
when we
complete isolation of bronchial
parenchyma, and gives ns a clue
to their original cause.
My
opinion that the vagus
lungs as elsewhere,
experimental stimulation of
i.e.,
—
as
motor nerve
—
acts in the
as stricto-dilator neiwe, is sustained
tlie
origin of the superior laryngeal)
causes the respiration to be-
come more and more rapid, the inspiratory phase being accentuated.
Noel Paton:
by
As Noel Baton writes”®: “Strong pulmonary branches of one vagus (below the
evidence.
If
the stimulus
Loc.
cil.,
p. 292.
is
chiefly
very strong respirations are
—
—
THE RESPIRATORY MECHANISM.
464
Weak
stopped in the phase of inspiration.
may
other hand,
stimuli,
on the
cause inhibition of inspiration.
‘‘Such experiments prove that impulses are constantly traveling from the lungs to the center whereby the rhythmic activity of the center
“How from
rently
is
maintained.
do these impulses originate in the lungs? their alternate expansion and contraction.
“If the lungs be forcibly inflated
Appa-
with a bellows
e.g.,
the inspiration becomes feebler and feebler and finally stops.
The nature tion
of the gas,
carried out
is
is
of
if
non-irritant, with
no consequence.
If,
which
this infla-
on the other hand,
the lungs be collapsed by sucking air out of them, the inspiration becomes
more and more powerful, and may end
in a spasm
of the inspiratory muscles.
“This shows that with each expiration a stimulus passes up
make it excito-motor nerve, mak-
the vagus which acts upon the inspiratory center to
The vagus
discharge.
is
thus a true
ing the center act in a reflex manner. the lung the vagus it
is
With each
collapse of
thrown into action, as the lungs expand
ceases to act, and, as a result, the inspiratory center stops
acting, the muscles of inspiration cease to contraet,
and expira-
tion occurs.
“While ordinary respiration may thus be considered as a rhythmic
reflex act, it
must not be forgotten
that the respira-
tory center can and does act rhythmically under the influence of the higher center, or a-rhythmically and spasmodically
these as well as the vagi are severed
from
when
it.”
The mode of action of the vagus as a “true excito-motor nerve” is thus subject in a great measure to the respiratory centers
—the
main one
of which, in the light of
my
views
is
The located in the neural lobe of the pituitary body. to impulses sensory transmit bronchi of the terminals sensory
vagal
this center
and e.xcito-motor impulses are transmitted by
it
to
the entire respiratory apparatus, including the thoracic respiraThe manner in which all these muscles are tory muscles. excited to increased activity by the efferent or excito-motor vagal an excess fibers does not differ from that of all organs reviewed :
of blood tion of
is
its
admitted into the contractile elements, through dilaAn excess of blood-plasma laden with arterioles.
THE NERVO-VASCULAR MECHANISM OF THE LUNGS. oxidizing substance
is
465
admitted, as previously shown, to the
myosinogen of the muscular elements, where inspiration is in order; hence the fact that strong excitation of the vagus “causes the respiration to become,” as Paton says, “more and
more
When
rapid, the inspiratory phase being chiefly accentnated.”
—physiologically—excessive
inspiration
is
to
cease,
the
sympathetic vasoconstrictors come into play: they restore the muscular arterioles to their normal caliber; less blood is admitted to the muscular elements and the inspirations resume their
normal rhythm.
must now be taken into account: that And from the standpoint of the clinician, this factor is by far the most important of all the physiological phenomena of the function of respiration. Indeed as will be shown in the second volume, But
a third factor
represented by the functions of the adrenals.
dyspnoea
is
often the result of adrenal insufficiency, the adrenal
secretion produced being inadequate to sustain the oxygenation
of the
body at
large.
Again, Miller, we have seen, refers to
the subdivision of the pulmonary artery “which divides quite abruptly, a branch going to each infundibulum”; ter “small arterioles arise
which supply the
from the
lat-
alveoli,” while these
on reaching the air-sac are said to culminate in “the rich system of capillaries to which they give rise.” If the “small arterioles which supply the alveoli” are abnormally dilated through
some general dyscrasia and the stream of venous blood of genation of the adrenal secretion
exposed to the
known
air,
we have
it
contains
is
oxjf-
thus imperfectly
a logical explanation of the well
—a sympathetic stimulant
beneficial action of belladonna
which, as
we
will see, causes constriction of the arterioles,
and
of potassium iodide, a powerful adrenal stimulant.
That fluctuations in the secretory
activity of the adrenals provoke dyspnoea is well illustrated by the effects of all drugs that are sufficiently active to markedly affect adrenal
may
functions. The action of venoms even more strikingly shows the morbid connection that exists between variations of suprarenal activity and pulmonary functions, even the stage of blooddisintegration being sometimes reached. Noe,®® for instance.
““No6:
Loc.
cit.
— THE RESPIRATORY MECHANISM.
466 refers to the
many
phenomena
tory
observers wlio have reported intense respira-
Viper-venom was
after cobra-bites.
also found produce at first “accelerated respiration,” then “somnolence, with slowing of respiration.” Bee-venom in suf-
by
I’hisalix to
ficient quantity gives rise to dyspnoea,
according to Paul Bert,
black blood being found in the vessels.
Toad-, salamander-,
and eel- venoms were foimd to affect respiration in a similar manner. Mosso noted that the process of death varied scorpion-,
with the dose heart
;
medium
:
stronger
doses
doses arrest
first
arrest resiiiration, then the
both simultaneously.
Paralysis
motor end-plates had evidently nothing to do with this process, since l\Iosso found the thoracic nerves responsive to
of the
the induced current.
Eemoval give rise to
the adrenals under
of
phenomena
these
conditions should
similar to a violent dose of venom.
Cybulski not only observed,'^® under such conditions, marked dyspnoea, a fall of the vascular pressure to zero, and haemoglobinuria, but also
found that the injection into the veins
of an aqueous 10-per-cent, solution of suprarenal extract “im-
mediately states that
caused
these
phenomena
after removal of both
of rats the respiration
to
disappear.”
BoineP'
organs in a large number
became “slow, painful, and
difficult.”
important features any of those generally recognized. understand why the nerve paths of the
Briefly, the functions of the adrenals are as
of the respiratory function as It is
now
possible to
heat and respiratory centers are so intimately related in the third ventricle.
Originating from a
common
center, the pitui-
tary body, the vagal, sj^mpathetic and adrenal nerves, jointly project from their
common
source, the pituitary body, to reach,
by way of the tuber cinereum, the walls of the third ventricle and the midbrain, the medulla oblongata, where they form subsidiary (and probably coordinating) centers whence the impulses to the respiratory organs are transmitted.
The newer
features of the nervo-vascular
mechanism of
respiration which I submit iu the foreadditional evidence and detail, may be pending going pages, summarized as follows:
(ordinary tranquil)
™
Cybulski: Gazeta Lekarska, March Bolnet: Loc. clt.
23.
1895.
—
4G7
THE ADRENAL SYSTEM AND THE THYMUS. 1.
The hulbar
respiratory center
the sole, or even the
is
not,
now
as
believed,
this class; it is
most important, center of
a subsidiary and, probably, a co-ordinating center.
The primary and chief respiratory center is located in the pituitary body and consists of three functionally related centers, the adrenal, vagal, and sympathetic centers, which, in 2.
turn, are connected by nerve-chains with the corresponding sub-
sidiary centers in the bulb,
and govern, through the interme-
diary of the latter, the respiratory mechanism. The chief respiratory center carries on its functions as fol-
lows :
by governing the production of the adrenal secretion, which takes up the oxygen of the air and forms the albuminous constituent (96 per cent.) of hcemoglobin, Its
adrenal center,
regulates the proportion of this oxidizing substance (the adrenoxi-
dase) supplied to the blood. Its vagal center, acting through the vagus (the intercostals
and phrenic)
as excito-motor (stricto-dilator) nerves of inspira-
provokes contraction of the muscles which dilate the larynx, the bronchi, and the thoi'ax and depress the diaphragm, and thus tion,
increase the intake of air by the lungs,
i.e.,
the supply of oxygen
from which the adrenal secretion and the hcemoglobin absorb oxygen to distribute it to the tissues. Its sympathetic center, acting, through
the
sympathetic
nervous system, as antagonist of the vagal center to provoke expiration, causes all the above-mentioned respiratory muscles to relax passively
(by constricting their arterioles) , thus en-
and bronchi to resume contract, and the diaphragm
abling the larynx the thorax to
their
normal
to rise, in
caliber,
order to in-
sure the expulsion of the expiratory air laden with carbonic acid.
THE ADRENAL SYSTEM AND THE FUNCTIONS OF THE THYMUS GLAND. In the first edition of this work (1903) I urged that there was “considerable analogy between the effects of thymus on the organism and those of the thyroid.” Parhon and Golstein"have since been
-led also to
Parhon and Golsteln;
conclude that “the relations of the
Secretions Internes, p.
690, 1909.
THE ADRENAL SYSTEM AND THE THYMUS.
468
thymus with the thyroid gland seemed very
close,” a view also
sustained by the recent experiments of Hoskins.’^® has, in fact, reported eighteen cases of infantile
which the thymus alone showed lesions-^a
fact
Euhrah'^*
marasmus
in
which suggests
that, as is the case with the thyroparathyroid apparatus, the
thymus influences in some way general metabolism. In keeping with this view is the conclusion of Basch” that a relation exists between the th3'mus and the growth of bones and also the healing of fractures-r-also a therapeutic property shown by thyroid preparations. Converselj", FischeF“ and others have observed no clearly deflned evidence that removal of the thymus influenced development, general or osseous, of young animals. the preponderating evidence sustains the positive view,
Still,
negative evidence being often due to faulty technique, or ascribable to the assumption of functions by the related organ
—the
thyroid in the present instance. Svelila’^ believes that the thyroid
gland only assumes
its
functions at birth, extract of foetal thyroid having proven inert,
while extract obtained from the thyroids of infants during the
month
same manner did thj'mus extract behave: foetal-thymus extract produced no effect, while that obtained from the thymus glands of infants in first
the
first
of life
was
effective.
month caused
Precisely in the
increase in the frequency of the pulse
and lessened blood-pressure. He found, moreover, that “among children of the same age the thymus extract is the strongest; In adults, howless so the thyroid, and still less the adrenal. ever, the adrenal outstrips both other glands.”
Svehla refers to “increased frequency of the pulse and lessened
blood-pressure”
extract:
evidence,
if its
as
the
prominent
effects
of
thj'mus
action corresponds to that of thyroid,
that a toxic dose had been administered to the experimental animal. This is sustained by the fact that other typical symptoms were present: i.e., muscular weakness, dyspnoea, and general collapse, a condition from which the animals could be saved by the timely administration of thymus extract, which
—
promptly restored the normal vascular pressure. ”
Hoskins:
’‘Ruhrkh:
"Basch:
™
Fischel:
Svehla:
American Journal of the Medlcai Sciences, Mar., 1911. British Medical Journal, Aug. 29, 190?. t. Kinderhellk., p. 1063. Zeitsch. f. exper. Pathol, u. Therap. B. 1, p. 388, 1905. Archlv fUr exper. Pathologle, Bd. xllll.
Jahrb.
TIIK
469
ADRENAL SYSTEM AND THE THYMUS.
extract seems to prove efficacious in precisely the same class of cases of exophthalmic goiter hut only when the asthenic or second stage is reached as thyroid extract.
Thymus
— —
for example, recalled his successful result in a marked case of twenty years’ standing, but he indirectly points to his patient’s advanced condition by the statement “the next three
Owen/®
months he spent mostly in bed.” His second case complained of feeling “low and weak,” sweated profusely, became bald, and had tremors and pigmentation. A third case benefited was one in which breathlessness, general weakness, and emotional outbreaks prevailed. He also refers to an extremely aggravated case treated successfully by Maude,''® in which drugs, including belladonna, had proven ineffectual. Hnder thymus tabloids, 45 grains daily, the patient rapidly improved, and invariably relapsed
when they were
discontinued.
Maude hav-
ing observed that the tremors were particularly relieved by
Owen
this foi-m of treatment,
thymus in paralysis
tried fresh
agitans, “with the result that the tremors
and the mental
benefited
were unmistakably and the muscular condition
state
greatly improved.”
An all
Maude’s cases shows that they are In the first “the heart and paralytic confine her to bed for over a year.”
analytical study of
of the advanced type.
conditions were such as to
The second “belonged
to a highly neurotic family; goiter
had and the “tremor, excessive muscular weakness, and cardiac disturbance were all well marked.” The third had recovered from a previous attack without thymus; existed since childhood,”
hence, serve
use after recurrence as the result of grief cannot
its
as
fair
The fourth was
example.
standing, and the patient
had
nervous
paralysis
symptoms,
viz.
suffered
of
thirty-two years’
from “various severe
of
various basal nerves ophthalmoplegia, paralysis of facial, ambulatory epilepsy, etc.” “She had had, in 1894, twenty-four motions in one :
.
day of almost pure arterial blood. In November, 1895, she had a sudden profuse hsematemesis, followed by collapse so extreme that she seemed moribund. After she rallied she was given 45 grains of thymus tabloids per day, for a month, and Owen: Maude:
British Medical Journal, Oct.
Lancet, July
18,
1896
10.
THE ADRENAL SYSTEM AND THE THYMUS.
470
her improvement was very remarkable; she remained in a fair state of health for many months/’ Degeneration of the arterial walls probably existed in this case, and
the loss
of'
it
seems likely that
blood can be credited with the relief afforded.
Todd’s case®® had an epileptic mother, her sister had suffered from myxcede'ma and had been cured with thyroid extract, and she was hei*self a “vei*y delicate”
girl. IST. J. McKie’s case®^ and those of 11. T. Edes®- and Philip James®® also represent instances in which there was thyroadrenal insufficieney. In a case
successfully treated by Boisvert®^ the jiresence of melancholia
shows that weakened adrenals were present and that the
also
increased insufficiency of these organs brought on by the thymus, as was the case with two of the patients referred to by Dr. Winter in which thyroid extract was used, led to recovery.
These examples, which could be multiplied, not only indicate that
thymus
extractives are active
when
there
is
impaired func-
tional activity of the thyroid
and adrenals, but they
prove that the thymus gland
is
also tend to
very similar to the thyroid in
its
upon these organs. The harmful effects of thymus in the first stage are illustrated by a case described by Watson Williams,®® who found that it aggravated the tachycardia and p}Texia: evidence that In it had been given while thyroid overactivity was present. action
the large proportion of cases reported, however, there
marked untoward
effect
produced.
It
seems to be much
active in this connection than the thyroid extractives.
some
in
cases
—
—probably
those
is
In
no less
fact,
on the border-line of thyroid
insufficiency it appears to act as a nutident tonic, as noted by Hector Mackenzie®® after a study of twenty cases in which he
had
tried
thymus gland, and
to
which further reference
is
made
below.
The connection between the thymus and
the adrenals
may
also be illustrated by the experiments of Abelous and Billard,®’ in which removal of the former gave rise to symptoms similar British Medical Journal, July 25, 1890. British Medical Journal. March 14, 1896. R. T. Edes: Boston Med. and Surg. Journal. Jan 23 1896. Philip James: Australasian Med. Gazette, July 20, lw7. Boisvert: Revue M^dicale de Montreal, June 21, 1899. Watson Williams: Clinical Journal. Dec. 11. 1895April, 1897. Hector Mackenzie: American Journal of the Medical Sciences, Abelous and Blllard: Archives de Physiologic, Oct., 1896.
“Todd; 8> 8=
N.
J.
McKle:
,
SB
“ 61
471
THE ADRENAL SYSTEM AND THE THYMUS.
skin,
the
gi-eat
muscular
blood-changes, oedema, tions of
even to discoloration of
that follow adrenalectomy:
to those
etc.
weakness—lapsing They also found
into
paralysis,
that the
secre-
the experimental animals were markedly toxic:
evi-
On the whole, this evidence, dence of inadequate oxidation. that the thymus gland indicate considered collectively, seems to supplies some substance which directly or indirectly stimulates and thereby en-
the secretory functions of the adrenal system, hances the activity of the oxidation, processes.
What
the nature of the agency tlirough which the thy-
is
and what is the specific relationThese questions are suggested by ship between these organs? the fact that, Avhile undue activity of the thymus increases that of the adrenals, there seems to be no evidence that tlie thymus
mus
stimulates the adrenals,
can
alone— i.e., independently
either exophthalmic goiter or
of
—give
thyroid
the
In
myxeedema.
all
rise
cases of the
former disease ascribed to the thymus found in available ture there
normal
We
invariably thyroidal involvement.
is
mus seems
sufficiently
active
to
bring
tlie
to
litera-
Yet the thy-
adrenals to
their
activity vdien the general vital processes are depressed.
have seen, on the other hand, that
its
removal gives rise to
symptoms recalling those of adrenalectomy. Baumann®® found minute quantities of iodine in the thy-
mus
also;
this trace,
tion
but other experimenters have failed to find even
and have ascribed Baumann’s findings
from neighboring thyroidal
such a trace of iodine
exists,
we
tissues.
to
contamina-
Even granting that
are well aware that the thyroid
power to stimulate the adrenals to ‘"a trace”; the labors of many investigators have conclusively shovoi that it must supply the organism with a considerable amount of does not owe
its
this substance.
Evidently we must look elsewhere for the solu-
tion of this problem, and, data bearing directly
upon the subbeing wanting, we shall have to seek for the required substance through its comparative behavior in the organism, and
ject
the
manner
in which its effects vary in the latter
from those
of thyroid e.xtractives.
Valuable in tliis connection are the autopsies of 61 children at the Ilopital des Enfants-Malades, of Paris, performed ***
Baumann:
Miinchener mcd. Wochenschrift,
p.
311,
1893.
THE ADRENAL SYSTEM AND THE THYMUS.
472
by Albert Katz at the request of Boumeville.*® All these children had died of various diseases, their ages varying from one month to thirteen years, though 41 were under two years of age. In all of the G1 bodies the thymus gland was present, while in 28 mentally weak and epileptic children examined by Bourneville the thymus was absent in 25. In another series, of 292 cases, it was absent in 74 per cent. But these comprise not only
all varieties of mentally abnormal children, but also various degrees of imbecility; so that the remaining 26 per cent, may have included a number of instances in which mental
development was high as compared to that of the cases in which the organ was absent. Yet, to avoid favoring our own line, .of argument, we will consider that in three-fourths of imbecile some of which were epileptics, the tliymus gland was
children, absent.
These observations become elucidative when analyzed through the effects of thyroid extract. Especially suggestive is the following casual remark of Cabot’s, in the course of a valuable paper published some years ago"®: “The fact that in myxoedematous children and cretins the thyroid treatment is associated Avith notable growth in height has led some observers to try its effects in if
dwarfed children not myxoedematous,
their development could not be helped.
I have collected 10
such cases, 3 in idiotic children and 6 in
development was mainly physical. height Avas observed in
were not
improved."'’’'-
all
It
A
to see
whom
the lack of
considerable increase in
the cases, hut the mental symptoms
seems evident that
if,
on the one
hand, the vast majority of cases of mentally Aveak children do
not possess thymus glands, and that, on the other, thyroid extract
will
enhance growth of
cedematous ones,
i.e.,
idiotic
children
(not
cretins), the oxidation processes,
my.x-
stimu-
by the thyroid simultaneously Avith the adrenals, are inadequate to alone bring on improA'ement of the mental symptoms. Again, it becomes evident that it is upon the th}Tuus that the mental development depends, and, finally, that it is to some agent which the thyroid gland does not contain that this development is due. lated
*•
Katz:
Le
Profrrfis
M6dlcal, June
“ Cabot: Medical News, Sept. “ The italics are my own.
12,
23, 1900. 1896.
—
473
THE ADRENAL SYSTEM AND THE THYMUS. This enables us to eliminate iodine,
main being
thjToiodase, as the
i.e.,
thymus gland, and, our inquiry from the oxidation process through the
active principle of the
disconnected
evident inefficiency of the thyroid to restore mental functions,
we
are led to seek for a chemical
Can we
nutrition.
body that will enliance cerebral
expect such an hypothetical agency, however,
upon the brain alone? This is hardly from analogy, and the nervous system at large must also utilize it physiologically. Our field is therefore broadened, since an agency connected with the nutrition of the brain alone, or one playing the same role in respect to the entire to concentrate its etfects
probable, judging
nervous system,
may
This
serve our needs.
fortunate, for the chemistiy of brain-
is,
to say the least,
and nerve- matter
is
far
from well known, and even a good analysis i.e., one based upon the more salient data available would be impossible
—
were the limits of the inquiry at
Of the
constituents
solid
three stand out prominently
:
all
of
narrowed.
and brain- matter, cerebrin, and lecithin.
nerve-
cholesterin,
Cholesterin, considered by Austin Flint, Jr., as a waste-product
and nervous
of cerebral
origin,
though
it
represents one-half -
shows no molecular constituent capable of (CjgH^^O), the fact that the thyroid secretes a specific agency being taken as standard; nor does cerebrin (C17H33NO3), though both this and the preceding body are of
all
the solids,
assisting us
abundance in the cerebro-spinal axis and nerves. With lecithin, sometimes termed “phosphorized fat,” which found in
represents about one-tenth of the solids, the case since its
different,
is
fonnula (C44H00NPOS,) suggests that j)hosphoi"us
represent the
constituent
we
are
seeking.
It
is
may
not only a
prominent component of the whole cerebro-spinal and neiwous systems, however, but it is also a constituent of the red and white corpuscles, milk, bile, serum, semen, and pus. Another body, protagon (Ci3oH33g]Sr5P035), has also been isolated from
brain-substance by Liebreich, cerebral
constituent
Blankenhorn.®^
considered
it
as
the
main
an opinion sustained by Gamgee and Hoppe-Seyler and other investigators are,
however, inclined to consider cerebrin.
-vvdio
:
Whether
it
as a mixture of lecithin
this be the case or not,
“ Gamgee and Blankenhorn:
and
phosphorus again
Journal of Physiology, vol.
11,
1879.
THE ADRENAL SYSTEM AND THE THYMUS.
474
appears as the only element capable of being at with the question in point.
To adopt
organic
associated
all
phosphorus as the characteristic con-
thymus gland, however, and declare minus or plus production that the mental
stituent of the
tliat
through
attributes
its
it is
of children are developed, would merely constitute a theory. As a stronger position is desired for all the deductions vouchsafed in this work, collateral evidence must be sought.
The
observations
stimulates growth,
it
of fails
Cabot,
that,
while
thyroid
extract
enhance mental development in
to
than myxcedematous ones, raises the question as whether such results can be due to the absence of phosphorus in the thyroid. If such is the case, the absence of this idiots other
to
element should also show
itself
the brain and nervous system, of
phos2)horus also exists,
is
the results obtained from
in
the extract in some other disease, in
any structure other than which a morbid deficiency
if
a feature
of
that disease.
We
know, for example, that phosphorus is introduced into the organism with food, and that calcium phosphate, by becoming deposited in the bones, gives them their hardness.
any evidence that the bones of subjects tract
is
stituent?
Is
there
which thyroid e.xsuccessfully administered lack of this hardening conin
Eefcrring to the use of thyroid extract in cretinism,
T. Telford-Smith”® makes the following statement:
“I have
found that during thyroid treatment the rapid growth of the skeleton leads to a softened condition of the bones, resulting
in a yielding and bending of those which have to bear weight, and, as cretins under treatment become more active and inclined to run about, this tendency to bending has to be guarded against.”
After referring to the experiments of Hofmeister in
rabbits and those of Eisenburg in sheep and goats in which bending of the legs Avas caused by removal of the thyroid, he adds: “While in rickets, however produced, there is perverted and delayed ossification resulting in softening and bending of
the bones, under thyroid treatment in cretinism there
is
rapid
resumption of groAvth in the skeleton, leading to softening, which is most marked in the long bones and at the epiphyses.” That we are dealing here with an absence of phosphonis and w
T, Tel ford -Smith;
Lancet, Oct.
2,
1897,
475
THE ADRENAL SYSTEM AND THE THYMUS. that the calcium phosphate
serves
harden the bones con-
to
currently with their growth seem obvious.
But why does
Marie,
ascertained by
the fact,
Simply through that the thymus is almost
this not occur in all cases
?
always persistent in cases of cretinism. When thyroid gland is administered, therefore, the increased oxidation procured with
and the
the aid of the adrenals also enhances thymic activity, assimilation of phosphorus
proven
by the
is
experiments
in
by
animals
Eisenburg, referred to by Telford-Smith.
If
thyroid caused bone-softening in these,
is
my
light of
This
increased in proportion.
it
process—
conception of the
^the
Hofmeister
is
and
removal of the
—
because
in the
adrenals were ren-
dered inadequate, and, oxidation being impaired in proportion, the
thymus
also failed functionally.
This process, however, involves the need, in the structures of the thymus gland, of a metabolic process culminating in the production of an internal secretion laden with phosphoruscontaining bodies.
Quotations from a study of the nucleins
and nucleoproteids
in
their relation to
Chittenden®® will serve to enlighten us: the
cells
which
substances
specific
internal
secretions
is
contained in the gland or
inherent quality of
all
secretion
“The manufacture
character
give
obviously
internal
a function either of
may
it
of
various
the
to
by
special
be in some cases an
the cellular elements of a given gland.
In the pancreas the formation of the active agent
is
limited to an interstitial,
occurring in
terized
epithelium-like tissue
patches throughout the gland
isolated
by
distinct
its
from the secreting
and
alveoli,
of being the source of the internal
adrenals, principle,
and especially charac-
This epithelioid tissue
vascularity.
apparently
is
is
certainly
suspected, at least,
Again, in the
secretion.
Schafer and Oliver have shown, the active which has such a marked influence upon the heart as
and arteries, is contained only in the medulla of the gland, and not in the cortex, the medulla forming about one-fourth of the gland by weight.”
“If we take the content of phosphorus as a measure of the proportion of nucleic acid contained
in
the
various et
p. Job, layo.
^ChlUenden:
.
.
forms
.
of
nucleoproteids
thus
far
Mfimolres de la Socidtd Mddlcale des HOpitaux de Paris,
Boston Med. and Surg. Journal, August
20,
1890,
THE ADRENAL SYSTEM AND THE THYMUS.
476
we
studied,
exceedingly great variations
find
of this aeid present in the moleeule;
number
evidence of the large
as
the
amount
may
be taken
in
a fact which
molecular combinations
of
present in the protoplasm of different
cells.
Thus, from the
kidneys we obtain a nueleoproteid with only 0.37 per cent, of phospliorus, while, as representing the other extreme we have in the pancreas a nueleoproteid eontaining 4.71 per .eent.
of
phosphorus and in the lymphoid cells of the thymus a corresponding body with 3.5 per cent, of phosphorus. The very .
nature of the the
nucleic
many
bases whieh
outside
acids
.
.
come from the cleavage
of these bases into other allied bodies by oxidation
own
tion; their
marked;
the
physiological
possibility
acids,
may
and, further, that
may
undiscovered reasons
exist
believing
for
action,
—na}%
other catabolic products
still
the
and reduc-
which, though mild, probability
—
is
many
that
be obtained from these nucleic other nucleic acids
in the cell-protoplasm,
that
of
body; the ready convertibility
the
the
nucleins
all
at
present
offer
good
and nucleoproteids,
which are the most prominent constituents of the protoplasm of all cells, are the most probable antecedents of the internal secretions.”
There phosphorus
evidently a sound foundation for the belief that
is
is
the active constituent of the thymus gland.
If
thyroid extract failed to improve the mental condition of the ten
cases
collected
growth witnessed,
by
it
is
was structurally unable
Cabot
notwithstanding
either because the to
the
increased
thymic gland in
all
respond to the increased oxidation
which the stimulated adrenals induced or because no thymus gland was present. That this gland is absent in the vast majority of weak-minded, but not myxeedematous, children is shown by the researches of Bourneville and Katz. That phosphorus is the main specific constituent of brain- and nervesubstance
is
a recognized fact fxilly sustained by physiochem-
That thyroid gland does not improve non-myxcedematous idiocy or weak-mindedness in children owing to the absence of phosphorus in the organism is shown by the corresponding effects it has on the skeleton of some cretins, as ical
data.
observed by Telford-Smith, the bones, by their, softness, showo*
All the Italics are
my
own.
—
—
477
THE ADRENAL SYSTEM AND THE THYMUS.
hardening that calcium phosphate Finally, that the adrenals, through the normal oxiprocures. dation processes insured by them when adequately stimulated ing
by the thyroid
the
of
absence
the
secretion, sustain the activity of the
thymus up
Hofto its proper standard is shown by the experiments of meister and Eisenburg, in which removal of the thyroid of various
—herbivorous—animals
bending
caused
of
the
legs.
The thyroid is thus able to stimulate the adrenals, and the But does the adrenals in turn can stimulate the thymus. thymus physiologically stimulate the adrenals?
The
fact,
that the tlijunus gland
ture, one calculated to
atrophy when
is
its
but a temporary strucfunctions as a building
organ are accomplished, would seem to suggest that stimulation If the deducof the adrenals is not one of these functions. appear to stand tions herein submitted are sound, it would prominently as a bone-forming organ and general pliosphorusor rather nuclein- purveying organ from the time of the completion of
its
lymphadenoid elements during intra-uterine life and growth of all tissues, including
until the final elaboration
its
frame-work,
skeletal
tlie
i.e.,
around the period of puberty,
powers gradually receding as permanent organs are developed.
This conception of itself
to
anyone
purpose does not appear to have suggested
its
so
observations
collateral
but
far,
of
a
it
is
quite in keeping with the
number
of
the
best
of
modern
embryologists.
One the
lof
the
sources
bone-marrow.
foetal
life,
of leucocytes,
In the process
the first points of
second month, but
it is
of
as
is
well
knoum,
bone-formation
ossification
is
during
appear during the
only during the fourth that the devel-
opment becomes markedly active on all sides. That the most active work of the thymus is performed during intra-uterine life
is
generally recognized; this, therefore, coincides with its
most active bone-forming period.
It
seems reasonable to con-
clude that so important a function as leucocytogenesis should
not devolve upon structures undergoing formation, and also that the bone-forming organ should be intrusted with the function
which ultimately would constitute the main active attribute of their product. Bone-marrow being the main leucocyteforming structure, we should therefore expect the thymus to
THE ADRENAL SYSTEM AND THE THYMUS.
478
assume
hone-marrow had reached
this role until the
nonnal
its
physiological development.
Kolliker
has
always
maintained that the formation
leucocytes was a function of the thymus:
he
been sustained by Prenant and
has
Oscar
Beard“^ took up the question and studied
it
care in the Baia hatis, the smooth skate.
