208 118 27MB
English Pages 474 Year 1998
5
10 9
4
+5
0
-5
3
-10
1
0
1
3
2
4
-15 Bregma 0
5
Figure 1
5
5
+15
+10
1
10
0 Interaural 8
2
+5
0
-5
2
3
7
E/OV aci
6
GrO
4
EPl Mi IPl
Gl
5
5
4
6
ON 3
7
2
8
Interaural 15.70 mm 5
4
3
Bregma 6.70 mm 2
1
0
1
2
3
4
5
5
10 9
4
+5
0
-5
3
-10
0
1
1
3
2
4
-15 Bregma 0
5
Figure 2
5
5
+15
+10
1
10
0 Interaural 8
2
+5
0
-5
2
GrA
vn
3
7 AOB dlo AOE
GrA
6 lo
aci E/OV
GrO Gl
5
4
AOL
EPl 5
Mi IPl
6
4
ON 3
7
2
8
Interaural 15.20 mm 5
4
3
Bregma 6.20 mm 2
1
0
1
2
3
4
5
5
10 9
4
+5
0
-5
3
-10
1
0
1
3
2
4
-15 Bregma 0
5
Figure 3
5
5
+15
+10
1
10
0 Interaural 8
2
+5
0
-5
2
3
7 GlA EPlA
VN
MiA
GrO AOE
6 dlo
AOL
aci E/OV 5
4
GrA
Gl
lo
5
EPl Mi IPl
GrO 6
4
ON 3
7
2
8
Interaural 14.70 mm 5
4
3
Bregma 5.70 mm 2
1
0
1
2
3
4
5
5
10 9
4
+5
0
-5
3
-10
2
0
1
2
3
4
-15 Bregma 0
5
Figure 4
5
5
+15
+10
1
10
0 Interaural 8
1
+5
0
-5
2
FrA
7
LO
MO
6
3
4
AOB
VO rf 5
Mi
aci lo
4
IPl
EPl GrO
E/OV
5
AOD AOE AOM
AOL
6
Gl AOV 3
7
2
8
Interaural 14.20 mm 5
4
3
Bregma 5.20 mm 2
1
0
1
2
3
4
5
5
10 9
4
+5
0
-5
3
-10
1
0
1
3
2
4
-15 Bregma 0
5
Figure 5
5
5
+15
+10
1
10
0 Interaural 8
2
+5
-5
0
2
FrA 3
7 PrL LO
6
4
MO
DLO
VO 5
5 AOD
rf
4
aci
E/OV
AOM
1a 1b
AOV
lo
6
AOL
3
7
2
8
Interaural 13.70 mm 5
4
3
Bregma 4.70 mm 2
1
0
1
2
3
4
5
5
10 9
4
+5
0
3
-5
-10
0
1
1
3
2
4
-15 Bregma 0
5
Figure 6
5
5
+15
+10
1
10
0 Interaural 8
2
+5
0
-5
2
M2
PrL
7
3
MO
6
4
LO DLO VO
5
5 AOD
ri
rf 4
aci
AOL
E/OV
6
AOM AOV
lo 3
7 VTT
8
2
Interaural 13.20 mm 5
4
3
Bregma 4.20 mm 2
1
0
1
2
3
4
5
5
10 9
4
+5
0
-5
3
-10
1
0
1
3
2
4
-15 Bregma 0
5
Figure 7
5
5
+15
+10
1
10
0 Interaural 8
2
+5
M2
-5
0
2 Cg1
M1 3
7 fmi PrL Cl
6
4 LO AI
5
DTr
ri
4
rf
6
1 2
E/O V
3
3
aci
DEn
3
1
AOV
3 2 1
2 Pir
AOM
DTT
lo
5
VO
MO
7
VTT
2
8
Interaural 12.70 mm 5
4
3
Bregma 3.70 mm 2
1
0
1
2
3
4
5
5
10 9
4
+5
-5
0
3
-10
0
1
1
3
2
5
4
-15 Bregma 0
Figure 8
5
5
+15
1
10
0 Interaural 8
2
+5
+10
0
M2
-5
2 Cg1 M1 3
7
PrL
fmi
4
6 Cl AID 5
5
IL VO
LO
AIV
DP
4
6
ri E/OV
rf
1 2
aca 3
3 DTT
DEn
Pir 7
lo
VTT
AOP
Tu
2
8
Interaural 12.20 mm 5
4
3
Bregma 3.20 mm 2
1
0
1
2
3
4
5
5
10 9
4
+5
0
3
-5
-10
1
0
1
3
2
5
4
-15 Bregma 0
Figure 9
5
5
+15
1
10
0 Interaural 8
2
+10
+5
0
M2
-5
2
M1 Cg1
3
7
S1J
PrL
fmi
6
5
4
IL
GI
Cl
E/OV
5 AID
DP 4
LO
VO
AIV 6
DTT AcbSh
rf 3
AcbC 7
aca DEn lo
mfba
SL
ICj
mfba
2
Interaural 11.70 mm 5
4
3
Pir
AOP 8
TuPo TuDC
Bregma 2.70 mm
TuPl 2
1
0
1
2
3
4
5
6
7
10 9
+5
0
-5
5
-10
4
3
2
1
1
0
2
3
5
4
6
-15 Bregma 0
7
Figure 10
5
5
1 M2
10
0 Interaural 8
+15
+10
+5
M1
-5
0