He
the absence of leucocjdcs in
J.
ascertained that
embryonic
of
ones arc formed
first
within the thymus epithelium and from
embryos from twenty-eight
Schultze.
with considerable
earliest period
tlie
blood in vertebrates persists until the
of
a position in which
In
its epithelial cells.
forty-two millimeters long the
to
formation and emigration of leucocytes from
tlic
comes very
no part of the
and
active,
emblem, including
blood, that
tlie
is
is
not infiltrated with leuco-
elsewhere within the body of the smooth skate.
with Kolliker, that the formation of leucocytes the thymus gland, and “the
from
its
tliymus be-
happens before lymj)hoid structures are developed
'This
cytes.
time there
this
at
epithelial
by what appears
to
it
me
to be a
a function of
thymus
the parent-source
is
a conclusion which
:
is
believes,
leucocytes arise in the
first
thus
cells;
leucocytes of the body”
Beard
of
all
further sustained
is
warranted deduction
:
that
i.e.,
thymus is the main organ upon which the osseous, cerebrospinal, and nervous systems depend, and perhaps all other the
tissues, for their
We
organic phosphorus during their development.
have also seen that leucocytes are included among the
bodies that contain phosphorus.
bone-forming organ
as a
observation
that
but when we
foetal
fix
little
of the
identity of the thyroid
thymus proves
recall the fact that
the fourth month, that
but
is
The
apparently contradicted by Svehla’s
its
it
inert
inordinate activity
element
itself,
there
is
doubt as to the value of the experiments. not
prevail,
all
the
data
e.xperi mentally;
only assumes
the
submitted,
may
its
function
cause
it
ample room
to
for
If these facts do
recognized
intra-
uterine supremacy of the thymus over other glands, Chittenden’s
analysis,
and
several
physiologically
established
facts
would also have to be considered wrong. All this entails the conclusion that
exceedingly
^
3
.
Beard:
valuable Lancet, Jan.
therapeutic 21,
1899.
thymus might prove an
agent
in
selected
479
THE ADRENAL SYSTEM AND THE THYMUS. In
cases.
seems possible that, in the very cases treated
fact, it
by Cabot, the addition of thymus might have caused the improvement in the mental The absence condition which thyroid alone failed to procure. of the thymus in Bourneville’s cases supplies a firm foundation thyroid
with
referred
extract
to
Though some
for this thought.
sodium phosphate,
benefit has been obtained
from
seems reasonable to believe that in physthymus, phosphorus will
it
iological combination, as it occurs in
prove
far
more
Whether
efficacious.
through this element
activity
or,
specific
physiological body intended
matters
little.
for
th e
this
we do axis
.nervous system utilize phosphorus as an all-important
specific source of energy,
oxidation which
and associate with its
intelligent use
by Owen in a case of
may
The
unattainable through any other agency.
we
insure residts
benefit obtained
shows that these are not
j^aralysis agitans
Indeed, we must not overlook the fact that im-
vain words.
adrenal
all
structures
the
reduced
activity
reduces
the
standard
nutritional
of
and that all cells fail to appropriate through metaholism involved their ph3^siological con-
stituents.
While,
classed
a nervous
as
this the enlianced
stimulation of the adrenals procures,
its
cannot but realize, that
paired
if
cerebrospinal
entire
a
special purpose,
stimulates the adrenals, and
It also
not lose sight of the fact that the
and
suprarenal
enhances
it
does thyroid, through
as
therefore, disease,
paralysis it
is
agitans
should
not
be
nevertheless true that the
nervous system, suffers
if the adrenals underlie the whole trouble, also from impaired nutrition, and that phosphorus, its source
of intrinsic energy,
is
as necessary to it as
oxygen
itself.
The
obtained from the therapeutic use of thymus gland mainly due to the phosphorus-laden micleins it contains.
benefit
to
is
A number of authors have suggested that thymus was able compensate for the adrenals. In Boinet’s e.xperiments in
rats, for
example, eleven out of fifty which had survived some time adrenalectomy showed hypertrophy of the thymus. Anld observed the same phenomenon in four cats, though he had
removed but one
adre.nal in these animals.
nati, Wiesfe, -Hedingeii,”® Hart,"'’
Pansini and Bone-
and others have
also observed
68 06
Wart.
Wien.
klin.
Wochenschr., D.
Gesellsch., B. xi, S. 29. 1907. xxi,
S.
1119,
1908.
4S0
THE ADRENAL SYSTEM AND. THE THYMUS. thymus
liypertro]jhy of the son’s
disease,
—a
who had
in subjects
condition
in
which,
as
died of Addi-
known, the But
well
is
functions of the adrenals are arrested by organic disease.
hypertrophy does not always indicate a compensative function, especially when any of the ductless glands are in question.
Those so far reviewed, the thyroid and adrenals, are intimately concerned,
we have
seen, with the destruction of toxic wastes.
It follows, therefore, that
removal of
eitlier set of
such wastes to accumulate in the blood, and, as raise the blood-pressure.
This in
is
organs allows
well
known,
itself is sufficient to
to
produce
and congestion of the thymus with enlargement witnessed in the adrenals under the influence of many poisons. The enlargement of the thymus should not,
hypertemia similar to
tliat
therefore, be regarded as compensative.
What is
the evidence available does seeVn to warrant, however,
that the thymus sustains the functional activity of the adrenals
by contributing what
it
contributes to
all
other organs,
the
i.e.,
excess of phosphorus-laden nucleins required by the organism
during
its
development,
i.e.,
overlook the fact that wliat
nervous system to
organ
the
:
I
until puberty.
mean by “organ”
the center and
and
its
intrinsic
glandular, to which phosphorus
culating
shown
iq
the
But we must not
axis-cylinders,
in the next chapter, a sine
here includes
its
and afferent paths supph', vascular and
its efferent
nerve is,
with the adrenoxidase
nerve-fibers,
etc.,
as
qua non of functional
cir-
will
be
activity,
under these conditions that insufficiency of the adrenals or of the thymus must produce morbid phenomena similar, though less marked in degree, to those of the thyroparathyroid apparatus and the adrenals, all concerned as I have shown.
also directly,
The
It follows
we have with nuclein mehibolism and
oxidation.
participation of the secreting organs of the adrenal
system in the functional relationship with the thymus shown in a case of marasmus carefully studied by
is
well
E.
L.
Thompson,’ ““ in which “in addition to changes in the thymus extreme atrophy was found in the thyroid, parathyroids, and medullary suprarenals.” Having had the opportunity to examine the thymus in 20 cases of marasmus at St. Ann’s Asylum, in infants from birth to 1 year of age, he found in, every case “a loo
Thompson:
Amer. Jour. Med.
Scl.,
Oct., 1907.
— 481
THE ADRENAL SYSTEM AND THE THYMUS.
So marked was the and other cases referred to, sustained by con-
notable atrophy of the thymus gland.”
evidence in this tributory
data, that Thompson concludes that “all marasmus exhibit marked atrophic changes in
collateral
infants dying of the
thymus gland.”
The important
role I ascribe to the
phosphorus in organic combination to
thymus,
all tissue,
i.e.,
to supply
accounts for the
morbid influence of atrophic changes in the thymus upon the organism which the “marasmus” portrays, in the light of the above facts, since, by causing atrophy of the thyroid, parathyroids,
and adrenals,
inhibits the functions of the identical organs
it
which, as I have sho^vn, combine to sustain oxidation, meiaholisni,
and nutrition. Though unable to account for the manner in which it exercised so potent an influence on the body at large, Friedlieben, as long ago as 1858, stated that “the size and condition of the thymus was an index to the state of nutrition of the body,” an observation confirmed, as stated by Thompson, by a
number
of
investigators,
among whom he mentions
heimer,^®^ Stokes, Euhrah, Eohrer,^®-
l\retten-
and Dudgeon,^®® who
all
noted that “atrophy of the thymus gland in children and wasting
hand in hand, “Dudgeon stating, moreover, that atrophy of the thymus gland was “the most characteristic lesion found in cases of marasmus.” of the tissues go
On 1.
the whole, the above evidence seems to
That the function
of phosphorus in
and growth
of
osseous systems,
thymus is organic compound as long
the
of the
hody,
demand
particularly
its
to
me
to suggest
:
supply an excess
as the development
cerebrospinal
and
it.
That impairment of the functions of the thymus underlies some of the disorders of nutrition which inhibit the development of the cerebrospinal, nervous, and osseous system during 2.
and early adolescence. That certain diseases of mdrition in children and adolescents, especially marasmus, rachitis, and trophic disorders of the brain and nervous system, are due, in part, to impairment
infancy, childhood, 3.
of
the functions of the thymus.
”2 loa
Dudgeon.
Bd. Ixvl, S. 55. 1897. 1 Klnderhellk., cxslv, p. 847, 1902. Jour. Path, and Bact., vol. x, p. 173 1905. ,
482
THE ADRENOXIDASE AND THE NERVOUS SYSTEM.
THE CIRCUJjATION OF ADRENOXIDASE IN THE NERVOUS SYSTEM. e
—
have now seen that aclrenoxidase
the oxidizing body of the Idood derived originalljf from the adrenals takes part in the functions of tlie many organs reviewed, in so far as their supply of oxygen
That
concerned.
is
Of
can be no doubt.
—
this applies to all organs there
the whole series, however, one, the nervous
system, including the cerebro-spinal system and all ganglia and nerves, is the most complicated by far. It must, therefore, re-
due attention to ascertain whether it also depends for its oxygen upon the adrenals. We shall see under the next heading
ceive
that such
is
the case, and, moreover, that the large proportion
many
of phosphorus which
of
tially
components:
its
stance of Schwann, the lecithin,
etc.,
the white sub-
contain, brings
it
within the reach of the thyroparathyroid secretion,
The adrenoxidase and
thyroiodase.
essen-
i.e.,
the
the thyroiodase constituting
the two active agents of the adrenal system, we shall be able,
moreover, to realize
why
the neiwous system ft so manifestly
involved in the diseases of the ductless glands.
Again, I would
while Harvey
call attention to the fact that,
revealed to us the circulation of the blood in practically
all
organs, the one exception in his epoch-making discovery was the
nervous system, and for obvious reasons: identity
of
bringing
it
the nen'e-cell, to view Avere
Its
histology,
and staining methods capable
unknown
in his time.
The
the of
explanation
of the circulation in the nervous system (apart, of course, from its
known nutrient
nerve
cells
vessels, AA'hich are, in reality, external to the
per se) sul)mitted in the next chapter, an amplifica-
tion of that published in 1903 in the present work,
the
first effort
is,
I believe,
of the kind in Avhich histo-chemical data
—and not
mere assumptions
—
are the basis of analysis.
or oxidizing sul)stance,
is
axis-cylinders of nerves.
shown
The
adrenoxidase,
to circulate in the neuraxons, or
If the reader will ask himself:
How
does the neurotoxin of tetanus, shown by IMarie and Morax,
IMeyer and Hansom, and others to ascend in the axis-cylinders of nerves, in
these
perfonu this feat? he elements,
phenomenon.
as
I
Avill
inteqjret
conclude that circulation it,
alone
accounts for the
CHAPTER
X.
THE POSTERIOR PITUITARY AS A GEXERAL XERVECEXTER AXD AS CO-CENTER TO THE ANTERIOR PITUITARY IN SUSTAINING LIFE. THE IDENTITY OF THE LOWER BRAIN. In
the foregoing chapters, I
nrgecl
that certain centers
in the medulla oblongata were probably but subsidiary centers
which received nervous impulses from the pituitary body by I way of the tuber cinereum and other basal structures. obtained by physiologists phenomenon in that it was caused
held, moreover, that “inhibition” as
represented a pathological
by excessive constriction of the cardiac
arterioles,
provoked by
vasoconstrictors contained in the nerve stimulated, the vagus.
As is well known, it was the work of the brothers Weber (1845) which first suggested that the heart could be “inhibited” by stimulation of a definite region in the medulla. Their experiments differed from those we have reviewed in that the tissues of the base of the brain were traversed by the current, thus
exciting structures
in
which we
have seen sympathetic and other nerves pass from the pituitary to the bulb. One pole having been placed in the nasal cavity of a frog fifth
and the
vertebra,
the
gradually resumed poles
upon the
on the spinal cord over the fourth or action momentarily ceased, then normal activity. Approximation of the
otlier
heaiUs its
and stimulation of the cord “Not until the medulla oblongata between the corpora quadrigemina and the lower end of the calamus scriptorius was stimulated,” says William T. Porcerebral hemispheres
])roduced no effect
upon the
heart.
did the arrest take place. Cutting away the spinal cord and the remainder of the brain did not alter the result.” The level
ter,
from structures below the brain is also suggested by the effects of experimental injury of the bulbar area which I lourens termed le na’iid vital. of fibers
31
(483)
— THE POSTERIOR PITUITARY AND THE NERVOUS SYSTEM.
484
Galen had already noticed that death ensued when a spot in the floor
tain
which
But
is
now known
the fourth
of
ventricle
as the center of the vagus
much
Legallois and Flourens have added
edge of
its
physiological relations,
we have seen, “The results of
as
is
close
cer-
that
to
was injured.
to our knowl-
and the spot in question,
considered as the respiratory center.
still
various
show,
investigations
liowever,”
says
Beichert,^ “tliat Flourens’s area, as well as certain other parts
of the medulla oblongata that have been looked
upon by others
as being respiratory centers, are not such, but are largely or
wholly collections of nerve-fibers which arise chiefly in the the
of
roots
vagal,
spinal
and
glosso-pharyngeal,
accessory,
trigeminal nerves, and which, therefore, are probably nerve-
paths to and from the respiratory center.
Moreover, excita-
tion of the ‘nceud vital’ does not excite respiratory movements,
but simply increases the tonicity of the diaphragm; nor
is
the
destruction of the area always followed by a cessation of res-
While the precise location of the center is still in ‘is abundant evidence to justify the belief in its That we existence in the lower portion of the spinal bulb.” are again dealing with the aggregate of centers to which the
piration.
doubt, there
Flourens body projects its fibers suggests itself. located his “vital Imot” in an area flve millimeters wide heiween the nuclei of the vagus and spinal accessory nerves again in the lower end of the calamus scripto-rius : i.e., a region comprised in the area to which the Weber brothers applied pituitary
one electrode,
tlie
or inhibition was
An
when
other being in the nose, first
cardiac arrest
observed by them.
interesting relationship seems to
these two sets of experimental
which the pituitary body sends
results.
me
Indeed, the area to
fibers
its
to exist between
thus becomes the
source of antagonistic effects involving the same structures
Weber
file
constriction of its in the
manner previously
by Flourens
in the
same
the floiy of impulses to
^
:
i.e.,
undue myocardium, coronaries and ischamiia of the
brothers caused arrest of the heart by causing
Reichert:
Loc.
cit., p.
45C.
described, while the lesion produced area,
when
sufficiently severe, blocked
and from the
heart.
Flourens’s 7ioeud
485
THE LOWER BRAIN.
no more the respiratory center than the area traversed by the current can be called an “inhibitory” area. We are simply dealing with the results of two morbid factors: vital, therefore, is
—and
physiological
and
(Weber)
overstimulation
therefore
(Flourens)
interruption
functional
—impulses
of
transmitted
through the medulla and the cord.
In the
fifth
chapter reference was
made
to the fact that
shown by Howell, con-
the posterior pituitary lobe alone, as
tained an active principle. This lobe, the “infundibular,” has long been termed the “neural” portion of the whole organ, and appears to me to present anatomical features that further
suggest a direct connection between
Hence the use
centers.
it
and the cerebro-spinal
words “physiological impulses
of the
transmitted through the medulla and the cord.”
becomes
all
the
more worthy
The
of a searching inquiry,
question
inasmuch
a casual examination of the mutual relations, anatomical and physiological, of the cerebral structures traversed by the as
current in the experiment of the
Weber brothers
suffices
to
show that the elements thus submitted to excessive stimulation coincide with those which would normally fall under the influence of the posterior pituitary body.
The
physiological
characteristics
of
the parts influenced
by the current must first be ascertained. In the frog, the distance between the nose and the medulla being very short, a current would implicate all elements in its direct path, considering the
character
animal, the lizard,
about the
appear to
floor
me
of
etc.,
the
of
the
structures
traversed.
In this
the nasal nervous terminals, the tissues
median ventricle and the habenula, would be involved. In man the
as the paths that
distance between the olfactory area or the nasal of the fifth pair
and the medulla
is
subdivisions
also relatively limited, and.
the intervening structures are of such a nature as to also allow the current to pass uninterruptedly in a straight path. But the of the median or third ventricle, which in its anterior portion overlies the base of the skull and is very thin, becomes what appears to be the inevitable path of free conduction, owing floor
proximity of the olfactory bulb and the trigeminal nasal terminals to the medullary centers. Of special interest here, however, is the fact that in man (and to a great extent in the to this
:
THE POSTERIOR PITUITARY AND THE NERVOUS SYSTEM.
4
PHYSIOLOGY OF THE POSTERIOR PITUITARY.
501
come from every part of the underlying structures and only reach the basal structures through paths that are continuous '
and irrespective of the nerves which arise directly from the two lobes and pass upward by way of That a profuse padding the interior of the infundibulum. of cellular tissue is Nature’s resource under such conditions “The is well illustrated by the following remark of Dejerine’s: vessels of the central nervous system are surrounded by two with the capsule’s
tissues,
sheaths of a different kind
and belongs in nature,
the internal
is
connective in nature
mesodermic layer; the external, neurogliar
to the
is
:
developed at the expense of the external, or ecto-
The
dermic, layer.”
capsule has been compared to the cerebral
cortex, perhaps with justice, as
we
shall show.
Berkley, referring to the various cellular structures in the
deeper portion of the lobe supplied with long extensions, say^:
“The
axis-cylinder extensions of all the cells in the inferior
portion of the to the larger
lobe
turn upward.
.
proportion of the smaller
.
.
Those belonging
of the superior border turn upward and intermingle with the marginal fiber net-work. All the axis-cylinder processes and the .
.
cells
.
long dendrites have a general tendency upward and forward, both dendrites and neuraxons branching as they proceed on-
ward
:
cells of
but
the dendrites of the inferior and
all traces of
median
the lobe are lost some little distance below the superior
and then the neurons only are intermingled with the extensions of the smaller superficial cells, jDassing them, however, before the border is finally reached, where they spread out into a most extensive fret-work of fine varicose fibers, still edge,
retaining
something of their previous
ment from the threads
longitudinal
arrange-
of the uptending fibers being coarser
than the lateral and intermingling branches. It is doubtfnl whether any of these fibers pass beyond the limit of the lobe into the infundibulum our sections give no evidence of such an arrangement.” This upward tendency of all cells, and the ;
evident concentration of their functional activity at the upper extremity, seem to us to further emphasize the identity of the posterior lobe as a powerful source of energy. Its junction with tlie end of the infundihulum becomes, under these circumstances, the normal pathway for all the energy that the
—
—
THE POSTERIOR PITUITARY AND THE NERVOUS SYSTEM.
502
can accumulate.
01 gall
or processes
organ
is its
We
Capsule and j^rotojilasiuic extensions serve a similar purpose, but the neck of tlie
all
own
functional limit.
must not
lose
sight of the fact, however, that other
nerves penetrate the organ.
This
Berkley says, in this connection
:
is
shown by the
fact that
“the nerve-fibers accompanying
the larger arteries are sometimes distinctly seen coming from the infundibular tract into the body of the posterior lobe of the
glaud and ramifying through it.” That tliere is no connection between these and the nervous structures previously described, however,
shown by the additional statement: “Connections between the fibers of the vascular supply and the nerve-cells of the organ, we have never been able to observe. That these are the nerves through which the organ receives its own functional energy i.e., the impulses to its vessels and alveoli, is
as in the case of other organs, is probable.”
The
prevailing view that the embryonal supporting sub-
stance of the brain and spinal cord, the ependymal neuroglia,
mammal
almost entirely atrophies and disappears in the adult
would tend
my
counteract
to
belief that the capsule
and
its
underlying structures are important factors of the posterior Berkley, alluding to the writings of various
lobe’s functions.
observers in this connection, and referring to the infundibulum
and other
which he had just “After reading these statements, it was some-
tissues
described, says
:
of
third
the
ventricle
thing of a surprise to find the above-described beautiful speci-
mens
of several types of ependymal neuroglia extending from
portions of the middle and inferior regions of the cavity of the third ventricle and reaching to the periphery, all portions,
all
and subpial endings being readily distinguishable. The region examined is, therefore, very interesting not only from the great variety of neuroglia-cells that may be seen within a very limited area, but from the bodies, branches, tentacles,
fact that varieties of the
supposed
to
ependymal
neuroglia-cells, previously
have entirely disappeared from the central nervous
.system in the adult
mammal,
are found present in perfect con-
dition in the brain of a very high order of animal, and are not confined, as has reptiles,
previously been supposed, to those
amphibia, and fishes/’
of adult
;
503
THK PITUITARY AND THE BASE OF THE BRAIN.
submitted are considered collectively, it seems to me that the following conclusion is warranted Removal of the hemispheres in an animal does not arrest its If all the data I have
normal 'bodily movements under external stimulation^ because these movements are dependent upon func-
power
execute
to
tional structures situated in the base of the brain
and in the
and which the posterior pituitary probably governs. Of course, this appears to contradict at once a great mass of experimental and clinical testimony, but the contradiction Eemoval of the motor areas in the rabbit is only apparent. gives rise to no detectable differences in the movements; the In the dog, the injured animal is similar to an intact one. spinal cord
same procedure, according tion of voluntary
body”; hut this
to
movement is
Foster, causes “loss or diminu-
in the corresponding part of the
only temporary, and the animal
may
re-
cover to such a degree that the temporarily paralyzed limb
cannot be told from the normal one.
Careful examination of
the brain after death shows that no regeneration of the lost part
had occurred. Even removal of the whole motor area causes no appreciable difference between the movements of the two sides of the body to a casual observer. In the monkey the results have been unequal: “^^hile in some instances recovery of the movement has, in the monkey, as in the dog, after awhile taken place, in other instances the
be
permanent.”
.
.
.
“The
‘'paralysis’
facts,
has appeared to
however,
knowledge relating to the permanence of the
within
our
effect are neither
numerous nor exact enough to justify at present a definite as stated by Foster. “On the other hand, the positive cases, where recovery has taken place, are of more
conclusion,”
value than the negative ones, since in the latter the recovery
may have been hindered by concomitant events of a nature which we may call accidental.” I might add that a single case of recovery in the monkey, when the motor area has been completely
removed, demonstrates that, generally speaking, the structures are functionally similar in all higher animals, including man, judging from such instances as the crow-bar case, or
one reported by Brown-Sequard,^^ in which an entire
Brown-S6quard
:
Socidte de Biologie, 1876.
THE POSTERIOR PITUITARY AND THE NERVOUS SYSTEM.
504
was destroyed and in which the only syinptonig were amaurosis and slight headache. This emphasizes the identity lobe
of the cerebral hemispheres as
an aggregate of centers which
record impressions and are the seat of reason, intelligence, and
but
volition,
applicable in
also
it
word “motor”
suggests that the
its literal
sense to
tlie
is
only
areas in the lower cerebral
mechanism i.e., the intermediary through which the mandates from the hemispheres are executed. :
I
have previously referred
afforded by
misleading information
to the
Nowhere
the use of electrical stimulation.
organism does this seem to be more applicable than
in the to
the
brainl This feature and the complexity of the processes involved are fully emphasized in the following lines of the late Dr. Foster: “Some writers appear to entertain the conception that
movement, such
in a voluntary
that
as
the forelimb,
of
all
is that the Vill’ stimulates certain cells in the cortical area, causing the discharge of motor impulses along the pyramidal fibers connected with those cells, and that these
that takes place
motor impulses travel straight down the pyramidal tract to the motor fibers of the appropriate nerves, undergoing possibly some change at the place in the cord where the pyramidal fiber makes Junction Avith the fiber of the anterior root, but deriving their chief, if not their AA'hole, co-ordination from the cortex
itself:
starting-point.
tJiat
is
to
That such
say,
co-ordinated at their untenable and that the
being
a view
is
misleading are shown On the by tlie following two considerations, among others: co-ordination one hand, as was shown in a previous section, the simplicity of the electrical
movements may be namelv in the absence of
phenomena
carried
out
is
apart
from the cortex, and we can hardly
of the hemispheres ; be tAVO quite distinct systems of coshould there suppose that :
employed ordination to carry out the same movement: one some AA’hen Avhen A'olition Avas the moving cause, and the other thing else
led
to
the
movement.
On
the
otlier
hand, the
cortical analogy of speech justifies us in concluding that the by the processes do take adA'antage of co-ordination effected action of other parts of the nervous system.”
processes Deferring directly to the general character of the “Hence, while admitting, as involved. Professor Foster says:
505
THE PITUITARY AND THE BASE OF THE BRAIN.
we must
do, that in the intact
pyramidal tract play
animal the cortical area and
part
their
carrying
in
voluntary
out
movements, their action is not of that simple character supOn the contrary, we are posed by the view referred to above. driven to regard them rather as links true, but
still
links
—
in a
complex chain.
we may probably speak
urged,
—^important
links, it is
As we have
already
of the changes taking place in
the pyramidal fibers as being, on the whole, of the nature of
but we would go heyond the evidence if we concluded that they were identiccU with the ordinary efferent
efferent impulses;
impulses of motor nerves:”^-
All the features emphasized in
these quotations, especially in the last lines, appear to isolate the se,
me
to
hemispheres from the source of motor impulses per
and to confirm what experimental evidence obtained
removal of the hemispheres had suggested:
i.e.,
after
that the lower
cerebro-spinal structures constitute the executive intermediary
which the cortical mandates are actively realized. well Imown, these lower structures, in turn, manifest their activity through the centers imbedded in them; what is there to replace the energy in the form of motor impulses tlirough
Yet, as
which
is
is
erroneously supposed to be awakened by the “will” in
“certain cells of the cortical area”?
Professor Foster partially answers this question
“The
says:
much
when he
discussion in a previous section has shoivn that
body is carried out by the middle portions of the hrain, and on these the motor area must have its hold as on the spinal mechanisms. The details of the co-ordination of the
of the nature of that hold are at present
unlcaown to us.” It would appear from the facts reviewed that what might be termed the central brain and the spinal cord constitute an entity a mechanical entity, perhaps made up of working centers, beginning with the olfactory bulb and the other nerv-
—
ous
structures
anteriorly, i.e.,
—
distributed
to
the
nasal
mucous
membrane
and terminating with the end of the spinal cord:
the neural tract of lower forms.
—but
ordination, and sensation
Motility, unconscious co-
only, in the case of the latter,
to the extent of transmitting sensory impressions to their re-
The
italics
are
my
own.
— TUK rOSTKUIOR PITUITARY AND THE NERVOUS SYSTEM.
oUG
spective
perception-centers
—
^ivould
enter
witliin
scope
tlie
of
this central brain.
As
to the source of the transmitted energy or impulses,
apart from the sensory connections with underlying structures
—
which the cortex to
possesses,
^the
ascribe to the cortical areas
strates the
phenomena
predilection of most writers motor functions but demon-
need of such an agency to logically account for the
To
witnessed.
ascribe to the central brain or its
centers per se attributes of a similar kind to shifting to fictitious
it
would simply amount
a convenient, but unknouai, quantity, and a
one besides, in the sense that
account for something.
have so far traced to
In
tlie
its origin,
it supplies
nothing to
only nervous system that I that of the suprarenal .glands,
the conversion of chemical energy into neiwous impulses was
found to be a functional attribute of the anterior pituitary body. That so extensive a system as that represented by the central brain and cord should likewise need a center such as that represented by the posterior pituitary body for the conversion of some form of energy of external source to satisfy
the needs not only of
its
efferent,
but also
its
afferent,
im-
pulses seems clear.
That the middle brain is the source of the motor phenomena witnessed is not only suggested by the fact that normal muscular contractility promptly recurs after removal of the liemispheres, but also by the following experiment by Professor M. Duval: “If a part of the gray substance of the cortex designated as the center of certain movements is cauterized, the same movements are obtained when the electrodes are
applied
upon the eschar thus produced.
•
experiment shows,” says the author, “that the
.
gmy
.
This
cortical
the not a necessary experimental condition Indeed, he states that production of localized movements.”
substance
for
is
the underlying white substance of certain parts will also cause
circumscribed motions in certain groups of muscles, of the cortex of one side
etc.
followed by
Can the removal the assumption of compensative functions by the opposite side? After the usual period of paralysis, due to shock, the normal l)e
motions promptly recurred, precisely as they had on the other To ascertain whether the cortex at all possessed motor side.
THK PITUITARY AND THE BASE OF THE BRAIN. attributes
Vulpian passed an electrode through
the
was far more
easily
that part
The underlying
in contact with the cortex being insulated. white substance was thus alone stimulated. latter
it,
607
He
excited than the
found that cortex.
It
seems clear that in these experiments the increased excitability
was due
proximity of the central brain. “All the brain can persist,” saj^s Brown-Sequard, “after
to the closer
functions of
tlie
the complete destruction of an entire lobe.’”®
and
clinical evidence,
Experimental
however, only eliminate motility and co-
The
ordination from the hemispheres.
cortex, as regards cere-
bral localization, merely loses the “motor” attribute suggested
by the tenn “motor area,” and is shown, by its functional relations with the underlying structures, to be a vast sensitive surface, to the “areas” of which the term “sensory” might be
more fittingly applied. The practical bearing
of this
may
be illustrated by an
experiment that will recall some of the familiar features of the earlier portions of this
work and
to the central brain as the source of
same time point motor phenomena. This at the
experiment, referred to by Professor Foster, is as follows:
“It
has been observed that in certain stages of the influence of
morphine the cortex and the
rest of the neiwous system
are
in such a condition that the application of even a
stimulus to an area leads not to
momentary a simple movement, but to a
long-continued tonic contraction of the appropriate muscles.”
As previously shown, many drugs raise the hlood-pressure and thus congest the adrenals and indirectly the hrain. Cerebral hyperiemia, Ave have seen,
is
tlie
source of the majority of
phenomena that follow the ingestion
of drugs that are
ciently active to stimulate the adrenals.
The
suffi-
intense headache
and other agents is obviously due to this congestion of the cerebral vessels; muscular contractions, tetany, etc., are of quinine
also familiar results of suprarenal overactivity; indeed, digitalis,
one of tbe most active suprarenal stimulants, is particularly active in predisposing muscles to contraction and in experimental animals suitably dosed a minimal current without the drug will produce maximum effects prolonged tetany with it.
—
“M.
Duval:
Loc. cit, p. U5.
—
THE POSTERIOR PITUITARY AND THE NERVOUS SYSTEM.