2 Cg1
3
7 fmi
PrL
S1J 4
6
IL
E 5
5 LV
GI
CPu
DP
Cl AID
1 2
4 rcc
AIV
DTT
6
VO
SHi
rf
3
3
DEn
AcbC
7
aca SL
Pir
AcbSh
lo
LSS
2
ICj
mfba
8 VP Tu
1
9
0
10
Interaural 11.20 mm 7
6
5
Bregma 2.20 mm 4
3
2
1
0
1
2
3
4
5
6
7
6
7
10 9
+5
0
-5
5
-10
3
2
1
1
0
+10
1 M1
-5
0
7
M2
10 +5
6
5
4
3
Figure 11
5
5
+15
2
-15 Bregma 0
0 Interaural 8
4
Cg1
2
cg 3
7 Cg2
fmi
S1J 6
4
E IG ec
5
5
CPu
LV
DP
GI
LSI
SHi
AID AcbC
aca
rf
2
DEn
SL
mfba
7
LSS
Pir
VP
lo
6
AIV
AcbSh
3
DI
Cl
exc
4
LAcbSh
mfba ICj
8
VP
VP
Tu
1
9
10
0
Interaural 10.70 mm 7
6
5
Bregma 1.70 mm 4
3
2
1
0
1
2
3
4
5
6
7
6
7
10 9
+5
0
-5
5
-10
4
3
2
1
1
0
2
6
5
4
3
-15 Bregma 0
7
Figure 12
5
5
1 M2
10
0 Interaural 8
+15
+10
+5
M1
-5
0
2 Cg1 S1J
7
3
cg fmi
6
Cg2
IG
E
4 S1JO
gcc 5
IG
LV
ec
LSD
5
CPu GI LSV
4
6
Cl SHi
DI
LSI
VDB
AID AcbC
3
AIV LSS
aca
rf
AcbSh
mfba lo
2
7
DEn
Pir
mfba
VP
8
LAcbSh
mfba ICj
VP
1
9
Tu
10
0
Interaural 10.60 mm 7
6
5
Bregma 1.60 mm 4
3
2
1
0
1
2
3
4
5
6
7
6
7
10 9
+5
0
5
-5
-10
4
3
2
1
1
0
2
6
5
4
3
-15 Bregma 0
7
Figure 13
5
5
1 M2
8
+15
+10
M1
10
0 Interaural +5
0
-5
S1FL
2
Cg1 S1J cg 7
3
Cg2 E
S1JO
IG S1DZ 4
6 gcc S1ULp
LV IG
5
LSD
5
CPu
ec
GI
LSV LSI SHi
4
Cl
6
DI
MS AID AcbC
ICjM
3
rf
aca
VDB
AIV
DEn
AcbSh
7
Pir LSS
2
mfba
mfba
lo
ICj
VP
8
LAcbSh
mfba ICj
2n
1
VP
9 Tu
10
0
Interaural 10.20 mm 7
6
5
Bregma 1.20 mm 4
3
2
1
0
1
2
3
4
5
6
7
6
7
10 9
+5
0
5
-5
-10
4
3
2
1
1
0
2
6
5
4
3
-15 Bregma 0
Figure 14
5
5
7
1
M2 M1
10
0 Interaural 8
+15
+10
+5
0
S1FL
Cg1
-5
2 S1J
cg Cg2 3
7 S1JO
IG
6
E S1DZ
gcc
4
LV S1ULp
LSD 5
SHi
ec
5
CPu
GI
LSV LSI Cl
4
DI
6
MS AID ICjM
3
rf
AcbC
AIV
aca
AcbSh
LSS Pir
VDB 2
7
DEn
8
LAcbSh
lo ICj
mfba
mfba
2n
1
VP
VP
CB
VP 9
ICj
Tu
10
0
Interaural 10.00 mm 7
6
5
Bregma 1.00 mm 4
3
2
1
0
1
2
3
4
5
6
7
6
7
10 9
+5
0
-5
5
-10
4
3
2
1
1
0
2
6
5
4
3
-15 Bregma 0
Figure 15
5
5
7
1
M2 M1
10
0 Interaural 8
+15
+10
+5
0
S1FL
-5
Cg1
2 S1J
cg Cg2
7
3
S1JO IG S1DZ
E gcc
6
4
LV LSD
ec
S1ULp
SHi 5
5 LSI CPu Ld
4
GI
LSV
6
ZL
Cl
MS
DI
ICjM 3 rf
AcbSh
VDB
aca
AID AIV
AcbC
7
DEn LSS Pir
2 lo
HDB
mfbb
mfba
VP
mfba
CB VP
ICj
ICj
1
8
LAcbSh
VP
9
2n Tu
10
0
Interaural 9.70 mm 7
6
5
Bregma 0.70 mm 4
3
2
1
0
1
2
3
4
5
6
7
6
7
10
9
+5
-5
0
5
-10
3
2
1
1
0
M2
0
7
1
M1
10 +5
+10
6
5
4
3
Figure 16
5
5
+15
2
-15 Bregma 0
0 Interaural 8
4
S1FL
-5
Cg1
2 S1DZ S1J
cg Cg2
S1DZ
7
cc
LV
6
3
IG
E
S1ULp
4
LSD SHi LSI
5 ec
CPu
Ld
GI
PLd
ZL
4
5
S2
LSV
DI
BSTMA
MS
AID
BSTL
AcbSh
6
Cl AIV DEn
3
aca rf
IPAC
AcbC
SIB
2 mfba
lo
7
VDB LSS
8 CB
HDB
mfbb
Pir
VP
VP 2n
1
ICj
9
Tu