508
In the course of the statements to which
I
have referred,
Foster, after ascribing the temjiorary paralysis obsen^ed after
operative interference to a condition “of the nature of shock,”
remarks:
“But, even giving
full
weight to this consideration,
there remains the fact that the cortical area
is
associated with
various co-ordinating and other nervous mechanisms belonging
limbs by such close
to the
ties
that these are thrown into dis-
when it is injured. And, side by side with this, we may put the remarkable fact, previously stated, that during an abnormal condition of the cortical area simulation of the area instead of producing the appropriate movements confined to the limb may give rise to movements of other parts culorder
—
—
minatmg
in epileptiform convulsions/’^*
If the word “associated” is given its full meaning, limbs and co-ordinating mechanism constituting one class, and the cortical
surface the other,
the
hemispherical mantle of gray
matter being considered solely as a great sensory surface, the de-
mands of experimental evidence seem to me to be satisfied. What are epileptic convulsions after all but manifestations of Can the latter ‘be credited e.xcessive motor activity? to the cerebral cortex, as is now taught in text-books? Ob.
.
.
viously not, since experimental evidence proves that the cortex
has no motor properties per
se.
But
irritation of this sensory
surface or an accumulation of physiological toxics, which peri' odically becomes sufficiently great to so stimulate the vasomotor
center as to
cause
sory cortex, but also of brain, are the
not only of the sen-
violent hypersemia,
clearl}'^
its
executive mechanism, the middle
defined causes to which physiological and
chemical evidence points.
Could the cortex without the middle
brain give rise to the same phenomena? case
shown by the preservation of
is
all
That such is not motor functions,
cluding co-ordination, after removal of the hemispheres. deed,
it
is
only
when
the middle brain
experimental animal thus deprived of of its
dynamic center lienee
it
All italics are
my
thing,
its
the in-
In-
removed that the sentient cortex and
is
practically loses its identity as a living
seems clear that the motor phenomena caused
own.
—
509
THE PITUITARY AND THE BASE OF THE DRAIN.
ly stimulation of the motor areas of the cortex are manifestations of activity of the central gray matter at the base of the brain, incited therein
by sensory impulses from these cortical
areas.
What so
evidently
preserved
The
lower brain?
this
constitutes
animals
in
co-ordination, their
hemi-
member
of the
of
deprived,
spheres, points to the cerebellum as a possible
Includ-
group of organs to be considered in this connection. ing this
the
therefore,
organ,
structures,
and beginning with
we would now
anterior
the
the posterior pituitary body;
have':
infundibulum; the central gray matter, fomiing “a bed
for the development of the nuclei of the cranial nerves”; the
tegmental system,
i.e.,
the reticular formation in the medulla
continued to the subthalamic region, and to which belong the red nucleus and
otlier
All
bulbar nuclei.
this
forms what
Poster so aptly characterizes as ^^a more or less continuous column of gray matter” connected with the spinal cord by various ties, besides being, as it were, “a continuation of the spinal gray matter.” It is as evident that the optic thalami and corpora quadrigemina are also members of the group, since these related organs appear to be necessary for the success of
the experiment in which both
moved. animal spheres,
cerebral
hemispheres are
Thus, referring to the frog. Poster says: it
is
“In
re-
this
comparatively easy to remove the cerebral hemi-
including
the
parts
corresponding
the
to
corpora
behind, intact and uninjured, the optic thalami
striata, leaving
with the optic lobes, the representatives of the corpora quadrigemina, the small cerebellum, and the bulb. be carefully fed and attended to, very long time If,
:
for
with this
illustration,
more than a
list
it
may
If the animal
be kept alive for a
year, for instance.”
we now examine the annexed from His’s work, and, therefore, not
before us,
originally
recently drawn, a rather suggestive coincidence appears, indicating, perhaps, a total independence, in the
region
containing
the
embryo, of the
enumerated
from the which subsequently develops into the hemisphere of the same side. In mammals the latter is at first insignificant, all
structures
vesicle
l)ut
it
develops
structures.
The name
The
very
rapidly,
soon
outline of the latter
of each part
is
overlapping is
given on the cut
the
middle
colored bluish gray. :
a feature that wdll
— THE POSTERIOR PITUITARY AND THE NERVOUS SYSTEM.
510
convey the mutual relations of the various structures included in this system than a verbal description. better
Again, the location of the posterior pituitary at the
head of the entire spinal system,
verj^
as shovTi in the illustration,
adds further testimony to that already submitted to demonstrate the functional relationship between the nervous struct-
ures lying in the posterior pituitary, including the floor of the
fourth ventricle, and the bulb.
A summary pituitary
of all these facts,
body has a
(1) that the posterior history Avhich distinctly
i.e.,
phylogenetic
identifies it as a part of the entire neural tract;
that
(2)
it
presents clearly defined histological characteristics of an active
neural organ; (3) that these characteristics extend to the infundibulum, the tuber cinereum, the floor and sides of the that these structures are continuous with
third ventricle; (4)
the reticular substance of the tegmental region, the medulla,
and tlie cord; (5) that the posterior pituitary body has been found to be in direct relation with the olfatory center and the bulbo-spinal axis in
all
classes of vertebrates;
that a
(6)
current passed between the olfactory and medullar centers
may
cause heart-inhibition and death; (7) that various nerve-centers are included in the structures with which the pituitary is functionally connected in is
all
vertebrates;
(8)
that sudden death
caused by a puncture in the region of the vagal bulbar center
through
interruption
of
the
efferent
and
through Avhich the cardio-pulmonary system
afferent is
impulses
incited to ac-
tivity and governed; (9) that electrical excitation of the exposed pituitary body causes an instantaneous rise of the blood-pressure
of over 100
mm. Hg.
the opposite,
i.e.,
(10) that removal of the pituitary causes an immediate and great fall of the blood-pres;
sure; (11) that division of the base of the brain across the path of nerves known to originate in the pituitaiy body prevents the action of drugs, such as antipyrin, which lower the temperature, and also the action of jnis and other septic materials which cause
functions carried on normally to cease by removal of caused after removal of the brain are the pituitary, seems to me to warrant the conclusion that fever; and finally (12)
that
all
:
The
posterior pituitary body is the chief center of the spi-
MEHIAN ANE ITERTICAL SECTION CF A TWC AND NE-HALF MONTHS’ EMBRYO,
[His.]
[CaiisidEra'hly Enlarged.] 1,
iiq.TiBduct of Sylvius,
Pons
2, Ivledulla Dblongata,
3, CsTB'bBlluiii.
Tubercula Quadrlgemina, B, PostBrlor TubBrcula QuadrlgBmlna. 7, Infundibulum and Pituitary Bodies. B, TubEr ClnerEum, B, Dptlc Thalamus, !, Fourth VBntriclB. 11, Hypoglossal IMetvb [Twelfth Pair], 12, Third VentrlclB, 13, 4,
yaTolil,
HemlsphETB
I
5, ilnterior
ITbsIdIb.
*
THE POSTERIOR PITUITARY
511
IN DISEASE.
system, and, as such the primary source of certain excitomotor impulses noiu hetieved to arise in the hull).
ml
Evidence.
Clinical
—^The
various
that
facts
have
I
enumerated in the summary in support of the conclusion just submitted being of a physiological kind, it seems evident that I
should, in view of the important functions ascribed to the
organ, also be able to adduce clinical evidence.
Indeed,
if
it
holds the important relation to the nervous system I believe it does, its influence in the pathogenesis of general neuroses
be very great. posterior lobe,
must
No disease having so far been associated with the it may prove profitable to seek among the symp-
toms of typical disease of the anterior lobe what signs might be assigned to implication of the posterior, with which it is intimately blended.
Acromegaly, which
may
be attended by irregularity of the
reflexes, paresthesias, localized pains,
plegia, etc.,
and known
to be
vasomotor neuroses, para-
due solely to lesions of the pituitary,
suggests itself as a profitable field of study in this connection. It is interesting to note, in this connection, that quite a
number
of
exceptionally able clinicians
for
instance —
sis,
the organic disease of
them
^liave
—von
Eecklinghausen,
considered acromegaly as a trophic neurotlie
pituitary being considered by
Again, the neural canal of lower' fonns
as secondary.
(as a whole) also produced a fluid capable of nourishing nervous elements and
led Collina^^ to suggest that the pituitary
that deficiency of this fluid, by reducing the
nutritional processes, gave rise to acromegaly:
activity
of tlie
further evidenec
and these organs is marked clinically to have attracted considerable That the various theories adduced also bear upon
that the tie between the nervous system sufficiently
attention.
nutrition of the nervous elements
favor of
my
view.
impaired nervous
is
practically all cases of aeromegaly
become
significant as testimony in
Indeed, the clinical signs that point to action are numerous, and are present in
sufficiently
when the
anterior lobe has
enlarged or functionally disordered to in-
volve the posterior lobe, either directly of tissue, etc., or indirectly
in the later stages, '“Colllna:
by pressure, continuity by overstimulating the adrenals, or,
by causing insufficiency of these organs.
Gazzetta degli Osped.,
.Ian.
8,
1899.
THK POSTERIOR PITUITARY AND TdE NERVOUS SYSTEM.
512
a previous chapter I have,
Ill
on good grounds,
I believe,
ascribed to overactivity of the adrenals the stage of “erethism,”
and
to insufficiency of these glands that of “cachexia.”
But,
if we ask how these states are produced by the adrenals, the answer which Avould not have been available before now seems to be within our reach.
have previously referred to the vicious
I
Though primarily
tains in acromegaly.
its
until well advanced:
own
i.e.,
Even
untoward sj’mpupon
until pressure occurs either
structure by the pathological
posterior pituitary.
that ob-
located in the anterior
pituitary, the lesion probably gives rise to no
tom
circle
elements or upon the
upon the whole organ, marked general symptoms.
slight pressure
shown by de Cyon,^® gives rise to But if the posterior pituitary is also considered as a factor the production of the symptomatic phenomena, as a source nervous energy, we not only have the vascular erethism as
in of
of
suprarenal overactivity, but distinct evidence of nervous ere-
thism besides. lines,
This
is
well illustrated by the following quoted
Gauthier’s definition of the erethic stage of acro-
i.e.,
megaly as given by Hinsdale^": “The phenomena of erethism which characterizes the first stage embraces, first, a painful hypcrcesthesia, which manifests itself in headaches and rheumatic pains; second, an hypertrophy of the muscular fibers which
may
give
to
patients
a
muscular power greater than
usual; third, palpitation of the heart accompanying the hyper-
trophy of that organ
;
and, finally, the polyphagia and polyuria
which may be considered of the activity.
respective
But
to be connected with
organs.”
an erethic state
Everything here points
to
these are only the milder manifestations.
over-
Tam-
burini, for instance, describes a case in which “the mental symptoms, on account of which the patient was sent to the
asylum, began to show themselves only a year before her admission.
They
consisted chiefly in delusions of suspicion ac-
companied by threats and acts of violence. The patient presented, in a marked degree, the bodily changes characteristic of acromegaly. While in the asylum she was confused, resistive,
De Oyon: HInsdulc:
Archives de Physlologie, July, Loc. ct7., p.
1^0.
189K.
— 513
IN DISEASE.
THE POSTERIOR PITUITARY
Only tlie anterior lobe was involved, the posterior presenting no change either in volume or sti’ucture.” This typifies the irritability or stimu-
and refused
{Uid suicidal,
lier food.
.
.
.
by pressure without organic change. The phenomena jiroduced are of another kind when both organs are involved in the morbid process, as appears to be
lation induced
and
the case in the following instance reported by Jolinston
patient, a woman, “was taciturn and and her memory was bad. Her utterance was thick and indistinct, as if her tongue were too big for her mouth. Her gait was slow and shuffling; her expression partly
Monro^“
intellect-
The
:
ually obtuse,
The skin of the the mucous surfaces are
melancholic, partly demented.
.
.
a
of
is
dull-yellowish
Hearing
.
The
ished.
.
tint;
.
pale.
Eeflexes are dimin-
somewhat impaired.
is
face
.
for
subject of these notes remained in hospital
She
about four weeks.
no
scarcely ever spoke, took
interest
She in anything, and slept about sixteen hours daily. was readmitted in September ^blind, more deaf, more drowsj'^, very feeble in muscular power. She could no longer rise without assistance. Control over the sphincters was lost. Paralyzed. For a couple of months before death there was a .
—
.
.
.
discharge of clear fluid from the nose.
body
is
much
.
represented by a large, red mass,
softer than
brain-substance.”
destroyed, the posterior lobe
The
.
.
The
.
.
pituitary
almost diffluent entire
organ being
had obviously followed the
fate
of its mate.
In a symptoms
case described
Pirie^® the history of the nervous
by
very clearly defined, though the author was un-
is
“The disease first when menstruation finally ceased.
fortunately unable to obtain an autopsy.
manifested
itself
in
1886,
Pains and pariestliesia of the arms and legs were
felt,
and
and feet were getting larger Along with the development of
the patient noticed tliat her hands
and more awkward. physical
.
.
.
symptoms a peculiar
took place.
alteration of mental
sluggish and irritable, and she suffered of
life.
.
.
.
much from
the ennui
Breathlessness on the slightest exertion ap-
Johnston and Monro: Pirle:
condition
Attacks of narcolepsy overcame her, she became
London Lancet,
Glasgow Medical Journal, August, Oct.
5,
1901.
1898.
THE POSTERIOR PITUITARY AND THE NERVOUS SYSTEM
514
and ultimately the muscle weariness so gained upon her that she had to take entirely to hed. Sensory disturbances are marked. Shooting jiains in combination with jicaretl,
,
.
paresthesia, tingling,
arms and
and numbness are complained
Xeuralgic pains are
legs.
of the body, viz.
:
tlie
of in the
felt also in various parts
A remarkfound in the lower front of the abdomen and chest up to about
the face, chest, back and loins.
able perversion of thermic
limbs and over
,
sensibility
is
the level of the fourth rib, the patient having no sensation of heat in these regions. Sternberg remarks particu.
.
.
on the occurrence of pain and parsesthesia
larly
valuable
as
signs for diagnosis in the early stages of the disease; they are
probably due, he considers, to changes in the cutaneous nerves.”
In a previous chapter
symptoms are impairment of both,
that
it
remarked
:
‘^Vhether the mental
certain functions of the pituitary itself, or to
now seems
evident
organs are involved in the pathogenic process.
If the
is
hotli
I
ascribable to the cereliral hvperaemia or to the
as yet
impossible to say.”
far-reaching meaning of this
fact
is
It
apprehended,
it
seems
—
hidden under the whole fabric of which we only now see the outline a truth of ovemdielming imporclear that there lies
—
tance to us physicians:
i.e.,
the fact that
it
is
not alone in
acromegaly that the typical signs of impaired function of the posterior pituitary appear, hut in other syndromes directly the adrenal system:
ascrihdble to
i.e.,
myxeedema, cretinism,
exophthalmic goiter, and Addison’s disease, which include in their aggregate the majority of organic changes of a morbid Irmd to which the system is liable, besides nervous phenomena. be briefly illustrated by further quotations from Dr. Pirie’s excellent paper, entirely devoted to the one case. As regards the muscular system, the author states that “mus-
This
cular
may
atrophy
is
a
prominent feature, affecting the thenar,
hypothenar, and interossei muscles of the hands, the forearmand arm-muscles, the calf- and thigh-muscles, and also the glutei,”
refers to Duchesnau,'®
and
“who has made
study of the atropliy of muscles in acromegaly. it
in
some
a
special
So marked
is
cases that it has been mistaken for syringomyelia.
Ducliosiiau
:
Thi'se de Lyon, iS9I.
515
THE POSTERIOR PITUITARY IN DISEASE.
progressive muscular atrophy, or amyotrophic lateral sclerosis;
has also been mistaken for Charcot’s cervical pachymeninEeferring to the gitis hypertrophica and for erythromelalgia.” it
“Its chromatogenous functions are disturbed,
sA;m, Pirie says:
much
rheumatoid
as in
Small freckles are frequent;
arthritis.
patches of a yellowish bronzing occur also
and the insides of the thighs.
chest,
on the
face,
Numerous small
ing such as occurs in Addison’s disease.)
many
(Mollusca fibrosa are described in
warts are present.
the
(Motais describes a bronz-
and xanthoma-like tumors by Dallemagne.) The patient from a brownish seborrhoea, especially troublesome in the scalp. The hair is thick and coarse and stands straight Profuse upward. There is a scanty beard and moustache. cases
sufi'ers
The heart
perspirations are constantl}'^ complained of.
There
lated.
the minute.
is
A
tachycardia, the heart beating about
soft, systolic, basic
Palpitations and fainting
fits
murmur
is
di-
is
98 to
heard at times.
Dyspnoea
occur very often.
is
marked, and asthmatic-like attacks occur, during which the patient has to
“The soft The scalp .
.
.
lumbar
sit
up
in bed
and
fight for her breath.”
.
.
.
parts are remarkably changed as well as the hones. is
much
thickened, as
is
also the skin of the face.
In addition to the kyphosis there is a compensatory and also a certain degree of scoliosis. The are enormously hypertrophied. The ribs are thick-
lordosis
clavicles
ened and expanded, the costal cartilages feel bony, and there are
nodular projections resembling the
Tachitic
the junctions of the ribs and their cartilages.”
chaplet’
.
at
“With
.
.
regard to the organs of special senses, the skin of the eyelids is thickened and puffy. The lacrymal glands are hypertroIncreased
phied.
laerymation
occurs
at
times,
noticed a colloid-like secretion between the
“There
and I have
ej^elids.”
.
.
.
amblyopia, nearly complete in the left eye, and colorvision for blues and yellows is defective. Bitemporal hemiis
anopsia
is
The pupils contract in accommodation and though very sluggishly in the case of the left the ophthalmoscope optic atrophy is found.”
present.
react to light,
With
eye.
“She suffered much
at this time from polydipsia and and for over twelve months there was an almost constant dribbling of saliva from the mouth. The .
glycosuria,
.
3.3
.
.
— THE POSTERIOR PITUITARY AND THE NERVOUS SYSTEM.
616
thyroid
-vvas
greatly enlarged, but under treatment with thy-
much
roid substance it diminished
how dependent
the
suprarenal system
“It
organism
when
in
upon
is
size.”
We
tlie
integrity
have seen the
of
infectious diseases develop.
I
can fully agree with Harlow Brooks-' wlien he says:
is
quite natural to expect pronounced abnormalities in the
various portions of the nervous system in a disease which exhibits so
many
neurological symptoms”; and his statement that
“examinations of the nerve-tissues have shown quite extensive
and general changes” further sustains dence of this kind, garnered from all
my
feature it serves to support
of,
the strongest kind.
is
thought
Evi-
deductions.
sides
long before the
me
appears to
words, therefore, rather than
my
own, when he reviews the
pathology of the disease, and which seems to
me
portray
to
parvo the main landmarks of neurological pathology.
in
of
again prefer to use the author’s own
I
I
have only omitted those of the author’s own estimates that do not bear directly upon my subject and what text was not purely descriptive: ‘‘Peripheral Nerves are,
for
tlie
.
—The
trunks of the peripheral nerves
most part, enlarged; this
is
due to an
directly
increase in the connective tissue of the endoneuriuui and peri-
neurium.
Often the sheaths of the nerve-trunks also show
This general connective-tissue
considerable thickening.
hj'per-
plasia frequently so encroaches on the nerve-fibers as to destroy
them, and degenerated nerve-fibers are quite commonly found
some of which may show complete (Arnold, Comini).
These conditions
the entire nerve-tnmk,
destruction
axis-cylinder
may
persist throughout
extending even into the nerve-roots.
(Arnold, Duchesneau.)
“Ganglia
.
— In
connective-tissue
macroscopically
the posterior-root ganglia, also,
elements
greatly
the ganglia
are
increased,
often
we
so
considerably
find the
even
that
enlarged.
Idicroscopically the ganglionic cells are sometimes pressed upon
Arnold reports that he and atrophied (Marie, ]\Iarinesco). found vacuoles in the nerve-cells. In Cases I and II of the author’s, the alterations in
« Harlow Brooks: Archives 1898, p. 692.
tlie
of
ganglion-cells were slight.
Neurology and Psychopathology,
vol.
1,
No.
4,
THE POSTERIOR PITUITARY
517
IN DISEASE.
detemiine whether the nerve-cell lesions are secondaiy, perhaps directly dependent on the connectivetissue hyperplasia about the cells and fibers, or are primarily “It
is
difficult to
Perdue to defective nutrition of the ganglion-cell bodies. haps these ganglionic changes are wholly, or in greater part, responsible for the degenerations and atrophies which take place in the muscles of the voluntary system.
—The
changes in the sympathetic ganglia and trunks have been made the subject of special study by several very prominent investigators, among whom are Marie, Marinesco, and Arnold, and have been looked upon by ‘‘Sympathetic
many
Qancjlia
.
Finding, as we do,
as factors of an etiological nature.
such pronounced change
in the blood-vessels,
at all strange that lesions in
it
does not seem
the sympathetic ganglia should
be present; but a view intimating a dependence or relation of the vascular changes to the lesions in the sjmipathetic sys-
tem
is
not in accordance with our oivn ideas expressed at the
close of this
In general, the changes in the sym-
paragraph.
pathetic ganglia are very similar to those already described in
the ganglia
and trunks
of the cerebro-spinal system.
cases the size of the ganglia
In some
considerably increased (Arnold,
is
Marie, Marinesco), and, microscopically, the connective-tissue
web
.
.
thickened
is
often
reported .
“Arnold
The
and proliferating. as
has
exhibiting
found
ganglion-cells
evidences
of
vacuolization;
are
degeneration.”
not
infrequentl}'^
considerable deposits of pigment are seen within the cytoplasm.
may
But, as in Case II, the ganglion-cells
be normal; the Nissl
bodies are present in normal arrangement, volume, and shape,
and show no deviations in their staining reactions; and the pigmentary deposit is not abnomially abundant. The sympathetic ganglia in the case reported by
normal.
It
is
Gauthier were also
advisable, at this point, to call attention to the
fact tliat the interstitial hyperplasia is
characteristic of the sympathetic system,
by no means a lesion but is simply an ex-
tension of the general process so often alluded to.
The growth
may depend in part on lesions in the walls of the vessels or both may be referable to tlie common factor of deranged nutrition. Cord and Medulla The pathological findings in both of
eonnective tissue in the sympathetic ;
.
—
— THE POSTERIOR PITUITARY AND THE NERVOUS SYSTEM.
518
the cord and medulla differ greatly.
Virchow, and also Fritsche
and Klebs, have rejjoi-ted hyiiertrophy of the medulla. The was enlarged in the case reported by Linsraayer.
spinal cord
observers have reported various degenerations in the Baruch’s case was associated with symptoms of S 'ringo3 myelia; Debierre gives a case with diseased posterior columns, j\Iany
cord.
while Arnold, Dalleraagne, and Tamburini have found at autopsy irregular degenerated areas in the cord, affecting, however,
no
any degree of constanc)^”
special place with
That the trophic
changes
in
the
nerve-tissues
explain
and myological symptoms in acromegaly is obvious, but these occur in advanced cases, •i.e., when such morbid changes have had time to occur. The signs which several of the neurological
point to the posterior lobe as the seat of an important center in keeping with physiological data enumerated
occur during the early or erethic stage,
viz.,
on page 510
the painful hyper-
numbness, the vasomotor neuroses and the palpitation. Their presence is explained by the marked rise of blood-pressure produced by irritation of the pituitary body proper, observed by Cyon, and confirmed by Masay, and by the long-recognized identity of the posterior pituitary as the neural lobe, its h istology and nervous connections. sesthesias in the extremities, the tingling,
Pending additional evidence in this direction the nature of the process through which the pituitary influences the nervous system requires study.
THE HISTOLOGY AND PHYSIOLOGICAL CHEMISTRY OF THE NEURON.
We
are first brought to inquire into the relationship between the modern conception of the structural composition of the cerebro-spinal axis and the views 1 have submitted.
Granted, therefore, that
tlie
seat of a process through
posterior
pituitary
which chemical energy
body is
is
the
converted
into nervous ciiergj', and that this constitutes the nervous impulses which the cerebro-spinal axis transmits to the various
organs,
how do
the nerve-elements utilize this
energy when
functionally active? I
logical
WaldeyeFs neuron as the morphounit of the cerebro-spinal axis, and the processes of
refer,
of course, to
— 519
THE PHYSIOLOGY OF THE NEURON. /
which are not in contact, but other, as to
make
it
possible,
sufficiently
when
close,
one to the
required, for a nerve-impulse
These facts have been to cross the interval between them. satisfactorily established by modern methods, especially through
and Eamon y Cajal.
the labors of Golgi
But the manner in he., how the closed
— —
which the gap between the processes is impulse passes from the terminal brash of the axon of one nervous element to the dendrites of the next is still to be
been suggested, however, that the processes behave, in a limited manner, as do the pseudopodia of the amoeba, and that by a slight extension the interval between It has
determined.
the processes
When
closed.
is
the processes are not in con-
be in a state of “retraction.” Much as such a function would facilitate and shorten our anal^dical work could incontrovertible e.xperimental facts be adduced to tact they are said to
by a review of tlie literature of the Indeed, subject, to recognize that such facts are not available. the majority of physiologists and neuro-histologists now consider the question of “amoeboid movements of the neuron” in the light of a working hypothesis. There is one feature of the investigations in this direction which may serve to throw more light upon the whole quessustain
we
it,
tion if one
me
are brought,
of the
in the present
more prominent deductions submitted by i.e., the work is taken into consideration :
fact that certain drags cause overactivity or insufficiency of the
adrenals.
Much of the physiological work done in connection with neuron includes the administration of various toxics,
the
—
strychnine, chloroform, morphine, etc., and amoeboid movements or other active manifestations of the protoplasmic processes
are thus ascribed to the action of the
neurons of
drugs upon the
views, the changes
form witnessed should be ascribed to increased or reduced
when
blood-supply
meaning sents
I
one
Demoor.
will
of
toxic doses
give in
the
the
complete
are
given.
To
illustrate
outline an experiment
key-stones
Before doing
to state that I will
to
my
whereas, in the light of
'per se,
of
the
entire
my
which repre-
tlieoiy,
that
of
may, perhaps, be ivell consider the terms "neuron" as applying this,
neiwe-cell,
however,
it
including processes;
"neiiraxon"
— THE POSTERIOK PITUITARY AND THE NERVOUS SYSTEM.
520_
to the (usually) single aiul long jirocess
the center of the nerve-fiber, and
is
which extends along then called “axis-cylinder;
—
many processes some of which end in many branches or tufts other than the neuraxon. With F oster and Sherrington Ave will consider that neuraxons carry “dendrites'’ to the cell's
—
impulses away from the into the cell.
Two
—
cell, while dendrites transmit impulses other prominent morphological features are
the “gemmules” minute projections all along the dendrites and their terminal twigs, Avhich recall those on the stems of
the moss-rose, and the varicose, or irregular, swellings that may be observed in the course of the dendrites or their terminal tivigs.
The experiment
of
Demoor was
He
briefly as follows:
dog by injections of morphine; a second dog was given morphine for some time, then killed by cutting the medulla; a third was trephined. The next day a piece of the left hemisphere of the latter dog was removed; the animal being then morphinized, another piece ^but of the right hemisphere this time was removed. Portions of the hemispheres of the two killed dogs having also been removed, all specimens were The cellular changes treated in precisely the same manner. were found to be similar in all specimens taken from the morphinized animals: their gemmules had disappeared. Alone of the series the piece removed before morphine had been given Now the Avas covered Avith regularly distributed gemmules. h-illed
a
—
—
fact I
wish to emphasize
is
this:
Avhile
this
experiment
is
thought by its author to show that the retraction of the gemmules constitutes the inactiA'e state, as induced by morphine through the local action this drug is noAV thought to have upon nerve-cells, the retraction of the gemmules is due to general Amsoconstriction
of
all
arterioles,
including
those
of
the
ad-
by a direct action of the morphine upon the sympathetic We thus have, instead of a purely center. (See page 1272.)
renals,
an example of the general physiological process through Avhich the neuron passes from the active to the passive state, the circulation of oxidizing substance in the neuron being local effect,
thus inhibited.
Again, the same structures treated by different methods have been found to yield different results. Thus; H. H. BaAV-
:
521
THE PHYSIOLOGY OF THE NEURON.
dcii" found that “all material treated according to the slow method of Golgi shows, as a rule, an almost absolute freedom
The varicose cells occasionally occur.” from varicosities practically yield found to rapid were the mixed method and the same results when the dendrites had taken the stain: the In gemmules were almost invariably present and regular. in others some sections almost every dendrite was varicose; hardly any. All these results were similar whether nonnal or ;
“toxic” material was used, and the author concludes that “it is
impossible for an unprejudiced observer to differentiate or
between the two kinds
distinguish
who has upheld clusion
that
of
retraction theory,
tlie
“imperfect fixation
is
Lugaro,^®
material.” also
reached the con-
very largely, though not
entirely, responsible for the
formation of varicosities and the
disappearance of ge.mmules.”
Weil and Trank summarize what
a review of the literature of the subject shows,
“The
are
there
.
—
Demoor and .
.
records
occasionally
contradictions,
of
when they
say:
findings have been in almost every case positive, although
as,
of
for
of
example,
negative
results
between the
Soukhanoff on the
effects
and even
investigations of
chlorofonn.
Eetraction of the gemmulse and coincident swelling of
the dendrites form the essential features of every description.”
Judging from the foregoing estimates as to the effects upon dendrites, these phenomena are to be considered as artifacts: he., as artificially produced changes. Under stains
of
these conditions,
it is
clear that the latter should appear, irre-
spective of the condition of the animal at the time of its death
whether under the influence of toxics as stated, fatigue,
he., etc.
That prevailing views
my
in this connection are erroneous
is
fimi belief after a critical analysis of available experimental
evidence.
and valuable in this conH. H. Goddard,^^ which con-
Particularly instructive
nection are the experiments of
sisted “in cutting through the entire head of the animal at a single blow with a very thin sharp knife, the parts of the head falling instantly into large dishes of Cox’s solution warmed
“
H. H. Bawden: Journal of Comparative Neurology, May, “Lugaro: R1 vista dl patol. nerv. e ment, vol. iii, 1^98.
*
H. H. Goddard: Jour, of Corapar. Neurol., Nov.,
1898.
1900.
THE POSTEUIOU PITUITARY AND THE NERVOUS SYSTEM.