10
0
Interaural 9.48 mm 7
6
5
Bregma 0.48 mm 4
3
2
1
0
1
2
3
4
5
6
7
6
7
10 9
+5
0
-5
5
-10
3
2
1
1
0
+10
0
7
M1
M2
1
10 +5
6
5
4
3
Figure 17
5
5
+15
2
-15 Bregma 0
0 Interaural 8
4
S1FL
Cg1
-5
2 S1DZ
cg
Cg2
7
3
S1ULp
IG cc
LV
LSD
6
4
SHi
LSI
5
S2
5
Ld CPu
PLd
ec
GI 4
ZL
MS
LSV BSTMA Cl
BSTL 3
6
DI
AIP
7
aca VDB
DEn
rf
IPAC SI
2
VP
LSS
mfbb
mfba
HDB SIB
lo
1
8
Pir
CB
9 ICj
2n
Tu
10
0
Interaural 9.20 mm 7
6
5
Bregma 0.20 mm 4
3
2
1
0
1
2
3
4
5
6
7
6
7
10 9
+5
0
-5
5
-10
3
2
1
1
0
2
6
5
4
3
-15 Bregma 0
7
Figure 18 M1
M2
5
5
1 S1HL
10
0 Interaural 8
4
+15
+5
+10
Cg1
S1FL
-5
0
2 cg
S1DZ
Cg2 IG
7
3
cc
LV
S1BF
df
LSD 4
6 LSI
5
SFi
5
S2 CPu
ec
LSV
ic
f
4 st
DI
BSTMA BSTLJ 3
ac
acp
acp
MnPO
rf
mfba
VP
HDB
lo
1
7
DEn
VEn
8
SIB MCPO
AVPe
AIP
IPACL IPACM
LPO
MPA 3V
mfbb
LSS
Al
Pe mfba
Cl
LGP
BSTMV BSTLP BSTLV StA ADP PS Fu MPOL
2
6
GI
BSTLD
MS
ZL
VP
VMPO
CxA
Pir
9
ICj
ox Tu 10
0
Interaural 8.74 mm 7
6
5
Bregma -0.26 mm 4
3
2
1
0
1
2
3
4
5
6
7
6
7
10 9
+5
0
-5
5
-10
3
4
2
1
1
0
1
+5
0
1
M1
M2
S1HL
3
10
0 Interaural +10
7
Figure 19
5
5
+15
6
5
4
3
-15 Bregma 0
2
8
2
Cg1
4
-5
S1FL 2
5
S1DZ
cg Cg2
6a 6b
7
IG
3 S1BF
cc
LV
df
LSD 4
6 pcf ec
LSI
5
5
SFi S2
CPu ic 4
LSV GI
f
st
BSTMA LGP acp
3
ac
DI
BSTLJ BSTLD BSTLP
MnPO
6
Cl
AIP
7
BSTMV BSTLV
acp rf
ADP
3V StA
2
PS
Fu VP
Pe
DEn
VEn
Pir
8
IPACM
LPO
MPOL
LSS IPACL
SIB mfba mfba 1
MCPO
MPA
AVPe
mfbb
VP
lo
VMPO ox
CxA
HDB
9 ICj
VLPO Tu 10
0
Interaural 8.70 mm 7
6
5
Bregma -0.30 mm 4
3
2
1
0
1
2
3
4
5
6
7
6
7
10
+5
0
-5
5
-10
4
3
2
1
1
0
2
+10
+5
0
1
S1HL
10
0 Interaural 8
Figure 20
M1
5
5
+15
7
-15 Bregma 0 M2
9
6
5
4
3
Cg1
S1FL
-5
2
S1DZ cg
Cg2 IG
7
3 S1BF
cc LV 6
LSD
df
ec
4
LSI SFi 5
S2
5
GI
6
CPu LSV ic
4
st
f
BSTMA
BSTLJ BSTLP BSTLI
CST
LGP
ac
MnPO
DI Cl
3 BSTMV
acp rf
ADP
BSTLV
DEn
IPACM
Pe MPA
VEn
VP MPOL
AVPe mfba 1
mfba
LPO
8
LSS
SIB MCPO
3V
CxA
Pir
HDB
mfbb
7
IPACL
PS
StA
2
AIP
9
VP
lo
VMPO ox
ICj VLPO Tu 10
0
Interaural 8.60 mm 7
6
5
Bregma -0.40 mm 4
3
2
1
0
1
2
3
4
5
6
7
6
7
10 9
+5
0
-5
5
-10
3
2
1
1
0
2
M1
1
M2
+10
S1HL
10 +5
0
7
Figure 21
5
5
+15
6
5
4
3
-15 Bregma 0
0 Interaural 8
4
S1FL Cg1
-5
2
S1DZ cg
Cg2
7
S1BF
IG
3
LSD
cc LV df
4
6
ec
pcf SFi
TS 5
5
S2
ic
st
vhc
4
sm LGP
SFO
CPu
BSTS
3V
GI
BSTMPI
BAC
f
6
BSTMPM
DI
BSTMPL BSTLI
3
B
rf acp
IPACL
PaAM PaAP Pe StHy
PDP mch
2
MPOC
SIB
LPO
mfba
HDB
mfbb
B
IPACM
lo
ox
8
LSS
VP
VEn
MCPO
MPOL VLPO MPOM
7
AIP
DEn
SID
MPA
1
Cl
BSTLP
APF
Pir
9
CxA AAV
Tu
SO
10
0
Interaural 8.20 mm 7
6
5
Bregma -0.80 mm 4
3
2
1
0
1
2
3
4
5
6
7
6
7
10 9