522
to 39° C. old, sisters
what
tired,
Ill
liis
first
experiment, puppies about seven veeks
from the same
litter,
were used, the one while somc-
the other after having slept.
pyramidal
A
careful count of
somewhat fatigued cells showing varicosity, while cells from the same region of the puppy killed after sleeping was 8.5 per cent. In the former animal 15.9 per cent, of the cells showed much varicosity; in the latter only tlie
cells
of the
cortex of the
J3uppy gave a proportion of 31.1 per cent, of
In the second experiment
0.8 per cent, shoived a similar state.
on waking in the morning; the second at night when tired and very sleepy. While it “was
the
lii*st
of
two
difficult to find
sisters
was
killed
a single varicosity on the dendrites of the morn-
ing puppy, for long distances in the cortex of the. evening
puppy” it was difficult to find a cell “whose processes” were It is evident that in these in“not more or less varicose.” stances at least the stain was not alone the source of varicosities, since it was only in the tired puppies that the varicosities
were very marked, while in the thoroughly rested animal
none could be found. Judging from these experiments,
practically
drites
varicosity
coincides with a fatigued condition.
of
the
den-
This corresponds
exactly with the experiment of Demoor, previously described, since retraction of the gemmules is accompanied by varicosity; •
so that fatigue
duced similar
and a large dose
of
morphine must have pro-
results.
If the staining process alone caused the formation of varithe same method having cosities in Demoor’s experiments,
been used for
all
specimens,
—how
—
is
it
that one of the latter
showed gemmules (which means absence of varicosities), and that tliis solitary specimen is precisely from the only animal which had not received morphine? Berkley-® found that poisoning with alcohol “in considerable doses, continued over a moderate time, ivill produce decided and ascertainable lesions of the nutrient structures and nervous elements of the cerecharacter to the pathological lesions produced by otber more virulent soluble poisons. The terminal
brum”
very' similar in
twigs of the dendrites were also found to have become varicose “Berkley: Brain, vl,
1897.
W'inter,
1895;
and Johns Hopkins Hospital Reports,
vol.
523
THE PHYSIOLOGY OF THE NEURON. gemmides being very scarce or
or beaded, the again,
may
is
a condition which,
add, chloroform, chloral hydrate,
wc
and other toxics used
and others with similar results, all tend in the one
by Demoor direction:
Here,
absent.
as 'does fatigue, moi’phine, and,
i.e.,
This
to morbidly reduce functional activity.
a wcll-lmown characteristic of the bromides.
is
a study of the
In
under the influence of poisonous doses of potas‘‘If the primal ascending sium bromide, H. K. Wright^® says several ampullous teraiination, dendron is followed to its visible cortical cells
:
or varicose swellings of varying size are
“on the basal processes
also
varicosities
met with,” are to be
.
.
seen
;
.
but
they are small and, like those of the ascending protoplasmic process, are sharp in outline, and shorn of the lateral projections which
obtain on the unaltered part of the extensions.
One may be seen on each secondary branch, and ranges in size from a small and scarcely recognizable to a readily obvious swelling. None of them, however, reach the dimensions of the apical projection and its branches.” If the method of staining is the cause of all this, we are brought to tlie conclusion that it must be selective as to the parts of the dendrite it affects, and that only functionallyimpaired cells are so affected by the stain as to show varicosities. Even tlien staining methods would furnish precious indications. But it seems clear to me that, while the newer chrome-silver methods
still
furnish imperfect pictures of the
morbid alterations of the neuron, they cannot with justice be said to either cause or prevent the formation or disappearance
of
gemmules and
varicosities;
in
other words, that they are
The marked tendency
not artifacts of the Golgi method.
of
the swellings to locate at the apices, and the gradual reduction of the varices as the cell-body
is
approached
other hand, a well-known pathological principle
morbid
effects
:
impaired general nutrition are
of
recall, i.e.,
on the
that the
first felt
by
terminal structures.
And
the painstaking experiments of Weil and
not appear to
me
Frank do
in the least to prove their conclusions that
“the varicosities must be regarded as artifacts” and that “they
“
H. K. Wright:
Brain,
Summer,
1898.
THE POSTERIOU PITUITARY AND THE NERVOUS SYSTEM.
524
depend for their presence and their amount on the form and of.” Demoor employed the same method in
method made use
each of his comparative experiments and his results were not similar, tlie non-morphinized specimen alone differing
from all comparative experiments, and likewise obtained results which distinctly showed a marked difference between the rested and fatigued animals. In these and other experiments referred to,
Hubbard used
others.
the
patiliogenic
the identical
method
in both his
including fatigue, was
agencj'',
allowed
cient time to produce alterations in the cortical cells,
if
suffi-
nutri-
tion has anything to do with the process.
In Weil and Frank’s experiments the animals were overwhelmed by the quantity of toxic administered, and death occurred, viewed from my standpoint, by arrest of the adrenocardiac functions, long before any marlced action upon the cells The doses of morphine admincould possibly have occurred. gramme istered were 0.38 and 0.41 (6 and 7 grains), respectwith death in 15 minutes; of strychnine nitrate, 0.018 gramme (Vs grain), death in 20 minutes; of hypertoxic urine, ively,
125 to 150 cubic centimeters (4 to 5 ounees), death in 15 to 25 minutes. evident.
—
meters
That these
are overwhelming doses in rabbits
is
killed with serum (30 cubic centiminutes; others with clhoroform inhala-
One animal was 1 ounce) in 5
by tracheal clamping in 8 minutes. The rest, six animals, were destroyed instantly by instrumental procedures. In none of these animals was there any distinction tions in 10 minutes; one
had been sleeping, eating, or romping, etc. That some were old and others young in the series of nineteen is probable as is well known, erethism, espeestablished as to whether they
;
cially in
such delicate structures,
is
greatly influenced by age,
and a few months in the rabbit represent as many decades in man. The weight of each animal was not recorded in order to establish
the relative action of a given
dose of the
to.xic
used per pound of animal, though, of course, in the experiments, the large doses used precluded any usefulness on this score.
Finally, the authors themselves will surely admit that “no and “very varicose,” “slightly “varicosities,” varicosities,” slightly
varicose,”
the
method of notation
utilized
by them,
—
;
526
THE PHYSIOLOGY OF THE NEURON. conveys but
Ami
exact information.
little
even this sus-
still,
Indeed, the short period
tains a deduction oiiposite to theirs.
toxics in the of time that elapsed between the injection of the animals killed in this manner represented by 108 blocks of
—
slides
—^must
have
sufficed
mules and the formation of cent, of these blocks show no
of
retraction
initiate
to
varicosities,
since only
the gem10.3 per
When, on the other
varicosities.
hand, the proportion of animals killed instantly by instrumental procedures 93 blocks of slides is analyzed, over two
—
—
and a half times as many, no
f.e.,
28 per
cent., are
found
to
show
varicosities.
But a
Why
fair
question suggests
itself
do the remaining 72 per cent,
in
this
connection
show any varicosities?
Only 14 per cent, of the blocks from the instantly killed animals are recorded as “varicose,” the remaining 58 per cent, being entered as “slightly” or “very slightly” varicose. In their explanation of the scope given these terms, the least
some
Now,
cosities.”
and the second
varicosities”
first
as “only very
means “at few
vari-
the authors state that “in the first nine cases
here recorded the brains were placed in fixing fluids within three to five minutes.”
we may
Nothing
is
said of the rest; so that
immersed
infer that the ten other brains ivere
longer intervals.
We
sion of myosinogen
after
have previously seen, when the conver-
myosin was studied, that oxidation i.e., until all the oxygen That this must be the case with the brain, into
processes continued even after death:
had been utilized. which contains one-fifth of the blood the entire encephalon is evident.
whole body, and
of the
that products of metabolism, especially
CO 2
,
should form in
It normally follows that
we
have in this factor a potent cause for the retraction of gemmules and the formation of varicosities. Indeed, the contrast between the for itself to
when compared
to
results
reached speaks
those of Goddard,
who
resorted
procedures in which the exact condition at the instant of
death were preseiwed, “the parts of the head falling instantly into large culture dishes warmed to 39° C.” Even continua-
normal brain temperature was insured. And what “It was difficult to find a single varion the dendrites of the morning puppy,” i.e., the thor-
tion of the
were Goddard’s results? cosity
526
THE POSTERIOR PITUITARY AND THE NERVOUS SYSTEM.
oughly rested animal; while in the thoroughly tired one “for long distances in the cortex it is difficult to find a .
.
.
whose processes are not more or less varicose.” That fatigue is the result of an accumulation of products of metabolism and especially CO, is generally recognized. cell
Goddard’s procedure appears to
me
to represent as nearly
perfect a one as available staining methods (Cox’s and the rapid
method show considerable parallelism in Weil and Frank’s report, while the mixed and slow methods appear unreliable and contradictory) will allow; his results, in my opinion, portray the actual changes that are produced in the neuron under the influence of certain poisons and during sleep: i.e., when the hlood-supply of the hrain is reduced.^’’ (See plate p. 1264).
Weil and Frank state that they
‘^are
able fully to cor-
roborate the statement of Cajal that normal and toxic material
of
cannot be differentiated by the number of varicosities or
The
gemmules.”
care with which such experiments
must
be conducted, apart from the method of staining adopted; the
need of immediate immersion, and other details to which we have referred, invalidate any opinion that the distinguished Spanish histologist he can show
may have
that his
e.xpressed
experimental
on
this
score,
physiological
procedures
were as perfect as his staining work must have been. 1
must
unless
Indeed,
express the belief that the greater part of the physio-
work done so far in this connection is valueless owing to the absence of the precautions to which I refer. histological
Again,
Eamon
y Cajal’s conclusions that “the nen^e-cells
do not move, but on the other hand, that the neuroglia-cells do move” (which underlies his view as to the gemmules and varicosities showing no difference Avhen normal or “toxic”), has been
sliown
liy
Dercum
to
embody
its
own
refutation.
“Cajal,” says the latter author, “points out the fact that the processes of the neuroglia-cells have numerous short arbores-
” We wish to particularly emphasize the fact that we are in no way criticlsing adversely the work of Drs. Weil and Frank. We have nothing but praise to express for these investigators. Much of the searching inquiry to which we are submitting their paper Includes the use of features introduced for the first time in the present w'ork, and obviously unknown to them. Indeed, if our views eventually prove to bo sound, we will owe much to the counter-evidence Drs. Weil and Frank and, we may add. Dr. H. Heath Bawden have published. S.
—
—
627
THE PHYSIOLOGY OF THE NEURON. cent and
plumed
and
collaterals,
states that in these cells
lie
two different phases can be obseiwed: tion,
—that
is,
first,
a stage of contrac-
which the cell-processes become shortthat stage in which the cell is relaxed,
a stage in
ened; and, secondly, a
—
is, a stage in which the processes of the neuroglia-cells are elongated. He maintains that the processes of the neuroglia-cells
represent an insulating and non-conducting material, and that
during the stage of relaxation these processes penetrate between the arborizations of the nerve-cells and their protoplasmic processes,
and
make
so
difi&cult
or impossible the passage of
the nerve-currents; on the other hand, in the stage of contraction the processes of the neuroglia-cells are retracted,
no longer separate the processes of the latter
are thus permitted to
come into
nerve-cells,
contact.^^
and they and the Evidently
Eamon y Cajal admits the very thing against which he contends, for if the nerve-cell processes are at one time not in and at another are in contact, they must certainly move, and the question before us is self-admitted. It matters contact
not whether the processes
of
much, but that they move at
the all is
nerve-cells
move
little
or
the question at issue, and
Eamon
y Cajal admits, though he malces the movement a purely passive one.”““ To me it appears clear that, since
this
Eamon y
Cajal held the neiwe-cell to be a passive structure,
requiring an independent connecting-link to close the circuit
with the adjoinng cell, he must have denied both the gemmules and the varicosities any physiological importance. His opinion, therefore, that normal material cannot be differen-
from toxic .material, when applied to the retraction of gemmules and the formation of varicosities, cannot be said to rest upon solid premises, and, for the time being at least, to in no wise affect the question. tiated
In a comprehensive review of the anatomy and physiology of the neiTOus system,. L. F. Barker^®
marks:
“The
makes the following
re-
physiologist of the present day sees in the func-
^ We win see farther on that Cajal’s observation as to the relaxation and contraction of neuroglia-cell processes is valuable In that it proves that the tips of the gemmules do not transmit nervous energy. S. -"Dercura: University Medical Magazine, April, 1897.
—
L. F. Barker:
New York
Medical Journal,
May
15 cl acq., 1897-98.
— THE POSTERIOR PITUITARY AND THE NERVOUS SYSTEM.
528 tions
the nervous system, even ia those which are most complicatxTl, only certain manifestations of energy. Moreover, he believes tliat in neurons, as in all other cells of the body of
and
as in the world generally, the law of the conservation of energy during transfonnation holds, and consequently regards
phenomena of irritabilit}', as CA’hibited by a neuron or by groups of neurons, as the kinetic representative of the potential forces of the cells and their foodstuffs. The metabolic the
and the
activities
vital manifestations of the cell are
—another
tant processes
which
concomi-
example of the inseparable connection
between what we terra matter and energj". There has been in man}' quarters a certain amount of hesitancy in exists
accepting the view that the capacities of the nervous system, particularly those of the brain,
chemical and
the
going on within it
has in
happily
tlie
now
physical
constituents
its
past proved
are
a
which are continuall}'
a hesitancy which, though
:
serious obstacle
to
For the plant,
disappearing.
fast
dependent directly upon
alterations
progress, all
is
the evi-
dence goes to prove that under the influence of sunlight and heat marked chemical and physical changes take place witliin it
be
which we recognize in
its vital processes.
In the animal
granivorous, camiyorous, or, like man, o.mnivorous
it
—
it
is
the cliemical energj' introduced as food which represents, in
the main, the source of the energy of the organism.
The
.
physiologists have been struggling for fifty years or
.
.
more
gain an insight into the nature of tuhat they call nerveimpulses, by which is to be understood the occurrences inside to
axons: to
for example, at the time
believe
Their
that they
efforts
are
when we have good reason
functionally
have supplied us
witli
extraordinarily
active.
a multitude of data, phys-
and chemical, interesting enough, no doubt, but which can serve as only the barest prolegomena to an explanation of the ical
essence of the" occurrences.
If
we
are so badly informed con-
cerning these elementary and fundamental phenomena we
may
very well be content to be modest for some time to come in our
claims as regards a physiological psychology. impossible that in
concerned which
which
yet
the nervous
system
do not exist outside
remain
to
be
recognized
It
is.
by no means
forms of energy are body and
the animal
and
studied.
.
.
.
529
THE PHYSIOLOGY OF THE NEURON.
Truly, to find out the properties of a single neuron would be a task appalling enough; but, when we remember that of the
no two are just But instead of burying
millions of neurons in one individual perhaps alike,
the quest would seem hopeless. pessimistic
in
ourselves
or
reflections,
being discouraged by
by what may perhaps forever remain to us unknowable, we may profitably turn to the consideration of some of the points which, lie more within our ken. One point, self-evident enough when one’s attention is
what
is
at present unattainable,
directed to
it,
hut which often appears to have been overlooked is the unremitting character
in connection with the neurons,
With a metabolism
of their activity.
occurring within the nerve-units
is
it
as complicated
as that
inconceivable that there
can be any period in which alterations in chemical structure,
and consequently energy transformation, are not going on. From moment to moment, throughout all the hours of the day and night, analytical and synthetic processes are taking place, associated with the alterations in physical forces
necessarily
accompany these changes.
thing that
lives,
the neurons
which
In common with every-
know no
absolute repose.
As
I
have said, in speaking of their metabolism, periods of extrava-
gant activity
may
alternate with
change, but total rest istence.
We
is
periods
more economic
of
inconsonant with continuance of ex-
are forced to
believe
that what
we
ordinarily
speak of as the passage of a nerve-impulse represents, as
it
were, a stormy process in the nerve-fiher, and that just as absence of a storm does not
probability
minor
mean
absence of weather, there are in
—
all
—
currents, if you will passing and fro in a given nerve-fiher in the intervals between the more violent excitations.” The words that I have italicized will doubtless recall some of the more prominent features previously emphasized alterations
to or fro or passing to
in respect .to
functions
of
the relative nervous the
various
organs
processes
reviewed.
involved I
have
in
the
termed
“passive” that form of energy continuously transmitted to tissues and vessel-walls. A quiet and steady flow of blood into the cellular stnictures, sustained by the tonic contraction of the arteries, and a stream of nervous impulses to the tissues coinciding in rhythm, perhaps, with that sent to the vessels.
THE POSTERIOR PITUITARY AND THE NERVQUS SYSTEM.
580
suffice to insure mitritiou
and
plied read}^ for active work.
to hold the structures thus sup-
What
is
the source of this energy?
If the posterior pituitary reinforces tlie flu.x of impulses
when seem
functional
activity
is
demanded,
and
to require another source,
brain and the cord are included in
energy would
jiassive
as the lower, or middle, tJie
‘^sphere of influence”
of this organ, the hemispheres are the only parts of the en-
cephalon that can supply of
tlie
But they do
need.
Bemoval
not.
hemispheres, we have seen, does not impair muscular
tlie
jump, a pigeon can fly, etc., and, after a period of shock-paralysis immediately after the opera-
activity; a frog can sJiort
movements
tions,
return
—evidence
that
nutritional
their
metabolism, incited and regulated by nen-ous impulses, conEvidcntljq
tinues. to
hemispheres have nothing
the
therefore,
do with the process; they are solely the seat of the “mind,”
and constitute an organ among the vasomotor
nerves
(
nutritional nerve-system.
et al.),
We
are,
supplied with
itself
Gulland,
Obersteiner,
Cavazzani, Frangois-Franck,
rest,
Huber,
Hurthle,
and probably with its own therefore, brought back to
the posterior pituitary as the only organ capable of satisfying
the needs of the situation
:
i.e.,
as the only source of passive
energy.
This suggests that metabolism
may
through the
suffice,
agency of the blood’s o.xidizing substance, to sustain physioduring the intervals between “stormy processes
logical activity
of the nerve-fibeF’; but this
is
promptly shoAvn
to be a
wrong
interpretation Avhen the effects of section below the medulla are recalled. diately
As
relaxed,
all
the arteries of the organism are imme-
a continuous stream of impulses
served to hold the vessels in tonic contraction jiassive
must have
evidence that
a factor to be reckoned with. Thus, co-ordinated muscular movements continue
nervous energy
the fact that all
:
is
after removal of the hemispheres relegates to the lower brain
the
function
of
supplying
active
energy
—and,
passive energy likewise, the need of the latter being division of the medulla.
Indeed, passive energy
described as passing to and intervals
between
tbe
more
obviously,
shown by
may
well be
fro in a given nerve-flber in tbe
violent
e.xcitations,
while
active
energy can as fittingly be likened to “a stormy process in the
— 531
THE PHYSIOLOGY OF THE NEURON. both ascribable,
nerve-fiber”:
it
now seems
liirely,
to the one
organ, the posterior pituitary body. establish the functions of the posterior pituitary within
To its
proper physiological limits, however,
it
is
necessary to as-
elements in general and neurons in par-
how nervous
certain
ticular are nourished, since it
is
upon the degree
of perfection
with which the nutritive processes are carried on by the blood that the functional integrity of these stnictures depends.
The
that a general nutritional
fact
is
have shown; but
further
it
finds
the
— —
statements of Professor Barker’s phasize a generally
known
fact
process prevails,
of
primary motive agency,
which the adrenal system
I
support in the following ^which,
of
course,
but em-
that, “in the absence of sub-
from the thyroid gland, the nervous system undergoes very important and serious metabolic modifications, evidenced by the remarkable nervous and mental phenomena with which all are now familiar. On restoring these substances to the body by the administration of a thyroid extract the symptoms may sometimes be made to disappear.
stances in the body derived
It
likely,
is
in the
main
however, that the neurons find their staple foods nutritive constituents of the blood as derived
from
the food digested in the stomach and intestines and purified
by the lymph-glands and have,
I
I
believe,
liver.”
satisfactorily
shown that the thy-
roid secretion incidentally sustains the activity of the anterior
pituitary body,
pouring
its
and therefore of the entire adrenal system, by
secretion into
the blood.
we have also two upon which I
The
functions
Among
digestive organs
reviewed.
ever, are
laid considerable stress,
spleen and pancreas,
tance
of
trypsin
—and
—the
derivatives, into
i.e.,
I called attention to the great
splenopancreatie
version of albuminoid substances,
we have
of
benign products.
the
the latter, how-
ferment
—
in
the
impor-
the
con-
and especially of their toxic These albuminoid substances,
seen, then pass
through the liver, and, after traversing the cardiopulmonary circuit are distributed broadcast throughout the organism. There is a feature which I kept in abevance,
—
however,
^though a well-known one, since at the time its true weight would not have asserted itself i.e., the fact that albuminoids include nucleins derived from the animal and vegetable :
34
THE POSTERIOR PITUITARY AND THE NERVOUS SYSTEM.
532
ingested with food, which nucleins contain at least 3 per We can now realize how great is the of phosphorus.
ceJls
cent,
of the pancreas
role
jihj'siological
and of the spleen
the
in
organism. Indeed, the functions of these two organs to constitute one of the pillars
As
rest.
upon which the
may
be said
vital functions
constituent of calcium phosphate, phosphorus
a
found in the bones, blood, milk,
and other
teeth, cartilage,
in quantities which bespeak of
etc.,
prominence, since calcium phosphate
is
is
tissues; in the its
functional
represented by nearly
pounds among the organism’s constituents. Sodium jihoswhich gives the blood, lymph, and other body-fluids their alkalinity and fluidity, and the potassium and magnesium phosphates, which fulflll much the same role, obviously find But it is when in phosphorus their main dynamic attributes. we reach the nervous system that the functional worth of this six
phate
—
element reaches
How
etc.
highest mark.
nervous
are
sheaths,
its
—
adequately
structures
supplied
—neurons, with
oxidizing substance, their phosphorus, etc.?
The Physiological Chemistry tions
myelin,
of
white
or
substance
axis-cylinders,
blood-plasma,
—The Schwann—a
of Nerves. of
their
funcjelly-
like homogeneous and transparent material which surrounds the axis-cylinder of nerves, and is only separated from it by It ^may be said to be unknown. a thin protoplasmic film which, and acid, is a fatty substance, blackened by osmic after death, coagulates and becomes opaque, loses its homo-
—
now
universally considered as a pro-
geneity, etc.
Myelin
tective coat:
a function which the overlying neurilemma alIs myelin fatty in the true sense of the word?
ready
fulfills.
is
in quantities, a very large iiroportion of about one-half, according to some obdried nerve-substance
Examined chemically
—
gervers
—
consists of a peculiar body:
cholesterin.
This body
but an alcohol; like gl 3Terin, however, which is “Though also an alcohol, it forms compounds with fatty acids. we do not know definitely the chemical condition in which Professor cholesterin exists during life in the medulla,” saj^s comFoster, “it is more than probable that it exists in some
is
not a
fat,
in bination with some of the really fatty bodies also present
533
THE PHYSIOLOGICAL CHEMISTRY OP NERVES. the medulla, and not in a free isolated state.” cliolesterin, Vhite’ nervous matter contains
.
a
.
less
but
less,
considerable, quantity of complex fat whose nature
According to some authorities rather
“Besides
.
is
than half this com-
which we have be present also in blood-corpuscles and in mus-
plex fat consists of a peculiar body, already seen to
lecithin,
Lecithin contains the radical of stearic acid (or of
cle.
still
disputed.
or of palmitic acid), associated, not
—
as in ordinary fats
oleic,
—with
simple glycerin, but with the more complex glycerin-phosphoric
and further combined with a nitrogenous body, neurin,
acid,
an ammonia compound of some considerable complexity; therefore of remarkable nature,
since,
though a
fat,
it
it is
con-
and phosphorus.” Cholesterin (C28H44O), (C44H50NPO0), and neurin (CsH^jlSrOa), as shown by
tains both nitrogen lecithin
the formulas, are all oxygen-containing bodies.
May
this sup-
posed coating and insolating material, myelin, not be to the nerve what myosinogen Cholesterin,
“It
tions.
is
is
we have
to
muscle
?
seen, is associated
with hepatic func-
singular,” says Professor Poster, “that, besides
being present in such large quantities in nervous tissue, and to a small extent in other tissues
a normal constituent of bile.”
and in blood, cholesterin
I have previously referred to
the fact that this alcohol, the only one
body in a free formation of
state,
and
bile,
is
which occurs in the
combines with glycocholic acid in the is thus eliminated by the liver. This
view sustains that of Austin Flint, who looked upon cholesterin as an excrementitious product derived from the nervous sys-
tem
:
i.e.,
the result of nerve-metabolism.
Cholesterin
is
pres-
ent in abundance in the white substance of the cerebro-spinal axis, as well as
in the myelin, or white substance of Schwann,
We have seen, however, that the elimination of excrementitious products by the liver is carried out by the in
nerves.
combination of various agencies cholic
acids
from
derived
process in which the
nating
role.
:
mainly glycocholic and tauroacid through an oxidation
cholic
oxidizing substance plays the predomi-
That an oxidation process
also occurs in a nerve during functional activity is suggested by the following lines of Mathias Duval “Direct experimentation has shown that the ;
functionating nerve
is
the seat of increased comhustion; this
—
—
THE POSTERIOR PITUITARY AND THE NERVOUS SYSTEM.
534
accompanied by the liberation of heat, the presence of which Schiff has demonstrated even np to the nerve-centers, under
is
the influence of fear, of excitation of the senses, of any cause
—
in a
word
—which produces —“a conspicuous component
cerebral activity.”
I^ecithin
of the brain, nerves,
yelk of egg, semen, pus, white blood-corpuscles, and the electrical
organs of the ray”
—suggests
its
identity as at least one
we are seeking by the
of the sources of energy
fact that
merely allowed to stand at the ordinary temperature tions
acquire an acid reaction and
intestines it
are decomposed.
sometimes breaks up into
its
In the
constituents;
its
if
solu-
fatty
and cliolin (Howell). Neurin and therefore a decomposition product of
acids, glycerin, phosphoric acid, is,
in reality, cholin,
As previously
lecithin.
stated, Tappeiner®^ obtained fatty acids
These
as a result of cholic-acid oxidation.
facts, of course, are
we
only cited as mere landmarks to indicate that
with oxidizable bodies. concerned, therefore,
it
As
seems probable that we have in lecithin
an agency capable, by the character of bohydrates, phosphorus,
are dealing
far as the nerves themselves are
—
etc.,
molecule,
its
i.e.,
car-
of acting as a potent source of
working energy when brought into contact with the oxidizing substance; and in cholesterin the main waste-product of nervecatabolism.
Admitting, then, that we have in the lecithin of myelin a body capable of acting as a source of energy in a way similar
myosinogen in muscle, how does the oxidizing substance of The nodes of Ranvier and tlie the blood-plasma reach it? to
nedrilemma that covers them allow axis-cylinder,
but the myelin
itself
silver stains to reach the
does not permit of this.
This suggests that the nodes themselves ing them may allow the blood-plasma to
i.e.,
—
the rings form-
filter
through them,
thus bringing the oxidizing substance in
immediate contact
anatomy
of nerves indicates
with the axis-cylinder. that such
may
be
The
the case.
finer
Indeed, the nodes referred to occur
and separate the nerve, as is well known, into as many segments, which recall, in a measure, the muscleof fiber and the liver-cell or, at least, features characteristic at regular intervals,
both these structures. Tappelner;
If the blood-plasma can penetrate the
Zeltschrlft fUr Biologie, Bd.
xli,
S.
GO,
1876.
— —
—
535
THE PHYSIOLOGICAL CHEMISTRY OF NERVES.
nodes of Eanvier as do stains, there only lies between it and the Rxis-cylinder an extremely delicate layer of protoplasm, Mauthner’s sheath, which in no way would impede the en-
—
trance of the fluid into the axis-cylinder
The term
“cylinder”
in accordance
latter:
itself.
the tubular shape of the
suggests
with Eemak’s view that
The
liquid.
who
prevailing view, however,
an albuminous
that of
is
made up
considers the axis-cylinder as
consists of a
it
delicate, longitudinally striated tube, filled with
M.
Schultz,
of fibrils united
by an intervening unknown substance. This seems to me to vividly recall the arrangement of muscular flbers as regards their relation with the blood-plasma: i.e., minute flbers into which the plasma
may
Again, we must not lose
freely enter.
sight of the fact, in this connection, that the axis-cylinder
is
nothing hut the elongated axon of a neuron, and that the now referred to, therefore, represent the intimate
fibrillffi
structure of a neuron’s axon. flbrillse
Now,
as Schafer holds that these
and as the have good reason to
are extremely fine tubes filled with fluid,
character of this fluid
is
not known, I
believe that they are channels for the
hlood-plasma:
i.e.,
for
the oxidizing substance.
But there
is
another feature which points to the axis-
cylinder as a channel for the oxidizing substance:
that the so-called “medullary sheath”
i.e.,
Schmidt,
them
The
strias
rep-
them were at first termed “clefts” or “incisures” by Lautermann, and others, but Eanvier considered
as protoplasmic septa
segment of the nerve into bers.
the fact
the myelin itself
contains a supposed “supporting frame-work.”
resenting
i.e.,
W. H. Wynn,®^ who
which subdivide each internodular several
gives
an
conico-cylindrical excellent review
chamof this
subject and the results of personal researches, refers to those
and Golgi,®'* who “from the examination of fibers treated by a mixture of bichromate of potash and osmic acid, and afteiward by nitrate of silver, find that each cleft is
of Eezzonico'*®
occupied by what appears to be a thread of substance passing spirally around the fiber.
“ W. H. Wynn:
darkl3'--stained
They
consider,” he
Journal of Anat. and Physiol., April, 1900. Rezzonico: Archivio per le Scl. med., Torino, vol. iv, 1880; and Gazzetta med. ital. lomb., Milano, vol. 1, 1879. Golgi; Arch, per le Sol. med., Torino, vol. Iv, 1880.
“
— THE POSTERIOR PITUITARY AND THE NERVOUS SYSTEM.
536
adds, “that the supporting frame-work of the sheath consists of a chain of funnels surrounding the axis-cylinder, each funnel being fonned by a spiral thread.” TizzonP® “believes
that
there
cylinder,
niann.”
nerve
but
is
one net^work
and that it McCarthy
has
been
is
m
stated
is
closely
the
structures,
wliich pass
medullary
the
slits of
have shown that,
to
hardened with
chromate,
investing
connection luith the
picric
sheath
acid
contains
axis-
Lauter-
“after
a
and ammonium minute,
rod-like
rapidly between the axis-cylinder and
the primitive sheath so as to give the cross-section of a fiber tlie
appearance of a wheel.
The
rods stain with carmine and
luematoxylin, which do not stain the myelin.
It
is
not possible
to isolate the rods as separate elements, for they are
not
dis-
from one another, but united.” Finally he refers to the fact that Lautermann, von Stilling, Eoudanowski, and McCarthy all believe that there is “a system of hollow canals in the sheath of the axis-cylinder,” and himself reaches the conclusion that the cones they form are protoplasmic, and not comtinct
posed of neuro-keratin, as
is
He
usually held.
divides “each
cone into six segments placed at regular distances apart and
converging from the primitive sheath to
tlie
axis-cylinder.”
shown in the annexed illustration, reproduced from his paper. If we now consider the segments as canaliculi leading from the axis-cylinder, we can readily see how the blood-plasma can penetrate the myelin and its oxidizing substance, and these bodies carrj" on, when brought into contact, a reaction similar to that which occurs in muscle-fiber. Indeed, This
if
is
well
the various features enumerated are collectively considered,
become apparent that the myelin, or white substance of Schwann, tvhen in contact with the oxidizing substance of the
it will
blood-plasma undergoes a reaction in which chemical energy
is
liberated.
When we
consider that the axis-cylinder
continuation of a neuron’s axon, for the various
is
as stated, the
not difficult to account
phenomena, known under the general term
“nerve-degeneration,”
Archlvio per
le
of
the disorganization of myelin, the
i.e.,
dissolution of the myelin,
®°Tizzonl:
it
is,
etc.,
Scl.
— at
med., vol.
the distal end of a nerve,
Hi,
fasc.
1,
1S78.
the physiological chemistry op nerves.
when the
latter has
been
cut.
Vei7
537
suggestive, in this connec-
“Waller are the following lines by Professor Barker*®: comresulted there severed proved that if a motor nerve was tion,
plete
degeneration of the fibers in the peripheral end,
even
Diagram op Relation Between Longitudinal and Transverse Sections, Showing Cones Cut Across at Different Levels. 1,
cone;
at base of cone; 2, 4, through interval
through middle of cone; between two cones. In 1,
3,
2,
through apex of and 3 the cone
segments and protoplasmic sheaths are seen. In 4 only the thin protoplasmic sheaths beneath primitive sheath and around axis-cylinder are visible. (IF. U. Wynn.)
to the muscles
which they govern, the central end remaining As a matter of fact, the changes charac-
apparently intact. teristic
of
the Wallerian
degeneration could not, as a rule, be traced farther in the central end than to the first node of Panvier.” Stewart®^ states that “in the degenerated nerve Barker: hoc. cit., p. 740. Stewart: “Manual of Physiology,”
p.
607.
538
THE POSTERIOR PITUITARY AND THE NERVOUS SYSTEM.
the substances soluble in ether are relatively increased owing, in part, to fatty degeneration of the axis-cylinder,” and that
“the percentage of phosphorus
is markedly diminished (Mott and Barratt).” Another process which seems to acquire a certain degree
of light
is
nerve-regeneration.
It is obvious that if we grant the axis-cylinder, as the extension of the axon, all functional and nutritive attributes, we may easily explain peripheral
nerve-degeneration,
but not regeneration, the peripheral segfor by reason of the section. We know,
ment being unprovided
on the contrary, that a piece of the nerve must be removed in order to prevent reunion, and that otherwise in two or three weeks, and often earlier, its functions will be restored. Xew cylinders and fibrils grow, acquire myelin, and, perhaps, guided
and
assisted
the
peripheral
by (nucleated) neurilemma, soon meet those of segment and become connected with them.
Physiological functions of a normal kind
must underlie
this
even in the peripheral end of the nerve; otherwise
process
union would not take place. Finally (we can only refer to a few of the more prominent processes involved in the vast subject
now claiming our
attention)
the
functional
phenomena
that follow after division of the cord distinctly indicate the
continuation of nutrition and the functional activity
impaired
“In the
—
in the distal fragment.
mammal
—though
Foster, for instance, says:
(dog) after division of the spinal cord in the
and apparently spontaneous movements lumbar cord. has thoroughly recovered from the operation
dorsal region regular
may be observed When the animal
in the parts governed by the
the hind-limbs rarely remain quiet for a long period of time;
they move restlessly in various ways; and, when the animal
suspended by the upper part of the body, the pendent hindlimbs are continually being drawn up and let down again with a monotonous rhythmic regularity suggestive of automatic is
rhythmic discharges from the central mechanisms of the cord. In the newly-born mammal, too, after removal of the brain
movements
spontaneous in nature are frequently these movements, even when most highly
apparent!}'’
obseiwed.
But
developed,
are very different from the movements,
all
irregular
and variable in their occurrence, though orderly and purposeful
539
THE CIRCULATION OP THE NEURON. in their character, which
we
recognize as distinctly voluntary.”
Indeed, the nervous energy that myelin and the oxidizing substance procure
hemispheres and
a frog deprived
that which allows
is
its
of
its
middle brain “to sink in water as though
the animal were of lead.”
The axis-cylinder composed of fibrils into which bloodplasma penetrates being continuous with the axon of a neuro'n, we are brought to realize the nature of the parallelism between phenomena of the latter and those of the supraBut we must glands to which I have already referred.
the functional renal
not lose sight of the fact that each “medullated” nerve-fiber is
divided by the nodes of Eanvier into as
many
subdivisions,
and that each intemodal segment receives its own supply of Does the neuron receive its supply through this chain of segments, or, rather, through the axis-cylinder that passes through them? That the former mechanism alone prevails is
plasma.
improbable, since so prominent a part of the entire structure
would hardly be sup-
as its cell-body, the seat of its nucleus,
plied in so indirect a manner.
The very importance
of
its
existence of direct supply.
Does such
we have not The Circulation op the Neuron. Barker,
far to seek.
functions betokens
a vascular system
tlie
exist
?
Fortunately,
—
in a review adduced for or against the neuron doctrine,®® concludes that “it may be said, with fairness, that the control instituted by hundreds of histologists in various parts of the world has practically in every instance in which of the facts that have been
the
method
of Golgi or the
method
of Ehrlich has been
em-
ployed gone to confirm the conception that the neuron is a unit in the sense of Waldeyer.” The latter investigator’s words, giving the gist of his doctrine, are also quoted: “If we review the main advance, made certain by the anatomical investigations discussed, it limitation,
now
lies,
in
my
tional elements of the nervous
system
consider the nerve-units-neurons), collaterals,
Eamon y Barker:
opinion, in the sharper
possible, of the anatomical as well as the func-
with Cajal.”
their
The
(for such
and
also
end-arborizations,
the
by
we have
to
discovery
of
Golgi
and
S.
following lines of Waldeyer’s are also
American Journal
of Insanity,
July.
1898.
THE POSTERIOR PITUITARY AND THE NERVOUS SYSTEM.
540
quoted
:
“If we assume, with Golgi and B. Haller, the existence
of nerve net-works, the conception
we can
still
the
retain
is
somewhat modified, but
nerve-units
—
.
.
which
of
all
tends to show that, while the neuron doctrine stands on a solid foundation, there is a stumbling-block in its way which has not as yet been removed.
Especially
is this true since the investigations of Apathy, of Naples, who, after several years’ stud}',
has unquestionably demonstrated the existence of a net-work of what he terms “neuro-fibrils.”
That Apathy’s
“neuro-fibrils” as well as Golgi
nerve net-works are not
but
nerve-elements,
and Haller’s
fine
capillaries
which serve for the circulation of blood-plasma, seems to me probable. In the following extracts the italicized words will serve to call attention to the various links between these struct-
ures and others that
we have
Professor Barker sum“Apathy has been convinced for some twelve years that the nervous system is composed of two varieties of cellular elements entirely different from each The nerve-cells, the other nerve-cells and ganglion-cells. architecture of which is quite in accord with that of muscleanalyzed.
marizes Apathy’s views as follows
:
:
A
give rise, he thinks, to neuro-fibrils.
cells,
turn, passes out of a process of a nerve-cell
neuro-fibril, in
and then goes through
a number of ganglion-cells, and ultimately, after leaving the ganglion-cell with which it is connected, passes more or directly to a muscular fiber or to a sensory cell. fibrils are, as
last less
The neuro-
conducting substance for the nerve-cells, Avhat the
The
muscle-fibrillce are as contractile substance for the muscle.
pathways to be followed by the neuro-fibrils are predestined from the earliest embryonic stages, for they correspond, according to Apathy, to the intercellular protoplasmic bridges."
That we have all required elements in support of evident; we have seen that muscle-fibers are, in cate
tubes;
that
vascular
channels
blood-plasma should be protoplasmic
for is
the as
need of their penetrating into and out of the
What
appears to
me
as conclusive
my
belief is
reality,
deli-
transmission
obvious as
is
of
the
cells.
evidence
is
indirectly
afforded by the deductions of Ehrlich, suggested by his study of the
and their processes “Ehrlich found,” says Barker, “that by
methods of staining living
with methylene-blue.
nerve-cells
541
THE CIRCULATION OF THE NEURON.
in salt soluinjection of a solution of methylene-blue dissolved the axistion inti'a vitam into the blood-vessels of an animal, cylinders of
numerous
PiQ.
The
of the nerve-fibers
(particularly
1 .—
sheath
many
sensory)
(see Fig. 1), as well as
nerve-endings
(see
2),
Nerve-fibers from a Frog Injected with Methyleneblue (Method of Ehrlich). {After KiiUilccr.) axis-cylinders
Is
the fibers
are
stained
dark
blue.
In
places
somewhat stained. The nodes of Ranvler and the at some of the nodes are well shown.
the myelin divisions of
were stained after a time, when exposed to the
air,
blue color, the other tissue-elements remaining
little
all
Fig.
affected.”
It seems
clear
that,
if
a solution
an intenseor not at
introduced
through blood-vessels can stain the axis-cylinders, the liquid
;
THE POSTERIOR PITUITARY AND THE NERVOUS SYSTEM.
o42
within the latter must be more or in the blood-vessels.
plasma, including
its
Again,
I
less
a continuation of that
have suggested that the blood-
oxidizing substance, was the liquid in the is true is shown by Ehrlich’s observa-
axis-cylinders; that this
tion that the conditions in the nerve-structures essential to the methylene-blue reaction” were, he thought (188G) “(1) ;
oxygen saturation; (2) alkalinity.”
J
liave
shown that these
are the essential attributes of blood-plasma.
Fio. 2.— Sensory Nerve-ending Stained with Methtlenb-blue (Method of Ehrlich) in the Exocardium of the Left Auricle OF A Gray Rat. (After Smirnow.)
This seems to
me
to afford an insight into the physiological
chemistiy of the axis-cylinder of the neuraxon when a short distance below the latter
it
has become a medullated nerve.
Indeed, the prevailing view that the myelin represents a protective
and insulating coat may
doubt, especially
composition
is
at least be said to be
when coupled with the
unknown, and that
tliere is
to
another external coat
the neuro-keratin neurilemma, which suggests, by tion, that it is
open
facts that its chemical
an isolating covering and that
its
composi-
it also fulfills this
•
—
:
543
THE CIKOULATION OF THE NEURON. role
in.
That the
non-medullated nerves.
the seat of
in}’elin is
and a dea combustion process during which heat is If we composition product, cholin, is formed, we have seen. liberated
now
consider
myelin, lecithin,
component carbohydrates and phosphorus, and
composition
the
i.e.,
of
as regards carbohydrates,
analogy,
the
of
active
to myosinogen,
its
prob-
the
a source of energy, as does the latter That such is the itself.
ability that it serves as
when in contact with oxygen, suggests case,
however,
is
shown by the
fact that the contents of the
neuraxon or axis-cylinder fulfills the conditions necessary for methylene-blue staining, as laid
down by
Ehrlich,
i.e.,
oxygen
saturation and alkalinity, the characteristics of blood-plasma.
Indeed,
it
seems to
me
permissible to conclude that
Myelin, or the white substance of Schtvann,
1.
structure what myosinogen is to muscle-fiber
source of energy. 2. The axis-cylinder are
:
made up 3.
A
and the
is to
i.e., its
nerve-
immanent
canaliculi .derived therefrom
of fibrils that serve as channels for blood-plasma.
part of this blood-plasma penetrates into the axis-cylin-
der through Ranvier’s nodes.
and
Lecithin, a body composed mainly of hydrocarbons
Jf.
phosphorus, the active constituent of myelin and a prominent component of the electric organ of the ray, when exposed to the action of the oxidizing substance liberates energy: i.e., nervous energy.
Continuing our quotations from Professor Barker’s cle,
I
will
appear to fihrils.
arti-
introduce the various points of comparison which
me
to sustain
my
interpretation of Apathy’s neuro-
“Inside the ganglion-cells a reticulum of fine
fibrils
derived from the neuro-fibrils in transit can be stained a beautiful
deep-violet color
That the
by Apathy’s chloride-of-gold method.”
method can be considered as similar in action method and that the stain follows the same channels and affects the same chemical constituents of the plasma is shown by the following remark of Professor Barker’s: “With a little care and a good sample of methyleneblue the nerve-endings and the axis-cylinders of medullated latter
to the methylene-blue
fibers,
with which they are continuous, can be stained in a
way far surpassing in constancy and completeness the best
re-
THE POSTERIOR PITUITARY AND THE NERVOUS SYSTEM.
544
suits of the uncertain gold-cliloride procedure.”
As
the methy-
and a .modified chloride-of-gold stains were those mainly used by Apathy, no confusion can occur on this score. Indeed, if we convert all of Apatliy’s neuro-fibrils into lene-blue
minute
capillaries, their identity as inherent parts of the gen-
eral circulation is placed
on a
solid foundation
by
tlie
following
remark of Professor Barker’s: “The doctrine of the fibrillary nature of the axon and unstainable portion of the protoplasm of the nerve-cell has recently received support from the studies
of Lugaro^® and Levi.*®
under
nerve-cell
The
fonner, too, in his studies of the
pathological
conditions
—
poisoning with lead and arsenic
come very
distinct in the nerve-cells.”
to the one system i.e.,
—for
That
the adrenal sj'stem, and that
it
“made up
its
is
evident.
mentary
“Each number near its origin, and in the course which it
fibrillge
mentary
—
are being given
fibril.”
The
itself
tj^pifies
lated” nerve-fibers,
may
off
at
it
at
Apathy any rate
follows ele-
short intervals until
be reduced to a single
fibrillary structure of
as clearly reproduced here as
but
neuro-fibril is,”
of a large
finally the neuro-fibril
now
cell-body extensions, on the other,
of “^elementary fibrils,’
fibrils
this directly points
precisely coincides with the
becomes a normal consequence.
—
be-
similarity of the neuro-fibril, on the one hand, to the
axis-cylinder and
states,
after
may
through which the morbid changes can occur,
foregoing remarks bearing upon this system,
The
example,
finds that the fibrils
an axis-cylinder
can well be; the giving
the irregular
distribution
and particularly those
ele-
of
off
is
of
‘“non-medul-
of the ““sympathetic”
system.
All this recalls a structure which appears to
me
to be inti-
mately connected with the general circulation, the neuraxon and its cellular extensions, and Apathy’s neuro-fibrils all
—
being considered as component parts of the general vascular
system
i.e.,
:
The is
that
it
prevailing view concerning the role of this structure affords a supporting frame-work for the nervous ele-
Both
ments. lated
Virchow’s neuroglia.
in tlie white matter
nerve-fibers
separated
Rlvista di patol. nerv. e mentale, vol. i, 1896. Rlvista di patol. nerv. e ment., vol. i, 1896.
Lugaro: y the way plexus, and axon represent a continuous
therefore,
found thickened, globular, animals must be connected.
that etc.,
But
the
vascular
:
it
It
clear
enters is
with
neuroglia-fibers
by Berkley in
his
jxiisoned
this fact siigjjests that these
649
THE CTROULATION OF THE NEURON. structures
should
'
the influence of the
should show
less,
under
swellings
irregular
present
likewise
agencies, and that the axis-cylinder
same
and
the intracellular fonnation of plexuses
anastomoses interposing a barrier to the too free passage of That such is actually the case is illustrated by the plasma.
annexed plates hy Berkley, which represent the lesions found ill the neurons of the poisoned animals to which reference has been made. If the protoplasmic processes or dendrites are the first to
bear the brunt of the vascular engorgement, the plasma being carried to them through fibrils connected with their tips, these tips or extremities should first
pressure.
This
from the second
is
show evidence of the expansile
well illustrated in Fig.
a “psychical cell
1,
which shows, using
cellular layer of the cortex,”
Berkley’s words, “a few pathological tumefactions on the upperOthermost branches of the apices of the apical dendrite.
wise the cell
is
This
normal.”
cell
was
selected
from a section
derived from the brain of an animal poisoned with ricin, death
A
having occurred in thirty-six hours. however, off
is
that
the greatest
it is
feature of importance,
—that giving
the main, or apical, dendrite
number
of subdivisions
—which
shows the
evi-
dences of engorgement; the extremities of the other dendrites
show more or
are not thickened, but they of
engorgement as the main trunk
marked evidenees
less
This ob-
approached.
is
way
viously suggests that the plasma penetrates the neuron by of the laterals
main dendrite and that cellulipetally
;
in
it
finds
other words,
into
the apices of the collaterals
may not
instead
This feature
Fig. 2, especially by the larger stem of the cell,
also it
is
were
it
mean
that
subsequently show thiek-
enings; being terminals, they should naturally do so pressure exceeds a given limit.
of
preeisely as if
this does not
col-
its
of their tips,
—
them by the main trunk main .stalk of a plant. Of course,
supplied to the
that,
way
entering these collateral branches by
way
its
is
when
illustrated
main trunk.
the
by
This
a projection-cell from the second layer of the cortex, shows
the effeets of fort ’'-eight hours’ ricin poisoning: 3
i.e.,
of
some-
what more prolonged engorgement.
Worthy Berkley
of special notice, also,
(referring to Fig.
is
2), that:
the fact emphasized by ‘There
is
now
distinct
THE POSTERIOR PITUITARY AND THE NERVOUS SYSTEM.
O')0
diminution of the gcmniulac wherever the swellings are found” which suggests that these minute ball-tipped projections from
—
all collaterals
are stnicturally similar to them, and that,
when
the engorgement exceeds in centrifugal pressure the resistance of a given area, the walls of the latter, including the gemmules,
more or
are
that
all
less flattened out.
Suggestive, likewise,
is
the fact
the gemmules stand out boldly in both preparations.
As many
as thirty-six or forty-eight hours having elapsed be-
fore death ensued, the animals were evidently submitted to a
primary period of intense stimulation, during which the gemmules were overdistended to such an extent as to cause them Indeed, the sudden cessation to lose their retractile property. of adrenal functions
and consequent death must have left the had been suddenly
cerebral stnictures much, as if the animals killed.
Of marked
interest in Fig.
3
the presence at the ex-
is
tremity of the main, or apical, dendrite of a section of what to represent a fiber or capillar}' from which the neuron with which it is connected might have derived its bloodsupply. The fact that it crosses its path suggests that the den-
me
appears to
drite itself
may
be a branch of the vessel.
Berkley describes
“Projection-cell of the long apical neuron as follows process variety, showing numbers of large swellings of the prothis
:
toplasm of the apical dendrite, thinning of the protoplasm of the stems in the interval between tlie nodules, and considerable The lateral branches loss of the gemmuhe along the margins. have mainly disappeared.
The
basal
processes
are
retained
intact.”
The nodules seem
to
me
also
to
illustrate
the
process
through which the collateral fibers become detached from the main stem, as shown by the denuded cells represented by Pigs.
4 and
5.
The thinning
of the
plasma between the stems would
deaccount for the manner in which the lateral branches are sufficiently tached, viz.; when the apical dendrite becomes of the more engorged the plasma ceases to circulate in one or nournodules, and the intervening protoplasm, failing to be the be should That the ha«al processes ished, disintegrates.
(corresponding in this with the condibut normal tion of the same' stems in Figs. 1 and 2) seems last to yield in this cell
LESIONS IN THE NEURONS OF ANIMALS AFTER RICIN POISONING-. [BerklBy.] [Johns Jlopkins Hospital Meports.\
i
i
.
I
:
'
i i
¥
*
1
i
THK OIKCULATION
when we
consicler
OXi"
551
THE NEURON.
only to the cell-body,
their proximity not
which contains a large supply of fibrils, but also to the axiscylinder {ax. in the drawings), which is the only centrifugal channel through which the engorged plasma can escape.
A
and 3 which shown by Figs. 1, the .adrenal phenomena brought on by
feature of the cells
strikingly links
them
toxics in the general
to
organism
is
the fact that, although they
from animals in which the doses of ricin injected were reduced with each animal, the morbid phenomena as exemplified by each cell in turn are correspondingly intensified. In other words, the adult rabbit represented by Fig. 1 was given subcutaneously a dose of 0.5 milligramme, and death occurred The in thirty-six hours: the cell only shows apical lesions. are derived
.
second adult rabbit was given the half of the previous dose, i.e., 0.250 milligramme, and death occurred in forty-eight hours: the entire apical dendrite tinctly involved.
The
of the last dose:
i.e.,
and two
of the collaterals are dis-
third adult rabbit was given the half
0.125 milligramme, and death occurred
markedly studded
in seventy-two hours; the apical dendrite
is
with thickenings, and
collatei’als
appeared.
It
is,
all
but two of
its
perhaps, unnecessai’y to lay
sti’ess
have
dis-
upon the
fact that this is due to the prolongation of the excessive vascular
tension:
i.e.,
of the time during which central vascular con-
caused peripheral capillary engorgement. And this need not be ascribed only to ricin. Berkley emphasizes this
traction
assertion
when he
many ways
says:
“The poison
similar to that of
ricin,
whose action
many toxalbumins
source, is capable of exerting a deep
is
in
of bacterial
and extensive degenerative
influence on the protoplasm of the nerve-cells of the bi-ain.”
And says:
this
may
further be extended to other toxics, for he also
“Poisoning with alcohol in considerable doses, continued
over a moderate time, will produce decided and ascertainable
and nervous elements of the cerebrum, very similar in character to the pathological lesions produced by other more virulent poisons.” We thus have evi-
lesions of the nutrient stnictures
dence in support of my opinion that poisons capable of causing congestion of the cerebrospinal and other nervous tissues do so by raising the blood-pressure and by thus driving the adrenoxidase-ladcn plasma into their neuroglia
and neyrons.
That the
THE POSTEUIOR PITUITARY AND THE NERVOUS SYSTEM.
5o2
alterations in the elements of the
neuron should he due to the same centrifugal pressure that prevails in the capillaries of all peripheral structures
obvious.
Finally, the fact that jihenomena witnessed occur under the influence of congestive poisons affords the complemental evidence in favor of my contention that a
neuron
is
is
directly connected
ivitli
the circulation hy one or
more
of its dendrites, which serve as channels for blood-plasma.
Even
the haemorrhages brought on by excessive pressure,
hematuria,
epistaxis, hamiatemesis,
engorged neuron shown in Figs. 6 and ley’s
series.
The
freel}^ inside
take their exit from the cation
if,
as
7,
and
from Berk-
also
observation of Apathy’s, therefore, that his
by way of the dendrite, ramify
‘T-ellulipetal neuro-fibrils enter
and anastomose
are exemplified in the
etc.,
cell
the cell-body, and, then reuniting,
by
wa}'^
of the axon,” finds its appli-
interpreted by mj^self, his neuro-fibrils are con-
sidered as blood-plasma channels. Still,
the identity of the
fibrils
in the cell-body as blood-
by the fact that they are continuous with the plasma-containing axis-cylinder and While this constitutes strong evidence, the fact that fibrils. tliey are blood-charulels can. only be determined by ascertaining the nature of the process in which the plasma takes part. This capillaries has so far only been suggested
ina}f
probably be done by inquiring into the composition of a
neuron’s ground-substance.
The Physiological Chemistry is
of the Neuron.
the nature of the ground-substance:
—What
that between the
i.e.,
After reviewing this subdivision of the general sub“A neuron is made up, like all other cells, ject Barker says In the latter a centrosome and of nucleus and protoplasm. fibrils?
:
an attraction-sphere are present; at onstrated in a ceidain
mic ‘portion of the eral
exoplasmic
number
cell
portion
least
it
has been dem-
The
of nerve-cells.
protoplas-
can be roughly divided into a periphand a central endoplasmic jiortion.
In neurons, as in musclc-cells, though less distinct in the former than in the latter, tliere is a tendency to a fihrillar}^ structure, the fibrilla; tending to occur in the peripheral ex-
oplasmic portion of both nerve- and muscle-
cells
in the endoplasmic portion of the jirotoplasm.
rather than
In both exo-
fig 6 .
fig ?
lesions in the neurons of rnimals after RICIN POISONING-1 [BerklBy ,]
[Johns J/ojtkins Hospital Rejmrts.^
:
I
i-i
f
t
653
THE PHYSIOLOGICAL CHEMISTRY OF THE NEURON.
plasm and endoplasm there can be made out in tissues which have been fixed a more or less homogeneous ground-substance granin which are deposited larger and smaller masses of a ular
nature.
corresponds,
The ground-substance
in
tissues
and stained by the methods of Nissl and Held to the ‘unstainable substance’ of Nissl, and the masses of granules to the ‘stainable substance’ of Nissl and the pigment.
fixed with alcohol
“The
'stainable substance’ of Nissl in healthy animals of
the same age and species, with the same method of fixing and staining, is tolerably constant in appearance and arrangement
group of nervecells: a fact of extreme importance for neiwe-anatoniy and The axons appear to be entirely devoid of the pathology. ‘stainable
of the sanie
and dendrites
in the cell-bodies
Whether the stainable subfrom solution through the bodies pre-existent, though invisible, first of
substance’
Nissl.
stances represent bodies precipitated
acfion of reagents or
brought into view through the action of fixing or staining reagents in the hardened tissues, in either case they appear to yield the chemical tests characteristic of the
group of nucleo-
Whether the staining reaction characteristic of the stainable substance depends upon chemical relations or upon purely physical conditions must, for the present, remain un-
albumins.
decided.
“The
fiinstainable portion’
—^though
ground-substance,
important than the stainable, nature and stnicture are in general.”
Still,
out by our analysis
—that
of the cell-body,
probably
still
is
functionally
is,
the
much more
not so well understood;
its
as obscure as those of protoplasm
the link with features previously brought
now seems within
reach.
Held has maintained that the stainable Nissl bodies represent simply substances precipitated of fixing mixtures;
from solution by the action
Fischer was led to the same conclusion.
Barker says, in this connection, that he repeatedly convinced himself of the homogeneous ajipearance of the protoplasm of the neiwe-cell Avhen it is
from the
examined immediately after the removal
That the ground-substance
living liody.
geneous, and that the unstainable portion sociation
But
of
some of
its
the stainable portion
constituents,
we have
is
is
homo-
a product of dis-
are therefore
probable.
seen has yielded the chemical
THE POSTERIOR PITUITARY AND THE NERVOUS SYSTEM.
554
tests “characteristic of the
group of uucleo-albiiniins.” group of nitrogenous
not, therefore, dealing with the
which
lecithin,
the
main
We fats
dividual constituent which It
is
to
constituent of myelin, belongs, but
with what probably represents, not a mere artifact, but an ures.
are
in-
precipitated by the fixing mixtimportant to detennine, therefore, the exact nais
ture of the Nissl “bodies,” and perhaps by a process of exclusion ascertain that of the unstainable substance.
“Held,” says Professor Barker, “undertook a most careful
and exact chemical
of the granules
studj'^
in
alcohol tissues.
Thus, he found that the Nissl bodies arc insoluble in dilute and concentrated mineral acids, in acetic acid, boiling alcohol, cold or boiling ether, and in chloroform.
they
are
easily
soluble
in
dilute
With pepsin and hydrochloric-acid
On
the other hand,
and concentrated
alkalies.
digestion he found that the
ground-mass of the protoplasm vanished and that the Hissl bodies alone remained undigested the reveree of what occurred on treatment ivith an alkali. The Xissl bodies yielded no reac:
tion with Millon’s or Adamkiewicz’s reagent.
Held obtained,
however, slightly positive results with Lilienfeld and Monti’s
microchemical test for phosphorus, and a considerable quantity of the gray matter of the spinal
marrow
after digestion with
pepsin and hydrochloric acid examined by Siegfried, of the
showed the presence of Held concludes, however, from these various rephosphorus. actions, that the Nissl bodies belong to the group of the nucleophysiological
albumins
:
Halliburton,
a
laboratory
view
of
which
who found
Leipzig,
agrees
which coagulated at from 55° as
with the investigations
of
in the gray matter a micleo-albumin
much as 0.5 per cent, of The large proportion
to 60°
C.
and which contained
phosphorus.’’ of phosphorus further sustains the
preponderating role that the oxygen of the plasma must play in the neuron, owing to the activity of the reaction between these two .elements.
It also indicates a close relationship be-
tween the neuron and all other cellular structures of the orThus, referring to Held, Barker says: “He asserts ganism. that in numerous experiments with his method (fomiol freezing) he has found in the most different organs constituents of the cell-body which behave not only tinctorially, but also mor-
THE PHYSIOLOGICAL CHEMISTRY OF THE NEURON.
555
phologically, exactly as the stainable substance in nerve-cells.
He
described
them
gland-cells,
in
in
liver-cells,
the
of
cells
pancreas, in the cells of some sarcomatous tumors, in certain connective-tissue cells, but especially in
lymph-glands. of Nissl
is
not
normal and pathological
also asserts that the stainable substance
Cajal'*'*
specific
for the nerve-cells, as he has
demon-
and of the connective-tissue elements." Hissl’s bodies appear to me, therefore, as constituting an organized component of the ground-substrated its presence in certain of the leucocytes
nucleo-albumin rich in phosphorus,
stance of the neuron,
a
which, judging from
similarity to a large
its
number
of cellular
structures elsewhere in the organism, represents the cell-struct-
ure
itself, precisely as is
the hepatic cell
when
free
from glyco-
gen, bile, or the agencies from which these are derived. to the
neuron what the neurilemma, Mauthner’s sheath,
are' to
the intemodal segment
does the protoplasmic
membrane
of
etc.,
and includes
a nerve,
of
It is
—the
Schwann
—
as
nucleolated
nucleus.
The
must be the equivalent of myelin: the white substance of Schwann. We have seen that this is also unstainable. Even picrocarmine does not stain it, and unstainable portion
Rahvier states that, the axis-cylinder becomes stained at the nodes because there is no myelin in this region of the nerve.
The
similarity between myelin of the nerves
cerebro-spinal system is emphasized
and that of the by Foster when he saj's:
“Obviously the fat of the white matter of the central nervous system and of spinal nerves (of which fat by far the greater part must exist in the medulla, and for nearly the whole of the medulla) is a very complex body indeed, especially so if the cholesterin exists in combination with
(or protagon).
and, indeed, in
Being its
tlie
lecithin, or cerebrin
so complex, it is naturally very unstable,
stability resembles proteid matter.”
also suggests, however, that protagon, a nitrogenous
taining phosphorus isolated
may
This
body con-
Liebreich from brain-substance, be the unstainable substance we are seeking. Hoppe-Seyliy
and DiakonolT, having found it to be composed of lecithin and cerebrin, the direct connection with the former is not re-
ler
Cajal:
Revlsta trlmest. mlcrograflca, vol.
1,
No.
1,
March,
1896.
'
THE POSTERIOK PITUITARY AND THE NERVOUS SYSTEM.
556
moved.