+5
0
-5
5
-10
4
3
2
1
1
0
2
Figure 22 M2
5
5
M1
+10
1 S1HL
Cg1
+15
S1FL
10 +5
0
7
-15 Bregma 0
0 Interaural 8
6
5
4
3
S1DZ
-5 cg
2
Cg2 S1BF IG
7
3
cc LV
LSD
df TS
6
4
ec
SFi vhc IVF
S2
5
5
SFO
D3V st
AV
ic
CPu
PT
sm
4 LGP
PVA
mch B
3
6
GI
f 3V PaAM
rf
BSTMPM
DI
BSTMPI
Pe
PaAP
Cl AIP
BSTMPL
7
SIV IPACL
SID
acp B
Pe
2
StHy
MPOC
SCh
LA
8
LSS
AAD
LPO
MPA MPOL VLH
1
IPACM
SIB
MPOM
mfb
lo
DEn
VP
VEn
Pir
MCPO HDB AAV
SO
ACo LOT
CxA
9
ox
10
0
Bregma -0.92 mm
Interaural 8.08 mm 7
6
5
4
3
2
1
0
1
2
3
4
5
6
7
6
7
10 9
+5
0
-5
5
-10
3
2
1
1
0
0
1
S1HL
Cg1
10 +5
7
M1
M2
+10
6
5
4
3
Figure 23
5
5
+15
2
-15 Bregma 0
0 Interaural 8
4
S1FL
-5
S1DZ
2
Cg2
cg
IG
7 LV
S1BF
3
cc
df
TS vhc
6
4
ec
SFO fi
AVDM
D3V st
5
AD
sm
5
PVA PT PC
4
S2 IAD AVVL AM
ic
AMV
Rt
PVA 3
f
B
MPA
3V
2
SM
PaAP
LH
MPO mfb
SIB
MCPO
VLH
1
IPACL IPACM SID
3
LA
LOT 2
SO
SCh
0
Pir VEn 9
ACo
1
MeAD
ox
8
DEn
BMA
AAV
AIP
AStr
AAD
AHA
Cl
LSS
B SIV
BSTMPL
7
DI
B
Pe
sm
GI
LGP
Re rf
6
CPu
CxA 10
lo
Interaural 7.70 mm 7
6
5
Bregma -1.30 mm 4
3
2
1
0
1
2
3
4
5
6
7
6
7
10 9
+5
0
-5
5
-10
4
3
2
1
1
0
2
7
-15 Bregma 0
Figure 24
5
5
M2
1
M1
S1HL
Cg1
10
0 Interaural 8
6
5
4
3
+15
+10
+5
S1FL
-5
0
2
S1DZ Cg2
cg
IG
7
3
TS
LV 6
4
vhc
fi
SFO
ec
AVDM AD
D3V
sm
st
5
S1BF
cc
df
PVA
5
S2
PT PC AVVL
CM IAD
4 ic
AM
CPu GI
AMV
PVA
6
Rt
DI
LGP
B Re
3 rf
sm
7
3V f
IPACL
2 mfb
AHA
8
LH MCPO AAV
VLH
LA
LOT
SO
3 2
ACo
9
CxA
1
MeAD
ox
lo
Pir
BMA
SCh 0
DEn
IPACM LSS VEn AAD
MPO 1
AStr
SI
BSTMPL
Cir
10
Interaural 7.60 mm 7
6
AIP
B SM
PaAP Pe
Cl
B
VRe
5
Bregma -1.40 mm 4
3
2
1
0
1
2
3
4
5
6
7
6
7
10
+5
0
-5
5
-10
3
4
2
1
1
0
6
5
4
3
7
-15 Bregma 0 M2
9
2
5
5
Figure 25
M1
RSA
1
S1HL S1FL
10
0 Interaural 8
+15
+10
+5
0
S1DZ
-5
2
RSGb
cg
S1BF IG cc
df
7
3
TS
LV
CA3
vhc SFO
S1
DG
6
ec
D3V
sm
st
AD
MD
ic
5
4
AVDM
fi
PVA
PC
Rt VA 4
3
LGP
7 ZI
IPAC
B SI
PaAP
f
DI
B VRe
2
CeC
mfb AHA Pe 1
MCPO SO
MeAD
1
8
BLA DEn
VEn 3
LOT
RCh
I
AA
AHC
3V
Cl
AIP
AStr
CeM
LH
sox
6
GI
AMV
Re
rf
CPu
B
VA
AM
IAM Rh
mt
5
S2
AVVL
PT
BMA
9
ACo CxA
ox
0
10
Interaural 7.40 mm 7
6
5
Bregma -1.60 mm 4
3
2
1
0
1
2
3
4
5
6
7
6
7
10 9
+5
0
-5
5
-10
2
1
1
0
+10
M2
0
7
1
M1 S1HL
RSA
10 +5
6
5
4
3
Figure 26
5
5
+15
2
-15 Bregma 0
0 Interaural 8
3
4
S1FL
-5
2
S1DZ RSGb
cg
IG 7
S1BF
cc df
3
TS
LV
6
fi
LDVL
D3V sm
st
ec 5
PC
MD
eml
PC
S2 AVVL
CM
IAD
5
AVDM
PT
ic 4
AD
MHb PVA
AM
IAM mt
Rt
VA
GI
AMV
Xi
2
VM Sub
VRe
ns
3VPaDC
al
PaMP mfb
f PaV
cst
B
IPAC
B
ZI PaLM
CeM
SI
LH
SPa
LOT
AHC
MeAD
opt
SO sox
AStr
7
Cl
AIP
DEn 8
BLA I
Pe
LaDL
CeL CeC
AHP
1
DI