Protagoii
Howell tlie
states
readily
up
breaks
into
constituents.
its
“while protagon seems to be regarded as principal form in which lecithin occurs in the brain, simple that,
lecithin is believed to be present in the nerves and other organs,” and he refers to Noll,"® who found “the quantity of
protagon in the spinal cord may amount to 25 per cent, of the dry solids; in the brain, to 22 per cent.; and in the sciatic nerve, to 7.5 per cent.” That it is difficult to analyze this question is suggested by his closing remark “Regarding the :
synthesis
of
lecithin
the
in
body,
portance of the substance, nothing the important role that
the
or
physiological
We
known.”
is
have seen
probably plays as myelin;
it
im-
its
pres-
ence in such large quantities, as a constituent of protagon, in the cerebro-spinal system plainly points to it as of the unstainable ground-substance of the neuron.
What
is
the role of cerebrin, which, with lecithin, forms
protagon, and from which
In a study of the chemistry of neiwe-degeneration Halliburton and Mott"® it
is
readily separated?
had previously shown that in general paralysis of the insane “the marked degeneration that occurs in the brain is accompanied by the passing of products of deOf these,” says the authors, generation into the spinal fluid. “nucleo-proteid and cholin are those Avhich can be most readily Cholin can also be found in the blood.” Having detected. refer to the fact that they
continued this work, they now find “that this
is
not peculiar
to the disease just mentioned, but .that in various other de-
generative nervous sclerosis,
alcoholic
diseases neuritis,
(combined beriberi)
sclerosis,
cholin
disseminated
can be also de-
The tests that they employed were the hlood.” mainly two: (1) “the obtaining of the characteristic octahedral crystals -of the platinum double salt from the alcoholic extract and a very interesting of the blood”; (2) a physiological test
tected
in
—
one,
I
.may
add,
if
the
functions
arc included in the process, namely:
of
the
adrenal
system
“the lowering of Iilood-
which the authors consider as “partly cardiac in origin and ]iartly due to dilation of peripheral vessels,” and pressure,”
“Noll: Zeltschrlft fUr physiol. Chetnie, Dd. xxvii, S. “Halliburton and Mott: Journal of Physiology, Feb.
370,
1S99.
28,
1901.
THE PHYSIOLOGICAL CHEMISTRY OF THE NEURON.
557
“which a saline solution of the residue of the alcoholic extract produces/’ This fall “is abolished,” they further state, “if the I may incidentally remark animal has been atropinized.”
embody the pathogenesis of most neuroses attended with degeneration, viewed from my standpoint, since we have here the phenomena incident upon arrest of function, But diauto-intoxication., and toxic suprarenal insufficiency. rectly bearing upon the subject in point is the evident iden-, that these few lines
product of degeneration.
tity of cholin as a
and putrefaction,” says Howell. we have seen, a waste-product of normal
decomposition
lecithin
in
But
likewise, as
it is
It “has its source
nervous-tissue metabolism, being eliminated with the bile in a
modified form.
and is
That
cerebrtn
is
of physiological metabolism is
found in pus-corpuscles and
present considerable analogy.
a product of putrefaction suggested by two facts: it fonnula and that of cholin
also
its
Even taking
as
standard that
furnished by H. Muller, which has given rise to considerable
CJ.H33NO3, while cholin is CgHj^NO,. becomes the functional ground-substance of
controversy, cerebrin
Lecithin, therefore,
is
the cell-body of the neuron, just as the neuron
and
its
it
is
in the nerve.
Both in
continuation, the nerve, therefore, the vascular
carry blood-plasma, which, by passing through their walls, maintains a continuous reaction, of which the phosphorus of the lecithin and the oxygen of the blood-plasma are main reagents and chemical energy the end-result. The relationship fibrils
between the vascular etc., is
well
But
fibrils and the ground-substance, nucleus, shown in the engraving on page 558.
though a useful product of metabolism, requires in its formation the aid of protoplasmic function, as does, in the muscle, tlie elaboration of myosinogen. In the cell-body this is probably performed, we have seen, by structures which the Nissl bodies, as nucleo-albiimins, represent. Indeed, lecithin,
in a study of the action of fixatives found'’’’’
that,
“when
a soluble colloid
upon protoplasm Plardy fixed by the action of
is
a
fixing reagent, it acquires a comparatively coarse structure in the process, which differs wholly or in part from the structure of the solulile colloid.” Again, that those jirotoplasmic
" Hardy:
Journal o£ Physiology,
May
11,
1899.
S
558
Fig.
THE POSTERIOH PITUITARY AND THE NERVOUS SYSTEM.
."i.
—
chematic Representation op the Lower Motor Neuron.
The motor ceR from the ventral horn of the spinal cord, together with all Us protoplasmic processes and their divisions, its axis-cylinder process with its divisions, slde-flbrlls or collaterals, and end-ramiflcatlons (telodendrions, or motor end-plates) In the muscle represent parts of a single cell or neuron, n'. Nucleolus, c, Cytoplasm showing the dark colored Nlssl bodies and lighter ground-substance. (7, 'Protoplasmic processes (dendrites) containing Nissl bodies. (Harker.)
659
THE PHYSIOLOGICAL CHEMISTRY OF THE NEURON.
stnicturcs are supjilicd by a vascular net-work similar to that of other
cellular
structures
shown by the observations of
is
Apathy, who took them for nerve-fibrils. to this feature of his investigations, says:
Barker,
“As
referring
to the relations
on the one hand, and Apathy makes very definite
of the neuro-fibrils to sensory surfaces,
muscular
tissue,
on
the
other.
the
chapter of his article.
A
statements,
especially
neuro-fibril
entering the cjdoplasm of an epithelial cell of a
in
last
up (very much as in a reticulum composed of the elementary
sensory surface in the leech breaks ganglion-cell) into a finer
A
fibrils.
large
number
of
the constituent
perhaps the majority, leave the the
cell
fibrils,
however,
in order to take part in
formation of a complicated interepithelial fibril-plexus.”
Neuron and
nerve,
therefore,
appear to be similar to other
organs as functional entities and to be subject to the same laws,
including
the
circulation
through
them
of
oxidizing
plasma.
This explains for the
first
time why tetanotoxin was found
by Bruschettini, Marie and others and why, in shown by Marie and Morax (see p. 1441), tetanotoxin, injected into the tissues, enters and ascends the axis-cylinders of nerves an observation confirmed by Meyer and Eansom. The role of the blood-plasma seems so clearly defined in the in the nerves
fact, as
—
foregoing analysis that I deem .all
—
parts of a neuron
cylinder
—are
it
permissible to conclude that
neuraxon or axis-
cell-body, dendntes,
channels for adrenoxidase-laden blood-plasma.
Are dendrites provided, as are the cell-body and the axismyelin? We have seen that, as stated by Barker,
cylinder, with
“the stainable substance of Nissl in healthy animals
same age and staining,
is
species,
of
the
with the same method of fixing and
and arrangement and dendrites of the same group of nerve-cells.”
tolerably constant in appearance
in the cell-bodies
He also states that “the axons appear to be entirely devoid of the stainable substance of Nissl”; but Berkley,^® referring to the nerve-fiber terminals which are extensions of the axon, writes: “The researches of Flechsig, as well as my own, have shown that these
fine
branches are furnished with a thin layer
of myelin nearly to their termination.” Berkley
:
J ohns Hopkins Hospital Reports, vol.
As
this refers to intra-
vi, p. 89, 1897.
.
,
V
f
*w
f
4
•
y
560
THE POSTERIOR PITUITARY AND THE NERVOUS SYSTEM
cerebral nerve-fibers, I
am
nervous system
upon
is built
brought
conclude that ike entire
to
same plan:
the
Tablets of from
to 2 grains (0.033 to 0.13 Gm.) of the desiccated gland can
be taken after meals.
Asthma, to arrest the paroxysms, by augmenting the pulmonary and tissue intake of oxygen and the cardio-vascular propi;lsion of arterial blood. From 5 to 10 minims (0.31 to 0.62 c.c.) of the 1 1000 solution of suprarenalin or adrenalin 6.
:
in 1
drachm
of saline solution should be injected,
drop by drop,
into a superficial vein, or hypodermically. 7.
To prevent
the recurrence of serous effusions in the
pleura, the peritoneum, the tunica vaginalis, etc., after aspiration,
by reducing the permeability of the
local capillaries
and
restoring the circulatory equilibrium.
In neuralgia or neuritis, as pointed out by Cai'leton, applied to the cutaneous surface over the diseased area to pro8.
duce ischaemia of the hyperamic nerves and thus arrest the
One
pain.
to 2
minims
(0.12 c.c.) of a 1 to 1000 adrenalin
ointment should be applied by inunction.
PITUITARY ORGANOTHERAPY. I have submitted elsewhere in this M'hich
have led
pituitary body as
work the manj^ reasons from those who consider the a secreting gland, and to attribute to tliis
me
to
differ
organ the functions of a composite nerve-center. Pituitary organotherapy, tbough of marked value, does not mean to me, therefore, as did the organic preparations reviewed so far in the
present chapter, the scientific use of a substance which carries on well-defined functions in the body, but rather the use of a
—
PITUITARY ORGANOTHERAPY.
7G()
tissue
mainly in chromafjin suhslance and nucleins, or in substances capable of producing jointly the effects of
rich
at least
adrenal preparations
generally
(a
recognized
modified,
faet)
and indeed improved, through their combination with other components of the pituitary body. I may recall in this connection that of the two lobes, as shown by Howell, Silvestrini,
Thaon,’®^ and others, the posterior
is
the only one whose e.vtracts
are active therapeutically, but that, as shown by Crowe, Cushing,
and Homans,’"'*
it
death in animals
—
not removal of this lobe which causes
is
as
it
should, were
it
like the adrenals
the thyroparathyroid body, a secreting gland important to
but removal of the anterior, which thera])eutically \\'biit
therefore, will not
offer,
inert.
is
explanation of the role of pituitary preparations take the
so-called
and
life
1
secretion into
will ac-
fact we have at our shown by Wiesel, the the active composterior lobe is rich in chromaffin substance ponent of adrenal tissue and that it is mainly the physiological though advantageously modified as a effects of this substance
count;
it
will
the
utilize
disposal for this purpose,
only certain that,
viz.,
as
—
— —
therapeutic agent through
its
condjination with other constit-
uents of the same tissue, I repeat
—that we
The phenomena awakened by
witness.
pituitary are strikingly those
and Bose’"® found, in 1896, that subcutaneous injections of pituitaiy extract produced a rise of temperature which lasted but a couple of hours. An intravenous of adrenal preparations.
IMairet
marked myosis, slowing of the cardiac beats, and hyperthermia as main
dose produced ful
respiration, powersigns, the animals
Schafer and Vincent'"" then found that pituitary substance raised the blood-pressure besides containing a depressor substance and that this substance when applied to recovering, however.
—
—
mucous inend)ranes caused blanching, as tion of adrenalin is applied.
mammals
it
They
is
the case
when
a solu-
also noted that in small
caused, in toxic doses, paralytic
symptoms which
they also consider analogous to those caused by adrenal extracts. According to Jas. Barr,'"^ pituitary extract actively produces ^o^Thaon: L’hypophyse, p. 99, 1907. tj Crowe, Cushing, and Homansi Bulletin of the Johns Hopkins Hospital, i
May,
i
1910.
Malret and Bose: Schiifer
Barr:
Arch, do physiol.,
and Sw’ale Vincent: Lancet,
Nov.
13,
1899.
p.
600,
1896. p.
Jour, of Physiol.,
8i.
vol.
xxv,
1899.
PITUITARY ORGANOTHERAPY.
767
and it is also known to produce glycosuria. In awakens all the typical phenomena, physiological and pathological, to which the adrenal product gives rise. The marked advantage of pituitary owing, doubtless, to the fact that it is bound up in organic combination with other arteriosclerosis,
other words,
it
—
components of the organ pressure to which
it
more
thus being
—
that
is
gives rise
sustains the rise of blood-
it
much
reliable in shock
longer than does adrenalin,
and other emergency cases. and the muscular tone,
It seems also to sustain the temperature
cardiac, vascular, intestinal,
and
uterine, longer than the adrenal
advantage
It possesses also a great practical
active principle.
over adrenalin and other adrenal principles in that
administered by the mouth without compromising
A fonn
product called “pituitrin”
its
b}"^
of a powder, is available on our
dose of which this dose
termed
market for
oral use, the
given as 10 to 30 grains (0.66 to 2 Gm.).
most
But
Gm.) being
cases.
also a liquid extract of the posterior lobe,
iS
can be
manufacturers, in the
too large, 5 to 10 grains (0.33 to 0.66
is
sufficient in
There
is
it
its effects.
“infundibular
extract,”
the
infundibulum
wrongly
being
the
pedicle which unites both lobes of the pituitary to the base of
This infundibular extract
the brain.
affects mucous membranes and should be applied only eight or ten times the same quantity of saline
precisely as do adrenal extractives,
when
diluted in
solution.
It
may
doses, or intramuscularly in 3- to 15-
c.c.)
doses.
Another liquid preparation in small flasks containing 15 cent,
extract,
grains (0.2 agent.
the
Gm.)
minim (0.62 minim (0.2 to
be given orally in 10- to 30-
c.e.)
quantity
is
also available,
minims (0.92
for
one
of the posterior lobe,
i.e.,
c.c.)
injection
to 2
0.92
“vaporole,”
of a 20 per
representing
3
which contains the active
The
injection should be given intramuscularly in the gluteal region, under strict antisepsis.
CAuniAc Disorders.
— As
sIiomti
by Benon and Delille,^®® and corrects
pituitary gland raises the depressed arterial tension purely functional disorders of rhythm. It is
recommended
in doses ranging
S°c. ae rnnpp^o de Mddecine de Paris, Oct., Thfrnp.. Gongres 1907.
Jan.
from 22
3 to 6 grains (0.2
and
April
23,
1907,
and
PITUITARY ORGANOTHERAPY.
768
to 0.4 Gni.)
of the whole glaiul, in inyocanlial weakness, par-
due
ticularly in that
receding, scanty. theless
OBSTETRICS.
the
jmlse
While serves
heconiing more
is
less active
valuable
a
when
infections
to
the hlood-pressure
than digitalis as a diuretic, purpose
in
it
never-
connection.
this
is
and the urine
rapid,
It
is
advantageous in mitral disorders when there
is
hyposy.stole
and
in chronic myocarditis, particularly that
to alcoholism.
It
is also
due
useful in the tachycardia of certain neuroses and during
menopause.
These results have been confirmed by
Trerotoli,^®”
Parisot,"" and others. It is contraindicated in aortic affections in any disorder in which high vascular tension prevails, and where there is a tendency to anginal pains, which it tends greatly to aggravate.
Pituitary gland
preferred to adrenal and particularly
is
adrenalin, as stated above,
when
former being useful in urgent
the action
is
to he sustained, the
Kenon and
cases.
Delille,
how-
and recommend pituitary gland only when Leonard Williams,”' on the other hand, deems
ever, prefer digitalis,
the latter it
fails.
superior
to
classic tonics
.
digitalis,
strophanthus,
what he terms the ‘Runaway heart of
in
states,” influenza,
pneumonia, bronchitis,
hut low blood-pressure, and in
]W)int,
instances
are
etc.,
all cases in
to.xic
with tachycardia,
which there
is
post-
—which, from my viewhypoadrenia—Williams regards
In these cases
cardiac debility.
to.xic
and other
strychnine,
of
pure
command. In heart- failure and shock, it has been highly recommended by l\Tummerv and Lymes and Bell and Wray, 15 minims (0.92 pituitary preparations superior to any remedy at our
c.c.)
While
of the extract being injected intramuscularly.
virtues effects
number
its
would seem to recommend it for the perpetuation of the of adrenalin, which are, at best, but temporary, the of cases in which
it
has been tried has been too limited
so far to warrant an opinion as to its actual value.
Obstetrics.
—Oale”^ found,
in the course of
comprehensive
experiments, that (in keeping with the adrenal secretions) the action of extract of pituitary was “a direct stimulation of involuntary
muscle
without
any
relation
to
innervation.”
and 33, 190 grains (0.50 Gm.) in divided The symptoms tend to return, however, on dis-
doses daily.
Cases subsequently treated were also
continuing the remedy. benefited, but
no cures were
effected.
from my viewpoint, corresponds precisely with that referred to under the preceding heading. We have seen in the fifth chapter that the main pathological condition, that to which all the prominent symptoms of ex''.I’iiis
mode
of
action,
ophthalmic goiter were due, was a general dilatation of the artePituitary extracts causing constriction of these vessels rioles. as long as it is administered, it offsets for the time the morbid
That such
phenomena enumerated.
is
actually the case was
M'ho found, experiand Carrion, their effects produced “always mentally, that pituitary extracts by raising the arterial tension,” producing at the same time
demonstrated by
II allion
“an intense vasoconstrictor action iqion the thyroid body. here precisely the physiological action necesof sary, the va.soconstrictor jiower of the adrenal component Briefly,
we bave
Renon and
Delllle:
Hallion and Carrion:
Soc.
Oesthfirap.,
I Mil.
March
13,
1907.
—
—
773
PITUITARY ORGANOTHERAPY.
the pituitary gland superseding the vasodilator action of the thyroid, the underlying cause of the disease.
Nervous and 1\Iental Diseases and Myopathies. Eenon and Delille used pituitary in 10 neurasthenics in whom tachycardia, irregular vascular tension, often beloiv normal, a sensation
of
.
were present.
myasthenia,
ojipression,
In these
insomnia,
cases, 3 to 5 grains
daily proved remarkably useful,
and
anore.xia
(0.2 to 0.3
Gm.)
though no complete recovery
was noted.
and Vincent’-® obtained a complete recovery in a
Delille
grave case of bulbo-spinal myasthenia by the simultaneous use
Parhon and Urechia and Leopold-Levi and de Eothschild’-’ had also obtained favorable and ovarian
of pituitary
e.xtracts.
results with pituitary in
good,
in
effects
similar cases.
of
cases
chorea
in
Browning’-® observed
which this disorder
oc-
curred in conjunction with stunted growth, as shown under the next heading.
In epilepsy,
it
was tried by Mairet and Bose,’-® but only
—
served to increase the
of attacks
since
number Spitzka has shown that
these were due to abnormal eleva-
tion
of
the
blood-pressure.'
a result to be expected,
In some instances
it
provoked
delirium. Sollier
and found
and Chartier’®® it
tried pituitary in
useful in depressive states.
mental disorders
It raised the blood-
pressure, reduced the pulse, suppressed profuse sweating,
improved the asthenia.
The
and
synthesis of perceptions and the
association of ideas were improved,
and mental operations were more promptly. Stunted Growth and Imbecility. In the case of a child years, which had shown the evidences of hypothyroidia with
incited
of 3
idiocy sufficiently to suggest the use of thyroid, Leopold-Levi
and de Bothschild found
this agent useless. The case being attended with marked myasthenia, they administered pituitary extract D/b grains (0.1 Gm.) twice daily, which corresjionded
with of
grains (0.5
Gm.) of the
improvement appeared within
a
fresh gland.
few days.
The
1“ Pf'iRe and Vincent: Soc. de Neurol., Feb. 7, 1907. Leopold-Levi and de Rothschild: Ihxd. Journai of Medicine, Sept, i»o Soiiicr
and Chartier:
''e Physioi.. p. 600, 1896. Congrfis de Dijou, Aug., 1308.
]\[arked signs
intelligence
1909.
—
PITUITARY ORGANOTHERAPY.
774
PARESIS.
developed to a remarkable degree, and soon reached that of a child of a corresponding age, 3 years, though before the treat-
ment
Two
did not exceed that of a 7 or 8 months’ infant.
it
similar cases, one of which showed symjitoms of Little’s disease,
were similarly benefited. Browning’''" used pituitary only in undersized or backward
He
children and youths (not real dwarfs or midgets).
following histories
A
gives the
:
had made little or no recent advance in growth. On pituitary, with some accessories for the chorea, she gained a couple of pounds in weight and over an inch in height in three and a half months, the chorea 1.
frail,
choreic girl of 14 years
A
boy of 2 years, after a period of cessation of growth, increased from 25 to over 30 disappearing.
pounds
(i.e.,
2.
slightly
rachitic
over 20 per cent.) in six months on the somewhat ^besides recovering in all
—
irregular administration of pituitary,
ways, and keeping up his good progress since, though at a slower
Browning noted when growth
rate.
way
it
is
usually keeps on satisfactorily.
once started up in this 3.
A
somewhat choreic
boy of 13 years and of scanty physique received pituitary, x\lthough his growth besides at times arsenic and accessories.
was said
to
have been at a standstill previous to
this,
he gained
and 10 pounds in weight in the next eight In another ton months, on somewhat irregular con-
2 inches in height
months.
tinuation of the pituitary, he in height
and
1
1
pounds
made
in weight,
a further gain of 3 inches
—when the
inquire anxiously for agents with the opposite record for a j'ear and a half,
of. 5
father began to
effect.
is
a
inches in height and over 20
pounds in weight, the patient having been under 70 pounds at the
This
5(!
inches and
start.
Intestinal Paresis.
—
Bell
and Hicks’®" have found
pitui-
tary extract of value in paralytic distention of the intestines. It never failed either in post-operative or other ^larcsis if given the intestine begins to distend in 15-
intramuscularly
minim
when
doses (0.02 c.c.) repeated in an hour,
if
rc(]uired.
I
he
he beneficial then sustained by daily doses if need be. few influence of the injections was, as a rule, noticeable in a I
effect is
minutes. Browning: Lnr. Ht. ‘“Bell and Hicks: British Medical Journal, March
27.
19irJ.
OVAKIAN OKGANOTHEHAPY.
775
OVARIAN ORGANOTHERAPY. As
is
well known, the ovaries correspond in
with the testes in
tlieir
many
particulars
Eemoval of the utenis and
upon development.
inlluence
the former prevents the normal development of
the appearance of menstruation, while their removal after puberty arrests menstruation
and
is
followed by atrophy of the remaining
structures of the genital apparatus.
The whole organism
is
in-
the ovaries, for their destruction or absence causes
fluenced by
grow without the general physical attributes of the This led Brown-Sequard to consider the ovaries as tlie source of an internal secretion. This view has been upheld by many observers who found that ovaries transplanted in the abdominal cavity, t.e., elsewhere than in their normal location, restored to the other genital organs the power to develop and girls
to
female
sex.
The identity of this and the manner in which it carries
carry on their physiological functions.
supposed internal secretion
on
its
function have, however, remained obscure.
My own
view, submitted at the beginning of this chapter,
does not cover this feature:
it
refers only to the
which ovarian preparations produce their it is
in
It points out
awakened by adrenal substance,
that these are similar to those
and that
effects.
manner
—not
probably to the presence of this substance
—
in the ovaries that they must shown by Schafer, a close homology between the interstitial of the ovary and the same cells in the adrenals; both sets of organs are derived from the Wolffian body; ovarian extract raises the blood-pressure and slows the heart, as sho^vn by Federoff,^^® Jacobs,^®* and otliers. Eemoval of the ovaries, moreover, reduces the oxygen intake 10 per cent., as shown by Loewy and Eichter,^^'^ while ovarian extract restores
necessarily an internal secretion
There
be attributed.
it;
it
exists, as
has been, therefore, regarded as an oxidizing ferment.
Neumann and metabolism
Vas^'"'
noted
that
Senator observed
;
ovarian
that
enhanced
e.xtract
ovarian,
preparations
in-
creased diuresis and the excretion of urea and phosphoric acid. Its phy.siological effects are those of adrenal preparations, therefore, in every respect. 133
Fedoroff:
Jacobs:
La Gyndcologle,
Oct. 15, 1891.
Dublin Jour, of the Med.
Loewy and
Richter;
Neumann and Vas:
Berlin, klin.
Monats.
f.
Scl.,
Sept.
1.
1897.
Woch., Bd. xxxvi,
Geburtsh.
u.
S.
1095,
1899. 433,
Gyn., Bd. xv, S.
1902.
OVARIAN ORGANOTHERAPY.
776 Its eU'ects
been
liavc
on oxidation are
clearly
recognized
so striking, in fact, tliat tlicy
by many
clinicians.
among
authorized to classify ovarian organotherapy agents,” write Ualcbe and Ijepinois.*'’^
be admitted,
is
“Tliis conclusion,
are
it
must
Curatcllo and
that reached by several authors.
Tarulli believe that
“W’e
the oxidizing
internal secretion of the ovaries favors
tlie
the oxidation of phosphorized organic substances, hydrocarbons,
and
According
fats.
to
Gomes,
it
enhances
oxidation
and
hydrolysis and favors the elimination of phosphates.
Albert Eobin and Slaurice Binet have shown that there
menstruation an increase of the respiratory exchange.
is
during Keller,
studying the general exchanges, found that there was increased nitrogen oxidation. in
enhances
itself,
We
have ourselves found that menstruation,
vital
functions and particularly the great Sauve'^’" states that ovarian
function of general oxidation.”
extract increases the haunoglobin content of the blood.
The prepamiion in general use is which may be given in doses of 2 to 5 Gm.) twice daily. The fresh organ may 15- grain
product should
(0.6
to
1.0
grains (0.132 to 0.33 l)e
Gm.) doses where
is not available.
first
the desiccated gland,
employed the
in 10- to
pharmaceutical
It soon loses its effect; small doses
be given, then gradually increased.
Ovarian preparations have been tried in
many
disorders, but
mainly in connection with those of the genital apparatus that they have been found of actual value. Natural axd Artificial ]\1 exopause. In disorders occurring in the course of the physiological menopause, or when it
is
—
the latter
is
produced by bilateral oophorectomy, ovarian prep-
arations have proven of considerable value in a large proportion of cases since Brown-Sequard first introduced their use. Experi-
ence has shown, however, that the improvement lasts only as long as the agent is administered, and tliat, furthermore, certain
phenomena
:
the palpitation, trembling, and “nervousness,” dis-
appear earlier than the others, bility,
and psychoses, though
the cutaneous disorders,
—
i.e.,
the asthenia, flushes, irrita-
effects in all
symptoms, including
especially acne rosacea and eczema,
are promptly realized, sometimes as early as the fourth day. nalche and Ldpinols; Bull. ggn. Sauve; Parts mOdical, April 1,
d.
thdrap., Jan.
1911.
8,
1902.
777
CORPUS LUTEUM ORGANOTHERAPY. These tlie
effects
are normally explained by the influence of
remedy on general oxidation and the improvement of
antitoxie functions of the blood,
ttie
the imperfect hydrolysis
tissue wastes being the underlying cause of the
phenomena
of
other
than the general asthenia.
The
best results are obtained in
grown obese
young women who have
after removal of the ovaries, or in
whom
obesity
is
In physiological menopause they marked, as a rule, and sometimes fail altogether to In such instances, good results may sometimes be
due to ovarian insufficiency. are less
appear.
Gm.) desiccated remedy alone. In
obtained by giving simultaneously 1 grain (0.066 thyroid, or by depending
upon the
latter
congenital ovarian insufficieney, desiccated ovary has caused the
appearance of menstruation.
W.
E. Dixon,’®® of Cambridge University, recalls that the
presence of ovarian tissue in the body, however small in amount, is
sufficient to
prevent
tire
distressing sjunptoms
which frequently
follow comjffete extirpation; even transplanted ovaries are some-
times able to prevent the menopause attending removal of the ovaries.
Hence the
beneficial effects of ovarian preparations.
Of late, however, the general attention has been centered upon the therapeutic use of the essential structure of the ovary, the corpus luteum.
CORPUS LUTEUM ORGANOTHERAPY. The consensus
of opinion at the present time is that the
internal secretion of the ovary
The function
is
produced by the corpus luteum.
of the corpora lutea in the early stages of their
life is to initiate
growth
j^i’ocesses
of this internal secretion
in the uterine cavity by
and subsequently
means
to ^rreside over the
nidation and development of the ovum, and the cyclic engorge-
ment preceding menstruation.
The
recent labors of Fraenkel’®®
confirming his previous investigations have strongly sustained the internal secretion theory and the above functions.
He
its
controlling influence over
found, moreover, that the therapeutic
value of corpus luteum was limited to cases presenting symjjtoms of vasomotor origin due to absent or deficient ovarian activity. ’“Dixon;
Practitioner, May, 1901.
laopraenkel:
Archiv
f.
Gynekologie, B.
xci,
S.
705, 1910.
CORPUS LUTEUM ORGANOTHERAPY.
778
Tliis coincides with tlie earlier conclusion of J. G. Clarke*^®
that the
ollice
of the corpus luteuni was,
among
others, that of
—
“a preserver of the ovarian circulation” a fact which explains in turn the presence of adrenal-like tissue, whose secretion, as is well known, is eminently capable of sustaining vascular Indeed,
tone.
as
generally
is
believed,
it
corpus
the
is
luteum which produces the ovarian internal secretion; it should, in accord with what I have stated concerning the mode of action of the ovaries, also produce effects similar to those of
We
adrenal preparations.
hypernephroma witnessed
is
of
need but
children
one
recall that in the adrenal
the
of
phenomena
essential
the extraordinary development of the genital organs,
those of a child of 5 years, for instance, being practically those of an
adult.
primary
Bouin, Ancel, and Yillemin*'*^ found that the
effect
was a violent
of toxic doses of lutean extract
elevation of the blood-pressure, sufficient to produce effusion into all
serous
The
cavities.
physiological
effects
therapeutic
of
doses have not been sufficiently studied to show positively, as
was the case with the ovaries, that they are all those of adrenal preparations, though Avhat there is known points in that direc-
One
tion.
fact
is
certain, however, viz., the functions of the
organ should not be ascribed to is
its
internal secretion
its
;
mission
probably limited to that of sustaining the circulation of the
ovarian circulation, as pointed out by J. G. Clarke.
The
‘preparations available include desiccated corpus luteum
{glandulce lutei desiccatce), which (0.2 to 0.3
Gm.) doses it
be given in
three times dail 3^
istered before meals, but
gastric disturbances
may
if,
may
as is
It
is
3- to 5-
sometimes the
case, it causes
be administered during, that
say, in the course of, the meal.
The term “lutein”
applied to the same product, but
it
is
grain
usually admin-
is
is
to
sometimes
misleading, and
its
use
should be discouraged.
The
indications for desiccated luteum are similar to those
for ovarian preparations.
Natural and Postoperative IMenopause.
—
It
must be
said that the evidence as to the therapeutic value of desiccated
luteum
is,
to say the least, conflicting.
^lorley,*^'
’"’Clarke: Johns Hopkins Hospital Report, vol. 11, No. >*> Bouin, Ancel, and Vlllemln: Nouveaux Rem6des, March ’“Morley: Jour. Mich. State Med. Soc., Nov., 1909.
who 8,
supplied
1907.
'
CORPUS LUTEUM ORGANOTHERAPY. desiccated luteum to ten physicians,
779
and obtained reports
use in 18 cases, 14 of which sulfered from postoperative
from natural menopause, states tliat 12 improved, and that hut 1 failed to be relieved.
pause, and 4
5
o£ its
meno-
were cured,
C. A. IIill““ also reported results obtained with extract of
corpora lutea in 12 patients, ranging in age from 25 to 38 years,
who showed
symptoms after The “nenmusness” was completely
the most severe type of nervous
removal of both ovaries.
relieved by the treatment in each case.
In only 2
cases,
however,
was there complete relief from flashes of heat. In another case, suffering from insomnia, which had continued ever since the operation over a year before, and was uninfluenced by hypnotics,
complete relief was attained after the use of 50 5-grain (0.33
Gm.)
One
an increase in sexual desire, wliile in the remainder no noticeable change was experienced. No complete cures were obtained. Several cases had interrupted capsules.
case reported
and others, who ceased treatment, were comowing to return of symptoms. The preparation each case was given in 5-grain (0.33 Gm.) capsules three
treatment
onl}',
pelled to resume in
times daily, one-half to one hour before meals.
On
the other hand, Ellice McDonakT'*'* publishes a report
of 20 personal cases in Avhich he had used a similar preparation.
“The five
though they
results of this study, small
be,
extending over
years,” writes this observer in his conclusions,
“seem to menopause need not be value is in cases in which the
indicate that the control of surgical
sought in the corpora lutea.
Its
uterus and ovaries or uterus alone are retained. it
Particularly
is
valuable in the treatment of scanty menstruation and the
premature menopause.
have treated a number of cases at the outdoor dispensary of the Kensington Hospital for Women, with I.
extract of the whole ovary,
But the
therefrom.
and never saw any
d'efinite results
lutein extract, being the essential part of
the ovary, does seem
to help in some degree and should -be accompanied, in suitable eases, by dilatation of the utenis, with the use of the stem pessary following operation, as advised by
Manson.
At
least,
administration of lutein
operations on pregnant
in
whom
is
indicated after
miscarriage
Gynecology, and Obstetrics, Dec., 1910. Jour. Amer. Med. Assoc., July 16, 1910.
S'i'-gery,
McDonald:
women
is
feared.
7S0 i
OUCUITIG OKGANOTHEUAPY.
his is particularly true in the early weeks of prej^Tiancy during
the iinhedding of the ovum, as it has been shown experimentally that the corpus lutcum has a definite effect under such cir-
cumstances.” It is obvious that the clinical experience at our disposal still
is
too limited to warrant any decision as to the actual value
of corpus luteum, though
must be said that many desultory have been published in which its rise was extolled.
cases
McDonald
it
rightly lays stress on the facts that “the manifesta-
tions of the surgical
menopause are
and extreme to
too varied
allow explanation by the mere absence of the internal secretion of the ovary.
The
internal secretion of the ovary
is
but
a factor
in the process of the menstrual life.” I
would go one step further and express
a
doubt that we
are dealing at all with an “internal secretion,'’ a designation
applied to almost any organic juice nowadays, and reiterate what I
say elsewhere,
than
is
viz.,
that true internal secretions
are
fewer
generally believed.
ORCHITIC OR TESTICULAR ORGAXOTIIKRAPY.
From
the standpoint of therapeutics, testicular prepara-
tions can hardly be regarded as of
The
more than
historical interest.
influence of the testicles on the body at large
is
well
known.
Castration influences the development of the organism in particulars. acteristics
Eunuchs preserve
to
a
certain
many
extent the char-
of infantilism, the skin remaining soft and white,
and weak, and the voice high pitched. Yet thej' are usually tall, owing to inordinate growth of the bones. They lack courage, initiative, and intelligence. It is evident, their muscles flabby
therefore, that the testicles do not carry on genital functions
onl 3^
Brown-Sequard taught that they carried on
1st, procreation
;
a dual role:
2d, the production of an internal secretion
which stimulates and sustains the energy of the nerve-centers and cord, and capable, moreover, of endowing the individual with physical, moral, and intellectual characteristics of sex. Ilis own physical and intellectual activity having been greatly improved at the age of 72 j'oars, by injections of^ an extract prepared from the testes of young dogs, he concluded that it
—
TESTICULAR ORGANOTHERAPY.
781
marked therapeutic value. No one who, as I did, saw Erown-Sequard before and after he had submitted himself to possessed
could
treatment
this
imagination
his
stretch
sufficiently
attribute the change in his appearance to auto-suggestion,
to
lie
literally looked twenty years younger.
The from
prevailing opinion
is
preparations
testicular
that the beneficial effects obtained are
not
due necessarily
though the existence of such
internal secretion,
is
to
an
not denied,
but to nucleo-albumins, substances that are rich in iffiosphorus, resembling greatly lecithins and glycerophosphates.
As previously from
my
stated, the testicular active principle, sperniin,
viewpoint,
is,
or at- least corresponds with, as to its
physiologieal action with the adrenal principle.
that
the
Shaw,^''®
latter
oxidation
sustains
unaware
of
and
any such connection, writes:
and, according to Poehl,
is
body
tissues.”
urged that the adrenal secretion carries on as
a
Batty
“Spermin carrier,
responsible for those internal oxida-
tions which take place in the
catalytically
have seen
an oxygen
possesses the very curious jiroperty of being
tion
We
metabolism.
ferment.
its
Again, I have
oxygenizing func-
Pantchenko^'*®
states
that
“Spermin acts catalytically, thus increasing the oxidizing power of the blood, and simultaneously activates the intraorganic oxidation processes where these are weakened.” Moreover, as is the ease with the active adrenal secretion, spermin gives, according to ]\Iari, the guaiac and Florence hasmin test which consists in adding a drop of iodine-potassium iodide solution to the fluid obtained by soaking a seminal stain in water.
At the point
of contact of the
two drops, dark-brown needle-
shaped or rhomboidal crystals will form which resemble the crystals of hasmin.
Dixon
states that a constituent of orchitic extract is
altered by boiling;
McCarthy holds that
and regularity of the heart much
it
un-
increases the force
as does digitalis.
It enhances
the resistance to disease, increases the production of urea, and also acts directly as
shown by Poehl
upon the cardio-vaseular system. ]\Ioreover, fact which indicates that it is not specific
—a
““Shaw: “Organotherapy,” Pantchenko:
p.
205,
Tribune mOdicale,
1905.
vol,
.\xvil,
p,
11,
1896,
—
KIDNKY OKGANOTHliUAl’Y.
782 to tlie testis
it is
in the female as
a ul>i(iuitous constituoiit of the whole organipin,
M-ell
as the male.
Testicular preparations, including sperniin, have been reeoin-
niended in a host of disorders, particularly tabes, neurastlienia, melancholia, impotence, and paralysis agitans; in several cuta-
neous disorders, eczema and psoriasis; in disorders of nutrition, gout, obesity, and glycosuria; but others again have failed to
obtain any favorable results.
mended by Poehl and
Spermin has
the foregoing disorders, but in
rheumatism, as typhoid
also
been recom-
his followers not only in the majority of
many
others besides, in acne,
marasmus, and in various infections, such diphtheria, and even cholera. It has been
syphilis,
fever,
tried in Addison’s disease, but adrenal preparations are to be
preferred.
is
In the light of the analysis submitted above, however, there belief that beneficial effects were obtained
good ground for the
in all these maladies.
That the nucleo-albumins of
orchitic
extract acting as would glycerophosphates could be beneficial in
the disorders enumerated, no one can deny.
he
said,
This can hardly
however, of the cutaneous and nutritional disorders,
unless the spermin the extract contains, hy enhancing oxidation
and the destniction of Spermin itself agent.
toxic wastes,
—
as
proves to be the aetive
adrenoxidase
—
is
unquestionably
capable of doing this actively, and in syphilis and marasmus to markedl}'^
enhance the functional activity of
all tissues.
the beneficial role of spermin in infections finds
its
Again,
explanation
I have repeatedly emphasized, viz., that the oxygenized adrenal secretion, the active agent of spermin, from my view-
in a fact
point,
is
an active participant
in all
immunizing
processes, local
and general. The main point to determine, however, is whether orchitic extract, or spermin. a (fords better or as good results in any of the disorders enumerated than other remedies at our disposal.
The
evidence available indicates that such
is
not the case.
KIDNEY ORG ANOTIIEi;.\PY. That the kidneys produce an internal secretion is still Brown-Sequard, having removed the kidneys and problematic. caused urajmia, found that the injection of a glycerin extract of
783
KIDNEY ORGANOTHERAPY. kidney prolonged the
life
of the animals as
compared
to those
in wliich the same operation was not followed by the use of
tlie
This experiment, which has been repeated by others, forms the basis of the belief that the kidney produces an That such a conclusion may not be warinternal secretion. kidney extract.
ranted
is
suggested by the fact that the kidneys, along witli so far reviewed,
some of the organs tissue
—the
so-called “adrenal rests”
times develops
—and that
as such they are capable, as
immamizing functions
factor in the
are also rich in adrenal
from hypernephroma somean active
of the body, of counteracting
temporarily the toxmmia or “urasmia” brought on by removal of Indeed, the relief afforded
the kidneys.
is
but epliemeral, death
two days in rabbits, in which
being postponed but one to
Bitzou“" repeated Brown-Sequard’s experiments.
Dromain and
de Pradel Bra’^** had also noticed that injections of kidney extract lessened the
of epilepsy, another toxaimia.
fits
Dubois^'*®
and EenauP®® have also found that kidney extracts were endowed with antitoxic power.
That we
are again dealing
the adrenal principle
mainly with a manifestation of its powerful blood-
further suggested by
is
pressure-raising property.
Tigerstedt and Bergnian found that
rennin possessed this power; Bingel and Strauss^®^ recently confirmed their observation, and found that
its action corresponded with that of adrenal and pituitary extracts, those of other organs causing depressor effects. The rise of pressure produced by kidney extract was high, t.e., from 40 to 60 mm. Hg, and
lasted from fifteen to thirty minutes. The authors concluded, moreover, that “the action of rennin, like that of adrenalin, is
exerted in the muscles of the peripheral vessels.” action, however, is
more
like that of pituitary
Its general
body
extract, the
adrenal principle being doubtless combined organically, as in the pituitary, with bodies
which prolong and perhaps control adLike adrenal prepara-
vantageously the action of the former. tions kidney extract produces
sustains
my
’”Bitzou: T,,
.
niol.,
opinion that
dilatation
action
is
of the
pupil.
This
duo to adrenal principle.
Jour, de physiol, ct de path, gdner., Nov. I.'i, 1901. Pradel Bra: C.-r. heh. dcs sel. et mdm. de la Soc. de
Paris, 1895. '“Dubois: Soc. de Biol., p. 287, 1.90.8. '“Renaut: Bull. gdn. de thOrnp., T. 117,
Strauss: 9r
its
Deut. Archly
f.
pp. kiln.
.8
and
27,
1904. S.
Med., xcvl,
470,
1909;
July
KIDNEY ORGANOTHERAPY.
784
Even the oxidizing power
1 liave cattribiitecl to the adrenal
secretion seems to be reproduced
“very
little justilication
Batty Shaw/®^ who 4ilso finds
;
for the existence, of an internal secre-
tion” in the kidney, remarks that “possibly nephrin and other renal preparations provide a
means
of stimulating oxidation in
—
general, the kidney merely sharing in this oxidation”
accurate estimate from
my
Shaw
viewpoint.
a verj'
adds, moreover,
that “similar good results have been reported as a result of
treatment by means of spemiin and testicular extract,” both of which, as I have shown, also owe, in all probability, their therapeutic effects to the adrenal principle they contain.
The
therapeutic application of kidney preparations has re-
ceived considerable attention, and favorable results have been
reported in about one-half of the cases of chronic nephritis, or Bright’s disease, in which
it
was
The mode
tried.
the light of the facts submitted above,
is
of action, in
mainly an increase of
the antitoxic power of the blood and diminution, therefore, of
Page and
the irritation of renal apparatus.
example,
report
marked amelioration
maceration prepared as follows:
A
in
for
Dardelin,'''®
18
cases,
verj^ fresh
using
a
kidney from a
is cut into minute pieces, washed with fresh water to remove the excess of urine, then hashed and pounded into pulp. This pulp is put into 300 grammes (9 ounces and 5 drachms) of fresh water to which the physiological proportion of salt, 7.50
pig
to 1000, has
been added.
It is then allowed to macerate for three
hours, stirred occasionally, and kept in a cool place to avoid
fermentation.
The
red water of the maceration
is
divided into
three parts to be drunk by the patient during the day.
It is
more conveniently given, however, in tablet form, as “nephritin” Only the active
prepared in this country by Heed and Carnrick.
used in this preparation, the dose
substance of the kidney being from 10 to 15 5-grain (0.33 Gin.) tablets daily in divided is
doses, given between meals.
Kidney advantage field is
for
prejiarations have also been used with
in
puerperal
intoxications
more
or less
and epilepsy, but their and particularly
essentially the various forms of nephritis,
the
])revention
of
uramiia.
’“Shaw: Lac. Ht., p. 21fi. ’“Page and Dardelin: Press© m^dlcale,
They
Dec.
also
21,
1904.
tend
to
increase
MAMMARY GLAND ORGANOTHERAPY. diuresis
and reduce
tiie
As
albumin.
785
stated above, however, favor-
able effects are to be expected in about one-half of the cases.
MAMMARY GLAND ORGANOTHERAPY. by some that the
It is held
internal secretion, but
weak that by
it
gland produces an
is
on the subject
and in
this country
by the
is
so
Introduced
can hardly be taken into account.
it
Bell, of Glasgow,
Shober,
mammary
what evidence there
late
John H.
has shown therapeutically marked stimulating action
upon the uterus, but the manner in which it produces this effect has remained obscure. An extract lowers somewhat, and but temporarily, the blood-pressure and the pulse. According to Shober, it diminishes the blood supplied to the uterus and thus controls liaBinorrhage, its action resembling that of ergot,
point, therefore,
would
it
though
From my
free of the unpleasant effects of the latter drug.
view-
act by causing constriction of the
arterioles.
Mammary
gland
is
prepared in the form of a tablet
made
of the desiccated gland of the sheep, each tablet representing 20 grains (1.32
Gm.)
of the fresh gland.
The
dose
is
from
3 to 6
tablets daily.
The
therapeutic applicaiion
is
restricted to the genital ap-
In cases of uterine fibroids characterized by excessive menorrhagia and metrorrhagia the bleeding was found by Shober paratus.
to be cojitrolled in a
few weeks and the periods become regular,
normal, and free from pain. patient’s health
in size
up
Ther'^ is improvement in the and weight, and the tumors themselves diminish
to a certain point.
better condition for sity for
The
patient
is’
thus placed in a
any needed operation, and often the neces-
an operation
is
postponed.
Where
there
is
evidence of
inflammatory or degenerative changes, or when serious pressure symptoms are not controlled after a reasonable trial, operation should not be delayed. In 43 cases of uterine fibroma treated by Fedoroff, cure
is
claimed to have been obtained in 33. while there
was a marked reduction of the growth in 43 ])or cent. Mammary gland is also, useful in cases of subinvolution unassociated with Jnalignancy or structural changes. Pozzi has advocated use in uterine hemorrhage of any kind attending metritis.
its
;
THYMUS ORGANOTHERAPY.
78(j
]\rammary gland 1ms also been recommended involution and to enhance lactation.
to assist uterine
on the use
JUit the reports
of this agent have been antagonistic. TI I YM U S
In the ninth chapter
ORG ANOTIl E R AP Y. 4G7), 1 submitted the experimental
(p.
me to suggest, in 1907, that the function of the thymus was to supply an excess of phosphorus in and
which led
clinical evidence
organic combination during the growth of the body, ularly while the development of the osseous
demanded such
i.e.,
partic-
and nervous systems
This was sustained by the recognized
a reserve.
and adolescents, especially and trophic disorders of the brain and
fact that certain diseases of children
marasmus,
rachitis,
nervous system, were due, in part, to the functions of the thymus.
While
it
cannot be affirmed that this theory actually represents
the function of the organ
—
the
many hypotheses— all
yard of
thymus Jiaving been the grave-
that can be said for
it is
seems to account for the clinical results obtained under
that its
it
use
better than any hypothesis so far advanced, besides correspond-,
ing with the laboratory findings of
Diseases of the Thyroid.
by
tried
its effects.
—In
who obtained
ilikulicz,^®'*
simple goiter
it
was
first
sufficiently favorable results
in 5 out of 11 cases to render operation unnecessary, at least for
the time being,
lleinbach'-"''^
considers
probably superior to
it
thyroid because the unpleasant effects of the latter are avoided for the
same reason
it is
especially suitable
has to be used continuously.
This view
is
when organotherapy
based on the employ-
thymus in a large number of cases in the Breslau clinic, ilikulicz gave from 2]/> to 4 drachms (10 to 10 Gm.) of the raw sheep thymus on bread three times a week, increasing the dose to 7 drachms (28 Gm.) if required. IVe have seen that in oxophthalmic goiter it had proven
ment
of
efficacious in the
advanced oases, and also when other remedies had been used fruit-
hands of Owen'"®
in those of Claude’'’’
in
gave 45 grains (3 Gm.) daily to a severe ease, wliieh greatly improved, relapsing whenever the treatment was
lessly.
The
latter
IM Mikulicz:
Berlin, kiln. Woch., Bd. xxxii, S. ni2, 1895.
.Mittheil. uus den Grenzgebiet. d. Brit. Med. Jour., Oct. 10, 1890.
’“Reinbach:
'“Owen: Maude:
London Lancet, July
18,
189C.
Med.
u. Chir., B. ,
I.
S. 202, 1896.
787
THYMUS ORGANOTHERAPY'.
S. Solis-Cohen^®*' also advocates its use in this dis-
interrupted. ease,
having found that
exerted
it
influence mainly
its beneficial
upon the nervous symptoms of the disease without affecting the exophthalmns. Huston White*®” found that the nervous symptoms were alone improved. These observations coincide with my own view of the manner thymus gland produces its beneficial effects. The
in which
excess of thyroiodase produced in exophthalmic goiter causes,
we have
seen, too rapid oxidation of the
combination in the
phosphorus in organic
tissues, particularly in those of the
nervous
Thymus, supply-
system which are extremely rich in phosphorus.
ing phosphorus in organic combination, replaces that lost by the
nervous system, thus procuring marked benefit in this one direction.
As
5 grains (0.33
to 30 grains (3
Gnu)
Gm.)
thymus are equivalent
of the dried
of the fresh gland, this dose can readily
be given three times daily.
—
Eachitis, or Eickets. The same explanation, i.e., the purveying of phosphorus in oiganic combination ^to the osseous
—
system, in the present connection benefit
thymus has procured
used thymus gland in
1%
over 100 cases, obtained especially in
—accounts for the undoubted
having Mendel, drachms (6 to 13 Gm.) daily in
in this disorder.
to 3
marked
benefit in a large proportion, but
tbe nervous symptoms, including spasm of the
had previously been
glottis.
It
marked
benefit.
by Stoppato,*®* but without In Mendel’s cases both fresh and commercial tried
tablets were tried, the cases being subdivided as follows’:
1,
those which showed prodromal
symptoms only; 3, those in which deformity of the osseous system was the chief feature; 3, those marked by spasm of the glottis, and, 4, those in Yvhich splenic enlargement was the most important sign. Marked improvement was noted in all after from three to four weeks, and dentition and the closure of the fontanelle proceeded satisfactorily. No untoward symptoms were noted a marked advantage over thyroid preparations. In a case of stunted growth, obviously
—
of osseous origin, in a
boy of 14 years, E. Webb Wilcox*®^ obAssoc., Aug.
iMWhiVi? vol.
m wiicox.
18,
786, 1899. xllx, S. 134,
1900.
p.
i,
Woch., Bd.
1902.
Boston Medical and Surgical Journal, Aug. 60
13,
1908.
BRAIN AND NERVE ORGANOTHERAPY.
788
tained 9i/4 inches growth in three years by the persistent use of 2 grains (0.13 Gin.)
The view
thymus night and morning.
that these effects are due to the addition of phos-
phorus in organic combination to the body
further sustained
is
by the results of experimental observation by Hart and Nord-
mann/®® that the tlijunus had a definite relation to assimilation, and that it took an active part in the resistance of the organism to infection. As I will show in the second volume, page 878, nucleo-proteid, in so far as is
concerned,
BRAIM’
is
its
phosphorus in organic combination
an active participant in the immunizing
process.
AXD NERVE SUBSTANCE ORGANOTHERAPY.
"While these agents have given good results, the theorj’^ that
brain and nerve substance possess or produce au internal secretion has never been sustained scientifically.
The
clinical results,
though quite discordant, particularly in
the neuroses and psychoses in Avhich these preparations have been
have shown a tendency to harmonize since the introduction by Sciallero^"^ of an oily extract. Page,^®® who has obtained unusually good results in neurasthenia by means of injections
tried,
them to its antitoxic and antispasmodic Wassermann and Takaki had previously shown that effects. tetanus toxin was neutralized by contact with brain substance, and that when a fatal dose of tetanus toxin was injected with The same brain substance the fatal effects were prevented. of this extract, ascribes
observations were
made
b}' Babes ; in and Nobecourt; in in epilepsy by Lion and also Kaplan,
in the case of hydrophobia
strychnine and morphine poisoning by tetanus by Krokiewicz
;
using Poehl’s opocerebrin several years earlier.
—
in
Sciallero,
idal
accord with Dana’s experience
who
obtained encouraging results
and epilepsy, used his oily extract “cephalopin” in doses varying from 1 to 5 c.c. (16 to 81 minims). Ko untoward effects were obtained. Although it is very improbable that brain extracts injected
in neurasthenia, hysteria, chorea,
tic,
into the tissues act as they do in the test-tube, lished that they act
much
it
seems estab-
as do the lecithins on the market,
Hart and Nordmann: Berlin, kiln. Woch., May Sciallero; Riforma Medlca, Jan. 27, 1904. ^“Page: C.-r. de I’Academie de M6d., March 30,
2,
ISIO. ,
1909.
i.e..
HORMONE THERAPY.
789
by furnishing phosphorus to the organism in an assimilable form, Be or as nucleo-proteids in enhancing the immunizing process. this as it may, these substances seem to have produced effects which suggest that they are worthy of further study.
HOKMONE THERAPY. The word “honnoue” was applied hy Starling
to the
group
—
by various organs the ductless glands in work which could enhance the functions of other organs. Precisely as I had held three years earlier of substances secreted
the group studied in this
—
(the adrenal secretion exciting the thyroid, the pituitarv'^, the
pancreas, etc.; the thyroid secretion exciting the adrenals, etc.), these hormones were secreted by the organs which produced
them
normal functions, and reached the distant structures they influenced through tlie intermediary of the blood. The functions I had previously attributed to the adrenal secretion in in the course of
the tissues, or to the thyroid secretion in respect to cellular phos-
phorus, embodied precisely the same idea.
We may
regard as
“hoi-mones,” therefore, the various internal secretions already described.
While the hormones previously described influence the various organs, others affect only one organ or a system of organs. Bayliss and Starling termed “secretin” a hormone formed in the duodenal mucous membrane under the influence of hydrochloric Carried by the circulation to the intestinal mucosa, the pancreas, and the liver, it activates the producacid from the stomach.
tion of the secretions produced by these organs.
1907 (see
vol.
ii,
p.
As I suggested in 861), this hormone presents several proper-
ties of
adrenal extractives. Be this as it may, the question has not been sufficiently developed as yet to warrant any conclusion as to the use of these substances in therapeutics.
Another hormone, however, has been obtained from the mucosa by Zuelzer, Dohni, and ]\Iarxer^““ which has been found to enhance peristalsis. It being impossible to obtain gastric
it
in
sufficient quantities
from the stomach, it was sought after elsewhere, and was found in ample quantities in the spleen that junkshop in which red corpuscles (which, as I suggested in 1903,
—
are the
common
’“"Zuelzer,
carriers of the adrenal principle) are
Dohrn, and Marxer:
Berl.
klin.
Woch., Nu.
4G.
broken up
1908.
HORMONE THERAPY.
790 along with other
cells.
This splenic hormone
lates intestinal peristalsis to a
specifically stimu-
degree so remarkable that the
movements in the experimental animal may readily be shown cinematographically ten to fifteen minutes after an intraintestinal
venous injection.
This hormone (available as hormonal in the trade) has been found of considerable value in chronic constipation, intravenous injections
(20
c.c.
—
—
5
drachms
—in
children and 40
c.c.
— 10
drachms in adults) giving 71 per cent, of recoveries, beginning from the second to the seventh day and lasting from six months to two years (Zuelzer). The injection gives but little local pain thus used, and causes a slight rise of temperature (hormone fever).
In intestinal paralyses following abdominal operations
or volvulus
it
has also given satisfactory results in some cases.
Henle*“’ also obtained favorable results, but they did not seem to be lasting. He found it advisable to enhance the action of the remedy by means of enemas and purgatives to insure elimination of the intestinal contents.
In intestinal occlusion the use of hormones has been recom-
mended, but care is necessary lest the violent peristalsis provoked aggravate any intestinal lesion that may be present. The recent observations of Saar^®’ and UngeH“® suggest, however, that the peristaltic action promoted by the hormone is not violent, even where there
is
obstruction.
50th German Congress of Surgery, April, Medizin. Klinik, Nu. 2. 1910. Unger: Berliner med. Woch., No. 11, 1911.
Henie: Saar:
1911.
INDEX TO VOLUME Abdominal
dilation of, versus
vessels,
contraction
capillaries,
of
Adrenal haemorrhage and acute hyperchild,
exophthalmic
(See
goiter.
Accelerator cardiac phenomena, Achondroplasia, 205. Acne, spermln in, 782.
Acromegaly,
445.
pituitary extract in,
posterior pituitary
symptomatology
in,
514.
512,
515,
608.
treatment of, 618. Addison’s disease, 97. adrenal extract in, pathogenesis of, 99.
99.
ad-
the
Infection,
disorders,
764.
in effusions,
762.
in neuralgia,
disorders,
in shock,
764.
764.
diseases,
in surgical heart in
761.
cardiac disorders, 765.
in surgical
surgical
421.
Adrenal, unilateral removal Adrenalin, 751.
765.
submersion,
60.
(See also Adrenals.)
in respiratory
in
respiration,
pulmonary functions,
755.
765.
754,
453.
467.
764.
in
in haemorrhage,
in sthenic
tions,
brospinal plasma-channels, 573. functional activity and, 233. functions of the thymus gland and,
765.
757.
from haemorrhage,
in neuritis,
pulmonary
65.
respiratory func-
as the foundation of immunity, 620. as source of engorgement of cere-
in collapse, 754.
in collapse
in
to
421.
capillary hsemorrhage,
in cardiac
relation
its
764. 765.
in bacterial in’
oxidizing agent, in
unexplained properties of the, 56. Adrenal system, in cardiac functions,
764.
in ascites, 762. in asphyxia,
14.
causes a rise of temperature, 66. distributed by the red corpuscles as
in,
sure, 13.
in asthma,
17.
11,
globin, 58.
of
(See also Suprarenal.) extract and vascular presdisease,
of
63.
as the oxidizing agent of the haemo-
138.
in Addison’s
constituent
a
action on muscle,
727.
Adrenal
764.
secretion
action on heart,
Adiposis dolorosa, thyroid extract Adrenal.
118.
of,
haemoglobin,
haemorrhagic,
renals,
in children, 120.
Adrenal
pituitary extract in, 770.
Adenoma,
123.
121.
tions of, 764.
spermin in, 782. symptomatology of, treatment of, 103.
the
treatment of, 124. Adrenal hajmorrhagic pseudocyst, 126. Adrenal insufficiency, 80, 115. Adrenal opotherapy, 750. Adrenal preparations, general indica-
771.
body
of,
infant,
symptomatology
516.
of,
616.
of,
in
of,
123.
increased functional activity of the adrenals as a cause of, 25. pathogenesis of, 118. prognosis of, 124.
607.
pathogenesis, 608. pathological anatomy
pathology
in the
in adults,
llyperthyroidia.)
diagnosis
adrenia,
337,
573.
Aberrant
FIEST,
ness, 764.
septicaemia,
764.
in toxaemia, 756, 764.
Adrenal functions, toxins, venoms, and drugs
poisons,
large in doses as Inhibitors of. 19. Adrenal haemorrhage and acute hyperadrenia, 116. diagnosis of. 123. in the adult, 123.
4.
Adrenals, action of drugs on, in the production of lowering of the temperature, 49. in production of muscular weak-
752.
failure,
of,
of
41.
variations of the sure,
blood-pres-
44.
as a cause of adrenal htemorrhage. Increased functional activity of the,
25.
cancer of the, diagnosis,
symptoms,
137.
140.
138.
treatment, 141. diseases of the, 56. ( 791 )
792
INDEX.
Adrenals, function of the, 56. functions suppressed by removal
of,
9.
Assimilation,
governing center of the,
hmmatomata
of,
immunity,
70.
in,
622.
Augmentor cardiac
9.
11,
13,
Axis-cylinders 453.
of
the,
morbid effects of drugs and venoms on the. 39, 54. nervous supply of, 8, 11, 12, 14, 17. splno-adrenal communicating fila415.
relations of, with the vagus.
the
vasomotor
296.
12,-
system,
11,
17.
14,
removal
animals, effects
of, in
of, 5.
man, 5, 6, 7. sarcoma of, 137. toxics which depress the blood-pressure by causing passive conin
gestion
of
the,
in,
764.
Bacterins,
8.
696.
the
nervous
of,
system,
Blood-clots, -platelets
dase,
-pressure,
in.
121.
droplets
338.
adrenoxi-
of
on ad-
drugs
44.
which depress
the, by causing passive congestion of the adrenals, 30. Bone necrosis, thyroid extract in, 711. Brain and cord, minute circulation of,
788.
lower, identity of, 483. neuroglia-fibers as the capillary sysof,
583.
substance in epilepsy, 788. Brain substance in hydrophobia, in
morphine poisoning,
in neurasthenia,
710.
in strychnine in tetanus,
Bright’s
Amblyopia in acromegaly, 515. Amyotrophic lateral sclerosis, 515. Anmsthesla as a symptom of acro-
521,
of,
of
64.
action
tions of the,
toxics
tem 85.
Alcohol, action of, on neurons, 522. Alcoholic insanity, neurons in, 590. Alopecia, thyroid extract in, 734.
ing,
disintegration
as
and nerve substance organotherapy,
64.
prophylaxis and treatment of, 94. Adynamia, general, thyroid extract in,
ApiUhy’s
(See Exophthalmic
incomplete. (See Hgperthgroidia.) Basophile leucocytes, 680. Benign hypothyroldia, chronic. (See Hypothyroidia.) Bilirubin, formation of, 337.
circulation
Adults, adrenal hmmorrhage diagnosis of, 213. functional hypoadrenia in,
megaly,
plasma-channels,
562. of,
482.
retraction of
449,
goiter.)