LGP Re
rf
6
CPu
Rh 3
4
S1
DG
BAOT
VEn 9
BMA ACo
RCh
CxA 10
0
Interaural 7.20 mm 7
6
5
Bregma -1.80 mm 4
3
2
1
0
1
2
3
4
5
6
7
6
7
10 9
+5
0
-5
5
-10
3
4
2
1
1
0
2
-15 Bregma 0
7
Figure 27
5
5
1
M2 RSA
+15
+10
M1
10
0 Interaural 8
6
5
4
3
+5
S1HL S1FL
-5
0
RSGb
cg
2 S1DZ
S1BF
IG 7
cc
df
3 DHC
dhc
LV
CA3
S1 4
6 DG
fi
D3V
sm
st 5
S2 PC
PT iml
CM IAD
4 IAM AMV mt
ic
AM
Re VRe
Xi ns al mfb
VA
PaV
cst
LGP
VM
Cl
PaDC PaLM SI
LH
3V
8
BLA IM
VEn
MeAD
Pir
9
BMA
Pe
opt
DEn
CeM CeL CeC
AHP AHC
1
7
AIP
IPAC LaDL
SPa
SO sox
6
Rt
ZI
PaMP f
GI
CPu
DI Sub
rf
5
AVVL AVDM
Rh
3
2
LDVL
MD
PVA ec
AD
MHb
RCh
BAOT
ACo CxA 10
0
Interaural 7.12 mm 7
6
5
Bregma -1.88 mm 4
3
2
1
0
1
2
3
4
5
6
7
6
7
10 9
+5
0
-5
5
-10
2
1
1
0
+10
0
7
1
M1
M2
S1HL
RSA
10 +5
6
5
4
3
Figure 28
5
5
+15
2
-15 Bregma 0
0 Interaural 8
3
4
S1FL
-5
S1DZ
2
RSGb
cg
IG 7
cc
df
alv
S1BF
3
DHC
dhc CA3 LV
6
S1
fi
ec
MHb sm
st
DG
D3V
5
AD LHb MDL
PVA iml
LDDM LDVL
CL
5
S2
AV
MDM
VL
PC CM
4
eml
CPu VPL
VA
AM
IAM
ic
mt
Rt
DI
rf
LGP
Sub
Re Xi
2
cst
VRe
vaf
PaPo mfb
f
PaMP 3V
1
opt
B
MGP
ZI
al
SI
SPa
Stg AHP
Pe
AHC
7
IPAC AIP
AStr
VM ns
6
GI
Rh 3
4
CeC CeL CeM
LaDL DEn
IMG
8
BLA
LH Acc
MeAD MeAV
IM VEn 9
BMA
VMHA sox
aot
ArcD ArcM ArcL
0
TC
ACo
BAOT
Pir
CxA
SOR
10
ME
Interaural 6.88 mm 7
6
5
Bregma -2.12 mm 4
3
2
1
0
1
2
3
4
5
6
7
6
7
10 9
+5
0
-5
5
-10
2
1
1
0
M2
RSA
+10
0
7
1
M1 S1Tr
10 +5
6
5
4
3
Figure 29
5
5
+15
2
-15 Bregma 0
0 Interaural 8
3
4
-5
2
S1DZ cg
RSGb IG
alv
7
df
cc
dhc
3
S1BF
CA1
CA2
DHC CA3
LV
6 ec
4 MHb
fi
sm
D3V PV
iml 4
LDVL 5
MDC MDL CL
IMD
S2
MDM VPM
VL
PC
CM
eml
LDDM
LHb
st 5
DG
ic
VPL
IAM
rf
mt
Rt
Sub
IPAC
Re
ns
Stg al mfb
f
3V
PaPo LH TC
opt
CeC
CeM
MeAD
VMHDM
1
AStr LaDL I 8
SI
AHP
Pe
CeL
MGP
ZI
A13
DA
AIP
B
Xi
cst
DI 7
VM
VRe 2
GI
CPu LGP
Rh
3
6
BLA BLP VEn
I
MeAV
DEn
IMG
BMA
BLV
9
Pir
VMHC VMHVL
sox
ACo
ArcM ArcD
0
PLCo CxA
BAOT ArcL
10
SOR
MEI MEE
Interaural 6.70 mm 7
6
5
Bregma -2.30 mm 4
3
2
1
0
1
2
3
4
5
6
7
6
7
+5
10 9
0
-5
5
-10
2
1
1
0
+10
7
M1
RSA
1
S1Tr
10 +5
6
5
4
3
Figure 30 M2
5
5
+15
2
-15 Bregma 0
0 Interaural 8
3
4
S1DZ
-5
0
2
RSGb
cg
IG df cc DHC
alv
7
CA1
S1BF
CA2
3
dhc CA3
LV 6
sm
LDDM
D3V
LDVL
LHb
st
ec
4
PoDG MHb DG
fi
PV
5
5
MDC iml
CL Ang
MDL MDM MDPL
IMD 4
6
PC CM
eml
VPL
lab
scp
2
MePD
VRe A13
mfb
f 3V
Pe
TC VMHDM
ArcD ArcL
0
Interaural 6.44 mm 4
3
2
1
BLP VEn
BMA BMP
9
BLV
ACo Pir
PLCo
SOR
Bregma -2.56 mm
MEE 0
8
10
ArcM MEI
LaVL
BLA
I
MePV
AIP
DEn
MeAD
VMHVL
aot
5
LH
VMHC
sox
6
CeM BSTIA
DMD
1
7
MGP
ZI SubI
DA
al
opt
LaVM AStr LaDL CeL CeC