233.
blood-platelets as droplets in
phenomena.
renals in production of varia-
tumors of, 8. Adrenoxidase and the motor nerves in their relation to muscular contraction,
as
Basedow’s disease.
30.
which produce congestion or venous stasis in the, 23. of,
515.
Bacteria, relations of, to liver. 341. Bacterial infection, adrenal extract
toxics
tuberculosis
765.
543.
131.
with
in,
452.
433,
17,
441.
and respiratory chemism, and the circulation, 18. malignant hypernephroma
ments,
leucocytes
as a symptom of acromegaly, thyroid extract in, 710.
6.
internal secretion of, action on the heart,
neutrophile
654.
Asthma, adrenal extract
126.
hffimorrhage into, in
Ascites, adrenal extract In, 762. Asphyxia, adrenal extract in. 764.
788.
poisoning,
kidney
disease,
Bromides, action
of,
Bronchopneumonia, in.
on neurons. pituitary
plasma-
channels, 540, .544, .568. vermiformis, functions
Appendix
in.
523.
extract
770.
renal insufficiency,
as
extract
Bronzing, a symptom of advanced ad-
578.
neuro-flbrils
788.
788.
784.
514.
neuron-gemmules dur-
788.
788.
515.
Bulimia as a symptom of acromegaly, 512.
of,
in
glycosuria,
363.
325.
Appetite, excessive, as a
acromegaly, In
glycosuria,
512. 363.
symptom
of
Cachexia parathyreoprlva. (See Ilypopnrathyroid tetany.) Cancer of the adrenals, 137.
793
INDEX. Cancer of adrenals, diagnosis
symptoms
of,
140.
adrenal
ex-
138.
of,
thyroid extract
in,
739.
727.
treatment of, 141. Capillary haemorrhage, tract in, 765.
Cardiac disorders, adrenal extract
in,
pituitary extract in, 767. sthenic, adrenal extract in,
adrenal
and
in epilepsy,
788.
in hysteria,
788.
in neurasthenia,
in
insuflaciency,
supply
of, 296.
nervous dual (See also Intes-
tines,
Liver,
Pancreas,
Stomach.) Diphtheria, pituitary extract
788.
spermin
in,
•
212
.
Drugs, morbid effects renals,
120.
in,
extract
hormone
chronic,
ther-
562.
of,
neuroglia-fibers as the capiliary sys-
tem of, 583. Corpus luteum extract
In
menopause,
778.
organotherapy,
etiology,
777.
193. 196.
of
young
in,
710.
extract
in,
children,
thyroid
extract
734.
in,
testicular extract in, 782. Effusions, adrenal extract in, 762.
Endemic cretinism,
196.
Enuresis, thyroid extract in, 733. Eosinophile leucocytes, 667. Epilepsy as manifestations of excess-
motor
ive
activity, 608.
cephalopin in, 788. kidney extract in, 783, 784. opocerebrin in, 788. thyroid extract in, 710, 716. Epinephrin, 751. Erysipelas, pituitary extract in, 770. Exanthemata, thyroid extract in, 711. Excessive activity of the thyroparathyroid disorders apparatus, due to, 212.
Exophthalmic
196.
pathogenesis pathology of,
of,
222
198.
body
In,
514.
sporadic, 197.
etiology
.
of,
223.
larval.
symptomatology
of,
193.
thyroid
in,
710.
extract
goiter, 214.
asthenic or myxeedematous stage
193.
posterior pituitary
treatment of, 198. Cretinoid pachydermia,
197.
(See Hypothyroidia.) pathogenesis of, 216. pituitary extract in, 772. posterior pituitary body in, 514. sthenic or first stage of, 217.
symptomatology Deafness as a symptom of acromegaly, 613.
thyroid
brain, substance in, 788.
764.
apy in, 790. Cord, minute anatomy
Cretinism, endemic,
chronic,
734.
523.
754.
adrenal
on the ad-
515.
Eclampsia, thyroid extract
Eczema,
790.
extract
of,
64.
92.
Cholera, spermin in, 782. Chorea, cephalopin in, 788. pituitary extract in, 773. Chronic benign hypothyroidia. (See Ilypothyroidia.) constipation, hormone therapy in,
from hmmorrhage,
39,
Dyspnoea as a symptom of acromegaly, 513,
prophylaxis and treatment of, Children, adrenal hoemorrhage in, diagnosis of, 123. Chloroform, action of, on neurons,
Constipation,
770.
Disorders due to excessive activity of the thyroparathyroid apparatus,
S3.
in,
in,
782.
212.
174,
tic, -788.
adrenal
and
Diseases of the adrenals, 56. of the thyroparathyroid apparatus,
788.
Cerebral activity, mania and, 572, 590. suhoxidation, melancholia and, 513. Cerebrospinal substance, minute circulation of, 562. system, general center of, 483, 591. Childhood, functional hypoadrenia of,
Collapse,
thyroid ex-
tract in, 734. (See Glycosuria.) Diabetes.
765.
513.
Cephalopin in chorea,
Dermatitis herpetiformis,
Diabetic coma, 363. apparatus, Digestive
757.
Catalepsy
Delusions as a symptom of acromegaly, 612. Dercum’s dfsease, thyroid extract in,
of,
216.
thymus extract
in,
786.
thyroid extract
In,
728.
of,
794
INDEX.
Exophthalmic
transition
goiter,
stage
221.
of.
treatment
Growth, stunted, pituitary extract
228.
of,
Haematoma, adrenal, Febrile infections, thyroid extract
in,
rickets,
tions,
Forme
cardiac
in
func-
421.
fruste de la maladie de Base-
dow. Fractures,
Functional
(See HypothyroUUa.) thyroid extract in, 710.
mechanism
activity,
of old age, 88.
prophylaxis and treatment of, 96. prophylaxis of, 89. treatment of, 89. Functions of the adrenals, 56. of the parathyroids, prevaiiing views
to
the,
formation of, 335, 339. molecule, formation of, in the
prevailing views as
nals,
formation,
its
347,
356,
Giycosuria as a symptom of adrenai insufficiency,
symptom ity,
as
363,
365.
of adrenal overactlv366.
a symptom of excessive formain,
Headache,
pressure
and,
Heart, accelerator phenomena
of,
of,
445.
active inhibition of, due to excessive vagal stimulation, 446. adrenal system In functions of, 11, *421, 433.
augmentor phenomena
of,
449.
foramina Thebesii in the functions 421,
441.
mechanism
functional
of,
452.
512.
of,
phenomena
of,
446,
452.
innervation of. 444. leucocytes and nutrition of, 441. fibers, inhibitor of non-existence nutrition
and the func-
substance
tions of,
433,
441.
“palpitations” of, 512, 515. Heart-failure, pituitary extract in, 768. surgical, adrenal extract in, 764.
Hormone
therapy,
366.
sis,
789.
constipation,
790.
in,
782.
(See Exophthal-
mic goiter.) in,
786.
Golgi’s fibers as plasma-channels, 585. Gout, testicular extract in, 782. (See Exophthalmic Graves’s disease.
paraly-
790.
in volvulus,
Goiter, exophthalmic.
thymus extract
441.
of,
occlusion, 790. in post-operative intestinal
76.
ptyalin and, 418. testicular extract
goiter.)
a source
as
512.
in intestinal
363.
drugs as a cause of, 362. non-convcrtcd sugar and, pituitary
plasma-channels,
568.
in chronic
tion of dextrose, 367.
coma
515.
as
fibers
oxidizing
360.
as a
736.
446.
607.
Glycogen and
in,
138.
sufficiency,
Haller’s
inhibitor
568.
extract
adrenal pseudocyst, 126. Hair, coarseness of, and adrenal In-
hypertrophy
143.
Gastric Juice, formation of. 297, 302. Gerlach’s fibers as plasma-channels,
Gigantism,
thyroid
Haemorrhage, adrenal extract in, 755. Haemorrhagic adenoma of the adre-
of.
143.
liver,
339.
Haemophilia, of
general, 233, 294. the brain versus retraction of the neuron-gemmules, 577, 578. hypoadrenia, 82. in the adult, 85. prophylaxis and treatment of, 91. in childhood, 83. prophylaxis and treatment of, 92. of infancy, 83. prophylaxis and treatment of, 90.
as to the,
distributed by the red corpuscles as oxidizing agent, 65.
335,
of
of the thyroid,
63.
as the oxidizing agent of the, 58. dissociation of, in glycosuria, 365.
205.
Foramina Thebesil
126.
Haemoglobin, adrenal secretion a constituent of,
738.
Fever, genesis of, 628. leucocytes in, 620. Fcetal
In,
773.
790.
Hyaline cells, 652. Hydrophobia, brain substance
in,
788.
Hyperadrenalisra. 115. Hyperadrenia, 115. acute, 116.
Hyperaemla, thyroid.
206.
HypertEsthesia, the posterior pituitary body and, 512.
Hypernephroma,
129.
795
INDEX. Hypernephroma, diagnosis
of.
132,
134.
malignant, of the adrenals, 131. of the kidney, 132. pathology of, 136. prognosis of, 137. treatment of, 137. Hyperthyroidia, 212. (Seo Iti/ftcrlhiiHyperthyroidism. roUlia.)
Hypertrophic rosacea, thyroid extract in,
(See AOOisou's
(See Ilypothyroidia.) Infancy, adrenal haemorrhage in, diagnosis of, 123.
childhood,
of old age,
in,
thyroid
83. 92.
Influenza,
90.
110.
symptomatology,
110.
of, 96.
446,
Insufliciency
(See
513.
in,
in,
pituitary
also
790.
cytogenous
tissue
of,
316,
of,
subepithelial
membrane
321.
functional
mechanism
of,
325.
pituitary
extract
in,
773.
of,
633.
thyroparathyroid apparatus
leucocytosis
In,
Kidney pituitary body as 624.
321.
143,
623.
the seat of the,
of,
minute anatomy of, 307. nervous supply of, 305, 326. phagocytes and their rOle in
the, 312.
prophylactic functions of, 309. secreting glands of, 308, 314. villi and lymph-follicles of, 314.
691. to,
center,
Thymus.)
790.
fenestrated
Cretin-
620.
Immunizing
420.
420.
321.
197.
620,
392,
pituitary extract in, 774. post-operative, hormone therapy
734.
698.
In,
(See Adrenals.) 362,
paresis,
general
relation
711.
700.
in,
adrenals in, 622. adrenal system as the foundation
its
in,
of
of the adrenals.
177.
of,
ism.)
in
19.
(See Thyroid.) Intestinal occlusion, hormone therapy
Myxccdema.)
(See
Ichthyosis, thyroid extract Idiocy and disease of the
leucocyte
stimulation,
the adrenal, 80, 115. Internal secretions and organotherapy,
Intestine,
Immunity,
nervous
452.
of the thyroid.
treatment of. 184. Hypothyroidism. (See II ypotliyroUUa .) Hysteria, cephalopin in, 788.
Imbecility,
770.
767.
of the spleen, 362, 392, of the thymus. (See
183.
myxoedematous,
extract
extract in, 711. pituitary extract in,
of the pancreas,
175.
symptomatology
bodies,
pituitary
770.
thyroid extract
183.
progressive.
201.
diseases,
Insanity, alcoholic, neurons in, 590. the posterior pituitary body in, 512.
tetany.)
of,
204.
poisons, venoms, and drugs in
Hypoparathyroid tetany, 741. symptomatology of, 742. treatment of, 744. Hypoparathyrosis. (See Hypopara-
of,
of,
Inhibitors of adrenal functions, toxins,
112.
Hypothyroldia,
90.
205.
large doses as, of,
of,
Inhibition, active, of heart due to ex-
109.
lliyrokl
Lorain type
cessive
prophylaxis and treatment prophylaxis of, 89. treatment of, 89. pathogenesis
83.
193.
Infundibular extract,
88.
treatment,
myxcedema,
Infantilism,
of, 94.
prophylaxis and treatment of, of infancy and childhood, 83. prophylaxis and treatment of,
etiology
II ypertliyrouUa.)
myxoedema.
Infectious
85.
prophylaxis and treatment
pathology
action of the,
of
Impotence, testicular extract in, 782. (See Incompiete Basedow's disease.
myxoedematous,
82.
in-
628.
Mongolian,
(Iiseti8C.)
terminal,
mechanism, mode
Infantile
in the adult,
of
prophylaxis and treatment
115.
80,
chronic progressive.
in
functions
center,
testine, 309, 322, 325.
functional hypoadrenia in,
735.
Hypoadrenalism, Hypoadrenia, 80.
functional,
Immunizing
extract,
703,
782.
Bright's disease, in chronic nephritis, in
784. 784.
796
INDEX.
Kidney in
extract, in epilepsy. 783, 784. intoxication, 784.
puerperal
functionai mechanism oi, 289, hypernephroma of the, 132.
organotherapy,
293.
Mammary
gland
fibroids,
extract.
in uterine Involution, 786. functional mechanism of, 280,
organotherapy,
782.
ism of, 266, 269. Lacrymation, pilocarpine and, 266. Lactation, mammary giand extract
in,
exophthalmic
(See
goiter.
classiflcation
eosinopbile,
functional
mechanism
immunity, and fever,
of,
776. 710.
Mental diseases, pituitary “xtract
In,
phenomena
of
acromegaly,
512,
514.
Migraine, thyroid extract in, 710. Milk, fluid portion of, as au immunizing serum, 311. Mitral disorders, pituitary extract
In,
768.
520, in,
523.
788.
Motor areas
691.
654.
physiological chemistry of, 647. relation to nutrition, organic func-
and immunity,
of gray substance as sensory areas, 508. nerves, an autonomous system, including vasomotors, 233. and glandular secretion, 262.
and muscular contraction,
233,
247,
of,
233,
261.
633.
Lifer the pituitary bodies as co-centers in sustaining, 483.
vasoconstrictor
function
261.
Liver, blood-pigments of, 334, 360. hepatic artery, functional vessel of,
Muscles
separate
with
supplied
not
vasoconstrictors,
253,
261.
in acromegaly, 514. adrenoxidase and the motor nerves in their relation
Muscular atrophy
326.
hepatic cell a miniature sponge, hepatic cell-canaliculi, 340, 360.
339.
minute anatomy of, 326, .360. pancreas and spleen, combined functions
in, in,
poisoning, brain substance
639.
620.
neutropbile, 653. in assimilation,
tions,
ovarian extract thyroid extract
Mongolian infantilism, 205. Morphine, action on neurons,
650.
of,
667.
in
of,
brain,
functions
483.
of,
Lungs, innervation of, 454. nervo-vascular mechanism of, 454. vagal system in functions of, 421. (See also Renpiration.)
Lupus, thyroid extract Lymph-follicles,
735.
In,
intestinal,
functions
of, 314.
Lymphocytes and hyaline
cells,
652.
Malarial fever, enlargement of spleen and adrenal overactlvlty, 332. Malignant hypernephroma of the. adrenals,
contraction, to,
233.
confusion
in
prevailing views
of.
236.
359.
physico-chemical functions, 326. Lorain type of Infantilism, 204.
131.
neoplasms, thyroid extract in, 711. gland extract in lact tion, 786.
In,
773.
543.
Ldpine’s glycolytic ferment as the oxidizing substance, 4U, 412. Leprosy, thyroid extract in, 735. Leucocyte granulations as secretory products, 644. Leucocytes, basophile, 680.
Mammary
Menopause, corpus luteum extract 778.
Lecithin as the active body of myelin,
Lower
782.
insufflciency, 513.
IlyperthyroUlia.)
534,
in,
Melancholia as a symptom of adrenal testicular extract in, 782.
786.
Larval
289.
785.
Marasmus, spermln
Lacrymal glands, functional mechan-
uterine
In
786.
process
functional
motor nerves and,
of,
261.
233.
source of chemical energy In. 239. hypernutrition and adrenal overactivity,
512.
weakness, action of drugs on adrenals in production of, 41.
and adrenal Insufficiency, Myasthenia, pituitary extract
613. in,
773.
thyroid extract in, 710. hulbo-spinal, ovarian extract in. 773. pituitary extract in, 773. Myelin and the functional energy of nerves, 534, 543. pituitary disorders,
Myocardial
tract
in,
ex-
768.
Myocarditis, chronic, pituitary extract in,
768.
Myopathies, pituitary extract
in,
773.
797
INDEX. Myosinogen, functions fiber.
muscle-
in
of,
261.
and the oxidizing substance, physiological chemistry
Myxoedema, etiology
185. 191.
of,
incomplete. infantile,
(See Ilt/pothyrokUa.)
193.
pathogenesis pathology of,
of,
191.
186,
Neutrophlle leucocytes, in
614.
Myxoedematous
653.
654.
cachectic stage of acro-
in
megaly,
514.
Nutrition, leucocytes in,
idiocy,
633.
197.
Obesity,
testicular
extract in,
782.
201.
diagnosis of, pathogenesis
thyroid extract
in,
724.
710,
204.
Obstetrics, pituitary extract in, 768. 201.
of,
symptomatology, 201. treatment of, 206.
Myxoedeme
assimilation,
Numbness
710.
in,
192.
of,
infantilism,
in,
186.
of,
thyroid extract
fatigue and sleep,
in
of,
522.
191.
symptomatology treatment
581.
579,
varicosity
.
pituitary body
posterior
234.
240.
of,
functional Neuron, lecithin, the ground-substance of, 557. lymph-channels of, 586. physiological chemistry of, 518, 552. physiology of, 519. transmission of vibrations between,
Eypothy-
(See
fruste.
roldia.)
Old age, functional hypoadrenia of, 88. prophylaxis and treatment of, 96. Opocerebrin in epilepsy, 788. Opsonins enhance phagocytosis, how, 696.
Narcolepsy
in
acromegaly,
513.
Nephritin,
784.
Nephritis,
chronic, kidney extract
in,
Optic atrophy in acromegaly. 515. Orchitic organotherapy, 780. Organic functions, leucocyte in its relation
633.
to,
784.
Nerve substance
in
neurasthenia,
of the action
organotherapy, 788. Nerves, myelin as source in.
534,
636,
energy
of
643.
physiological chemistry
of,
532.
Nervous diseases, pituitary extract
in,
773.
energy, source of, system, circulation in the,
533,
adrenoxidase
482.
general center of, 483, 591. Nervous system, including neurons,
composed of plasma-fibrils surrounded by myelin, 560. Neuralgia, adrenal extract in, 765. in acromegaly, 514. Neurasthenia, brain and nerve substance in, 788. cephalopin in, 788. pituitary extract in, 773. testicular extract in, 782. thyroid extract in, 710. Neuritis, adrenal extract in, 765, Neuroglia-cells as links between circulation and neurons, 570, 687. -fibers as plasma-channels, 539, 643. -fibrils of the brain and cord, their capillary supply, 582.
Neuron, circulation
of,
539,
659.
direct continuation of circulation some of its dendrites. 652.
functions of gemmules, histology of, 618.
Organotherapy.
677.
by
of,
700.
internal
secretions and, 700. Osteomalacia, thyroid extract in, 710. Osteomyelitis, thyroid extract in, 710.
Ovarian extract,
703,
775.
in
bulbo-spinal myasthenia,
in
menopause,
643.
536,
of
fundamental principle
preparations, 788.
organotherapy,
773.
776. 775.
Oxidation, thyroparathyroid apparatus in.
143.
Oxidizing substance and the digestive organs, 296. and glandular secretion, 262.
and myosinogen,
261.
as a reagent in all functional processes,
293.
Pachydermia, cretinoid. Pachymeningitis as a acromegaly, 515. Pancreas,
internal
197.
symptom
secretion
of
of,
362,
381,
385,
420.
functional
mechanism
of,
420.
in
the formation of glycogen, 356. the posterior pituitary body and, 513, 514. Paralysis agltans, parathyroid extract Paraesthesia,
in,
747.
testicular extract in, 782. Parathyroid extract in paralysis tans,
747.
agl-
798
INDEX.
Parathyroid organotherapy, 739. tetany. (See limMparathyrokl
Pituitary extract, tet-
the,
the,
the internal
secretion
Parry's
views
Exophthalmic
(See
disease.
696.
Phloridzin and glycosuria, active
as
lecithin,
363.
principle
of
processes,
center,
168.
posterior, as an aggregate of neu596.
as central sensorium,
598.
histology of, 493, 500. as general center of nervous sys-
tem, 483, 511, physiology of, extract.
591.
493,
large
in
doses
as
in,
770.
inhibitors
of adrenal functions, 19. Polydipsia in acromegaly, 515. Polyuria and adrenal insufflciency,
Post-operative
paralysis,
intestinal
hormone therapy
in,
790.
Progressive hypoadrenia, chronic. (See Addison’s disease.) hypothyroidia. yxo’dema .) (See Prurigo, thyroid extract in, 734. Pseudo-Graves's disease. (See Hyper-
U
thyroidia.)
Psoriasis,
testicular
thyroid extract
extract in, 782.
in,
734,
735.
in,
784.
Pulmonary system. Innervation
of, 454.
Rachitis, thymus extract in, 787. Red corpuscles as carriers of oxygen
supply the plasma its oxidizing substance, 247. Removal of the parathyroids only, 146. to
Renal extract, 703. nervo-vascular ism and, 454.
Respiration,
of,
453,
mechan-
454.
pulmonary, adrenal secretion
acromegaly, 771. disease, 770. in Addison's in bronchopneumonia, 770. in bulbo-spinal myasthenia, in cardiac
disorders,
in chorea,
773.
767.
myocarditis, in diphtheria, 770. in erysipelas, 770.
768.
exophthalmic goiter,
772.
in heart-failure,
in imbecility,
773.
in,
60.
Respiratory center, identity of, 454. disorders, adrenal extract in, 761. functions, adrenal secretion and, 453. system, innervation of, 454. Rheumatic pains in acromegaly, 512, 615.
in chronic
768.
diseases,
in Influenza,
770.
in Intestinal
paresis,
mental diseases,
Rheumatism, spermln
in.
chronic, thyroid extract
773.
in infectious
in
Poisons
physiology
591.
704.
in
in
767.
Pneumonia, pituitary extract
624.
body as the seat of thyroparathyroid center,
770.
Puerperal intoxication, kidney extract
593.
483,
phylogeny of, 491. body as the seat of the immunizing
rons,
in typhoid fever, organotherapy, 765.
512.
533.
as active principle of myelin, 543. nervous energy and, 533, 536, 543. posterior pituitary body and, 693. proportion of, in nuclein, 632. Pilocarpine and lacrymation, 266. and sweating. 279. Pituitaro-adrenal nerve, governing center of the adrenals, 70. Pituitary and giycosuria, 76. bodies as co-centers in sustaining vital
770.
in tachycardia, 768.
Pitultrln,
t/oiter.)
Peyer’s patches, function of, 314, 325. Phagocytosis, how opsonins enhance,
Phosphorus
pneumonia,
in shock, 768.
in tuberculosis, 770.
146.
of,
773.
in stunted growth, 773.
149.
functions of the, prevailing as to the, 143.
removal
of
773.
in obstetrics, 768.
in
147.
of
in myopathies, nervous diseases, 773.
in neurasthenia,
uiiu.)
Parathyroids, dual function theory of effects
in
770.
774.
782. 710,
729.
Rickets and adrenal insufflciency,
515.
in,
205.
foetal,
thymus extract in, 787. thyroid extract in, 710. Iligor mortis, nature of, 240, 244. Rosacea, hypertrophic, thyroid
ex-
tract in. 735.
773.
in mitral disorders, 768. In myocardial disorders, 768.
Salivary
glands,
ism
of,
functional
270,
275.
mechan-
INDEX.
799
of the adrenals, 137. Scleroderma, thyroid extract in, 735. Seborrhoea, thyroid extract in, 735.
Surgical heart-failure, adrenal extract
Seusorium commune,
Sweat-glands,
Sarcoma
adrenal extract
surgical,
Septicaemia, in,
598.
Shock, adrenal extract extract
in,
and
768.
in,
Addison’s disease,
in cholera,
in
insufficiency,
pilocarpine,
275.
in organic
of,
functions, 294. Syphilis,
spermin
thyroid extract
in, in,
and
782.
711.
acromegaly,
514.
in syphilis,
782.
adrenal secretion, action
Terminal hypoadrenia,
782.
in typhoid
fever,
pathogenesis
782.
(See also Testicular organotherapy.) Spleen as a leucocytogenic center, 333, in
of,
malarial fevers,
332.
mechanism
functional
of,
385,
389.
internal secretion of, 362, 420. post-prandial enlargement of, and adrenal overactivity, 332. Splenic vein, path for spleno-pancreatic
secretion,
Spleno-pancreatic
367.
internal
secretions,
on
of,
369,
392,
albuminoid
poisons,
404.
Sporadic cretinism, 197. Status hypoparathyreoprlvus. (See Ilypoparathyruid tetany.) parathyreoprivus. (See Hypoparathyroid tetany.)
Sthenic cardihc disorders, adrenal extract in, 765.
Stomach,
functional
mechanism
of,
296.
nervous supply of, 297. physico-chemical functions of, 296. vascular supply of, 300. Strychnine poisoning, brain substance 788.
Stunted growth, pituitary In, 773. Submersion, adrenal extract in, 764. Suprarenal. (See Adrenal.) apoplexy,
6.
hmmorrhage,
110.
of,
702.
782.
in glycosuria, 782. in gout, 782. in impotence, 782.
in melancholia, 782. in neurasthenia, 782.
in obesity, 782. in paralysis agitans, 782. in psoriasis, 782. 782.
organotherapy, 780. (See Spermin.) Tetania parathyreopriva. (See Bypoparathyroid tetany.) Tetanic spasm due to hyperoxidation, 234.
Tetanus, brain substance in, 788. due to adrenal overactivity, 234. thermal phenomena in, 234, 236. Tetany, hypoparathyroid, 741. thyroid extract in, 710.
Thymus
extract in diseases vt the thy-
roid,
in
786.
exophthaimic
in goiter, in rachitis,
in rickets,
goifi^r,
786.
786.
787. 787-
gland, adrenal system and the, 467.
organotherapy, 786. Thyroid, diseases of, in.
thymus extract
786.
dual function theory of the, 147. effects of internal secretion of, 148.
5.
Surgical diseases,
adrenal extract
in,
752.
disorders,
in eczema,
on, 66.
112.
of,
in tabes,
420.
362,
in,
treatment
of,
109.
110.
of,
symptomatology Testicular extract,
335.
enlargement
768.
Temperature, action of drugs on adrenals in the production of lowering of the, 49.
marasmus, 782. rheumatism, 782.
action
adrenal
Tabes, testicular extract in, 782. Tachycardia, pituitary extract in,
782.
782.
in diphtheria,
in
and
702.
in acne, 782. lin
764.
280.
275,
Syringomyelia
578.
577,
in,
mechanism
functional
Sympathetic nerve, role
3.
Skin diseases, thyroid extract in, 734. Sleep and cerebral ischemia, 626. retraction of the neuron-gemmules during,
adrenal extract
515.
764.
removal of adrenals and,
Spermin,
of,
Sweating
764.
pituitary
764.
in,
septicaemia,
thyroid extract
in,
737.
extract in adiposis doiorosa, 727. in alopecia, 734. in asthma, 710.
800
INDEX.
Thyroid extract
bone necrosis,
In
in cancer,
739.
in chronic
rheumatism,
711.
Dercum’s
710,
729.
disease, 727.
in eclampsia,
710.
chronic,
eczema
734.
734.
young
of
children,
734.
in enuresis, 733. in epilepsy, 710, 716.
in exanthemata,
in fractures, in goiter,
problem,
150.
as
710.
728.
404,
in ichthyosis,
711.
735.
malignant neoplasms, In menopause, 710. in
710.
spermin
710.
tract
in seborrhoea,
in,
in syphilis, in surgical in tetany,
Vaccines,
Vaporole,
711.
disorders,
in tuberculosis,
views
209.
symptomatology
of,
207.
treatment of, 209. organotherapy, 708. (See nypcrihuroidla.) Thyroidism. Thyroiditis,
chronic,
in cardiac functions, 421.
767.
pressure,
extract
adrenal
node
of 261.
of action. 255, 274,
294.
tem, 233. Impulses, the posterior pituitary as the source of, 597, 598. Venoms as inhibitors of adrenals, 19. morbid effects of, on the adrenals, 39,
Thyroparathyroid apparatus, diseases 212.
disorders due to deficient activity
54.
functions of, 314. Vital process, the pituitary bodies and, Villi,
174,
696.
Vasodilators,
206.
209.
of the,
gland extract
Vasomotor functions and adrenal sys-
206. of,
786.
mammary
and, 13. Vasoconstrictors as suljdivlslons general motor nerves, 253,
711.
functions of the, prevailing as to the, 143. diagnosis
Vascular
737.
711.
fever,
hypermmia,
711.
786.
Vagal system
734.
710.
in typhoid
in,
735. 735.
diseases,
in skin
in,
involution,
in rickets, 710. in scieroderma,
in,
its formation, 342, 346, 360. Uterine fibroids, mammary gland ex-
735.
734,
8.
Urea and
710.
734.
in psoriasis,
420.
782.
in,
thyroid extract
in osteomalacia, 710.
in prurigo,
369,
770.
in obesity, 710. in osteomyelitis,
404,
392,
pituitary extract in, 770. thyroid extract in, 711. Typhoid fever, pituitary extract
710.
in neurasthenia,
of,
,
Tuberculosis of the adrenals,
711.
in migraine, 710.
myxoedema,
764.
420.
cretion,
735.
in myasthenia,
thyroid extract
711.
.
711.
in insanity, 711. in lupus,
163.
which produce congestion of the adrenais, 23. Toxins, conversion of, into benign products, 369 392 404, 420. in large doses as inhibitors of adrenai functions, 19. Trypsin as the spleno-pancreatic se-
735.
734.
in infectious tonsillitis, in leprosy,
infectious,
cellular
of
Toxics
rosacea,
diseases,
in infectious
activator
phosphorus, 152. as Wright’s opsonin, Tic, cephalopin in, 788.
Toxaemia, adrenal extract In, Toxic albuminoids, reduction
710.
in hypertrophic
body as the seat
168.
secretion
in,
in haemophilia, 736.
in
of,
738.
adynamia,
in general
623.
pituitary
Tonsillitis,
711.
infections,
in febrile
immunity,
center,
herpetiformis,
in
143.
in
In dermatitis in eczema,
apparatus, in genoxidation and immunity,
eral
in cretinism, 710. in
Thyroparathyroid
intestinal
483,
593.
Volvulus, hormone therapy
In.
790.
of the, 174.
disorders due to excessive activity of the, 212.
thyroparathyroid opsonin, secretion as, 163.
Wright's
J
.>
A
I