B
ns
7
IPAC
VM
Re
cst
DI
B
SubV mt
GI
LGP
SubD
Rh
rf
CPu
VPM
VL
ic 3
S2 Rt
Po
1
2
3
4
5
6
7
6
7
10 9
+5
0
-5
5
-10
2
1
1
0
+10
6
5
4
3
7
Figure 31
5
5
+15
2
-15 Bregma 0 M1
M2
RSA
1 S1Tr
10
0 Interaural 8
3
4
+5
S1DZ
-5
0
2
RSGb
cg
IG
alv df
7
CA1
cc dhc
S1BF
3
CA2 CA3
6
fi
sm
MHb PV
iml
ec
DG
D3V
st
5
4
PoDG
LV
MDC MDL IMD
4
LDVL
LDDM LHb
Po
Rh 3
lab
rf
6
Re
2 opt
3V
7
VM
mfb sox
CeM
DA
MCLH PeF
MePD
LH
MeAD MePV
BSTIA I
SOR
LEnt
8
DEn BLP
BLV
9
VEn Pir
BMP
ACo
PLCo
VMHVL
0
LaVM
BLA
BMA
PRh
LaDL
LaVL
Pe VMHDM TC VMHC
ArcD
AStr
CeC
SubI
DMD
f
CeL
MGP
ZI
al
1
IPAC
B
VRe A13
ns
Ect
LGP
SubV mt
DI
CPu
VPL
VL SubD
scp
cst
GI
VPM
CM
eml
Rt
MDM PC
ic
5
S2
CL Ang
10
ArcL ArcM
Interaural 6.20 mm 7
6
5
4
3
2
1
MEE
MEI 0
Bregma -2.80 mm 1
2
3
4
5
6
7
6
7
10 9
+5
0
-5
5
-10
3
4
2
1
1
0
2
6
5
4
3
-15 Bregma 0
Figure 32 RSA
5
5
7
M2
M1
1
S1Tr
10
0 Interaural +15
8
+10
+5
S1DZ
-5
0
cg
2
RSGb
alv
IG hf
7
CA1
df cc
S1BF 3
CA2
dhc
CA3 LV
st iml
MDL
MDM
PC
CM
ml
st
Sub
eml
VL
VPL
B
opt
7
f
LaVM
SubI PeF
DMD
BSTIA
LH
MePD
1
MePV VMHDM ArcD
0
ArcL
TC
MTu
BLA
BLV
ArcM VMHVL
9
VEn Pir
PMCo BMA
SOR
DEn
BLP BMP
I
8
LaVL
I
MCLH
VMHC
LEnt
MGP
Pe DMC
LaDL
CeL
ZIV
DA
PRh
CeC
ZID
A11
3V
ns mfb sox
Ect
VM
VRe Do
6
CPu
Re mt
2
AuV
LGP
scp AStr
Rt
Rh
ic rf
Po
CL
VPM
4
3
5
MDC
IMD eml
AuD
LPMR
PVP
4
LDVL
LDDM MHb
ec
5
D3V
sm
fi
S2
PoDG LHbM LHbL
6
PLCo
10
MEI MEE
Interaural 5.86 mm 7
6
5
Bregma -3.14 mm 4
3
2
1
0
1
2
3
4
5
6
7
6
7
10 9
+5
0
-5
5
-10
3
4
2
1
1
0
2
6
5
4
3
7
-15 Bregma 0
Figure 33
5
5
M2
RSA
1
M1 S1Tr
10
0 Interaural 8
+15
+10
+5
0
S1DZ
RSGb
-5
2
cg alv
S1BF
IG df
7
CA1
cc dhc
hf
3
CA2
FC
S2
CA3 DG
6
LV
MHb sm
D3V
AuD
LDVL LPMR
fi 5
4
PoDG LHbM LHbL
CPu
LDDM CL IMD
MDL
iml 4
Rt
MDC
Po
MDM ec
eml
3
ic
ml
scp
st
ZID
sox
CeL
SubI
PH DMD
Pe
LH
CeC
MGP
TC
VMHC
BLA
VMHDM
MePV
Te
ArcD ArcL
Interaural 5.70 mm 7
6
5
4
3
2
1
ArcM
I
0
9
VEn
BMP BLV
Pir
PLCo
VMHVL
10
Bregma -3.30 mm
MEE
MEI
8
BLP
MTu PMCo
0
LaVM LaVL DEn
I
MePD
DMV
DMC
LEnt
BSTIA
MCLH
PeF
f
PRh
LaDL AStr
3V ns mfb
ZIV
A11
mt
1
7
VRe
opt
Ect
CPu
VM
Re
eml
2
6
VPL
PC
CM imvc
OPC
AuV
VPM
LGP
rf
5
Au1
PVP
st
1
2
3
4
5
6
7
6
7
10 9
+5
0
-5
5
-10
2
1
1
0
RSA
7
M2 M1
1 S1Tr
10
0 Interaural +10
6
5
4
3
Figure 34
5
+15
2
-15 Bregma 0
5
8
3
4
+5
-5
0
2
RSGb
cg
S1BF IG
7
df
hf
cc
CA1
dhc
3
alv
S2 CA2 PoDG
6
D3V sm
LV
CA3 DG
LHbM
MHb
4
AuD DLG
LPMR
LDVL VLG
ec
5
fi
fr
Au1
PVP
iml
st
5
LHbL Po
CL MDL
ic 4
eml
ic
IMD
3
Ect
VPPC
7
A11
opt
ZID
VM
scp
AStr
PRh
LaDL
LEnt
ZIV
2
sox
st
mt
ns
PH Pe
LaVM
STh
SubI
LaVL
3V
mfb
1
6
AuV
VPL
OPC
ml
LV
CPu
VPM
PC CM
rf
Rt
MDM
MePD DMD
PeF
BSTIA
BLP
LH AHiAL
f
Pir
BMP
9
VEn
PMCo
DMV ArcD
8 DEn
BLV
Te VMHC VMHVL
PLCo 10
0 ArcM
Interaural 5.40 mm 7
6
5
ArcL
Bregma -3.60 mm
InfS 4
3
2
1
0
1
2
3
4
5
6
7
6
7
10 9
+5
0
5
-5
-10
3
4
2
1
1
0
2
6
5
4
3
7
-15 Bregma 0
Figure 35
5
5
RSA
1
PtA
10
0 Interaural +15
8
+10
+5
0
-5 Mol GrDG alv
RSGb
Py Or Rad LMol
2
cg IG df
hf
7
cc dhc
3
Hil 6
CA2
PoDG
LHbM LHbL sm
S1BF
CA1
AuD
CA3
DG
4
D3V LPMR
LPLR
DLG Au1
5
fi
ec
MHb
PoMn
VPL
MD
ic
opt
ns mfb
MePD
LaDL
STh
PH
DEn
3V
PMV ArcMP ArcLP
0
AHiAL
PSTh
DTM
f
Interaural 5.20 mm 3
2
1
0
BLP
9
BMP Pir
PMCo Te VTM
10
PLCo
InfS
af
4
8
LaVM
LH Gem
1
5
PRh
ZID
LEnt mt
LV
6
TeA
7
ZIV
sox
7
CPu
VPM
Ect
VM
scp
BSTIA
6
SPF
rf
2
AuV
Rt
VPPC
ml
fi
OPC
PF
CM 3
Po
CL PF
st
4
PVP
fr
iml
eml
5
VLG
Bregma -3.80 mm 1
2
3
4
5
6
7
6
7
10 9
+5
0
5
-5
-10
3
4
2
1
1
0
2
-15 Bregma 0
7
Figure 36
5
5
1
RSA
+15
+10
PtA
10
0 Interaural 8
6
5
4
3
+5
0
-5
RSGb
cg
2
IG hf
7
S1BF CA1
df cc
3
IBl
dhc alv
PoDG 6
bsc
hbc
DG
D3V
sm LHbL 5
CA3
LPLR
DLG
APTD VLGPC
4
PVP
fr
VPM
6
VPL
pv Ect
VPPC
ic
ml
rf
7
SPF PR
scp 3V
sox
ZID F
PRh
ZIV CA3
PH
2
ns
Gem mfb
cp
SMT SuM
1
f
PSTh AHiAL
0
ArcMP
4
3
2
1
0
10
PLCo
InfS
Interaural 4.84 mm
APir
VTM
ArcLP
af
9
Pir
BMP
PMCo PMV
DEn
BLP
AHiPM
DG
LEnt 8
LaVM
LH PMD
DTM
LaDL
STh
MRe
5
TeA
SubG
opt
6
5
AuV
Rt
PF
LV
7
Au1
IGL VLGMC
Po
str fi
3
4
AuD
IMA LPMR
MHb
LHbM
ec
CA2
OBl
Bregma -4.16 mm 1
2
3
4
5
6
7
6
7
10 9
+5
0
5
-5
-10
3
4
2
1
1
0
2
6
5
4
3
-15 Bregma 0
Figure 37
5
5
7
RSA
1
V2MM PtA
10
0 Interaural +15
8
+10
+5
0
-5
RSGb
cg
2
S1
IG
7
CA1
cc
df hf
3
IBl
dhc
AuD PoDG DG
hbc bsc
LPLR
D3V
IMA
LPMR
MHb str
fi
CA3
Au1 VLGPC VLGMC
IGL
ec
4
DLG
APTD
5
Po ar fr
rf
PVP
ml
ic
TeA SubG
VPPC SPFPC
RI
3V
Ect
PR
scp
ZIV
pm f
8
LH
SuM
DEn
ML
MMn
BLP
DG
AHiPM
APir PMD
PMCo
VTM
10
ArcMP
Interaural 4.70 mm 6
9
PLCo
af
7
Pir
AHiAL
MM MRe
LEnt
STh
SMT
sumx
cp
CA3
Gem
2
ns mfb
PRh
PH
mtg
LV
7
ZID F
sox
1
6
VPM
pv
opt
AuV
VPL
PF
4
0
5
PrC alv
3
CA2
OBl
6
5
Bregma -4.30 mm 4
3
2
1
0
1
2
3
4
5
6
7
6
7
+5
10 9
0
-5
5
-10
2
1
1
0
+10
7
1
V2ML
RSGb
PtA
cg
-5
0
V2MM
RSA
10 +5
6
5
4
3
Figure 38
5
5
+15
2
-15 Bregma 0
0 Interaural 8
3
4
2
IG cc
df 7
hf
alv
CA1 S1
dhc
3
AuD PoDG bsc
6
DG PiRe
hbc
SCO
str
IMA
Au1
APTD DLG
LPMR
MPT
5
PrC
APTV Sc
PVP
ar
PF
Eth
pv opt 3
IGL
LPLC LPLR
ml scp
rf
SPFPC SubG
fr PH 3V
sox mtg
LV
F
SuM
mfb
ZIV
f
LEnt 8
DEn Gem
pm
1
7
PRh
CA3
SNR LH
BLP
DG
MMn
Pir 9
AHiPM
MM
LM
ML
VTM
APir PMCo
MRe
PLCo
ArcMP
0
10
af
Interaural 4.48 mm 7
6
5
Bregma -4.52 mm 4
3
2
1
0
6
Ect
CA2
ZID
PR
RI
sumx
ns cp
TeA
VPM
fr
ic
AuV
VLGMC VLGPC
Po
ec
2
4
CA2
3V
alv
4
LPMC OPT
pc 5
CA3
1
2
3
4
5
6
7
6
7
10 9
+5
0
5
-5
-10
2
1
1
0
RSA
V2MM
+5
0
7
1
V2ML
10
0 Interaural +10
6
5
4
3
Figure 39
5
+15
2
-15 Bregma 0
5
8
3
4
V2L RSGb
-5
2
cg
alv
PtA
df 7
scc
hf
CA1
3
AuD
dhc PoDG DG
6
bsc
OPT MPT
hbc
5
PLi str
OT
LPMC
APTD
PCom
pc
dlf
APTV
SCom PAG Dk 3V
3
rf
ml
LPLC
MCPC
5
DLG
SG
IGL
MGM
PIL
IMLF
TeA
VLGPC VLGMC
PoT Eth
AuV
CA2
MGD
MGV
ctg
opt
IMA
PLi
SCO
alv
4
4
Au1
PiRe
CA3
LT
Ect
SPFPC
PRh
PR
scp fr mtg
ZID
RI
6
7
CA1
ZIV
8
2
sumx
ns
cp
SuML
mp
mfb
DEn
SNCD
SuMM 1
SNR
PBP
LH
mt
f
BLP
DG
MM ML
LEnt 9
APir
AHiPM
LM
PMCo 0
10
af
Interaural 4.20 mm 7
6
5
Bregma -4.80 mm 4
3
2
1
0
1
2
3
4
5
6
7
6
7
10 9
+5
0
-5
5
-10
2
1
1
0
+10
RSA
0
7
1
V2MM
V2ML
10 +5
6
5
4
3
Figure 40
5
5
+15
2
-15 Bregma 0
0 Interaural 8
3
4
-5
V2L
RSGb
cg
2
alv scc 7
FC
dhc
hf
PtA CA1
3 AuD
PoDG DG
6
4
PiRe
Au1
bsc
PPT MPT
LPMC
OPT
csc
LPLC
5
OT IMA APTD
pc PAG
PLi dlf
alv opt MZMG
4
ctg
PAG
Aq
dtg
APTV
IMLFG Dk
scp
L RV SN
SNRDM
fr SNM VTA mp
CA3 MGV
PoT MGM
REth
PIL SPFPC SNL
PR mtg
2
DpMe
TeA
PP
CA1
6
Ect PRh
LT
7
ZI PBP
RLi vtgx VTRZ PBP IF PN IPF
SNCD
LEnt
8
DEn
MT
cp 1
AuV
CA2
SG
IMLF
MA3 ml
MGD
MCPC
EW 3 rf
5
DLG
PCom
APir
MM
9
AHiPM af
PMCo 10
0
Interaural 3.80 mm 7
6
5
Bregma -5.20 mm 4
3
2
1
0
1
2
3
4
5
6
7
6
7
10
9
+5
0
5
-5
-10
2
1
1
0
2
6
5
4
3
-15 Bregma 0
7
Figure 41
5
5
1
RSA
+15
+10
V2MM
V2ML
10
0 Interaural 8
3
4
+5
0
-5
RSGb
cg
V2L
CA1
scc
7
dhc
2
PtA
FC
3
hf
6
pc opt
SG
APTV DpMe
scp RLi mtg VTRZ
2
VTA aopt 1
mp
cp
fr
PIL
REth
CA2
PRh
CA1
8
SNR
DEn
MT
IPF
7
SNL
SNCD PBP PN
6
Ect LT
PBP
RPC
TeA
PP
SPFPC
vtgx IF
AuV
CA3 MGV MGM
PoT
Dk IMLFG
MA3 ml
MGD
MCPC
dtg
rf
5
PLi
EW 3
DLG
APTD
LPAG
IMLF
Au1
LPMC
OPT
PCom Aq
ctg
MZMG
4
csc DMPAG
OT
PPT
SC
dlf
alv
4
LPLC MPT
IMA
PoDG
DG
SC
bsc
5
AuD
S
PiRe
alv
LEnt DG
MM
9
APir AHiPM
af
PMCo 10
0
Interaural 3.70 mm 7
6
5
Bregma -5.30 mm 4
3
2
1
0
1
2
3
4
5
6
7
6
7
10 9
+5
0
-5
5
-10
3
4
2
1
1
0
2
Figure 42
5
5
+10
1
V2MM V2ML V1M
10
0 Interaural +15
+5
7
-15 Bregma 0
RSA
8
6
5
4
3
V1B
-5
0
cg
2 RSGb
V2L
fmj Post
7
RSGa
hf alv
csc
InWh
DMPAG
DpG
DpWh
dtg MA3
ctg
EW
IMLF
DpMe
PoT
IPDM 3n
1
mp
cp
IF
PBP VTA PN
IPC
3n
SNL
Ect
LT
7
PRh CA1
8
DEn
SNCD
LEnt SNM
IPR fr
PP
PIL
SNR
vtgx hf
6
TeA
CA3
MGM
RMC
RLi
ml 2
MGV
Min ELm
RPC VTRZ
CA2
APT
PaR
scp
AuV
MGD SG
mtg rf
5 PLi
Dk IMLFG
mlf
Au1
LPMC
LPAG
Aq
MZMG
alv
PPT
DLPAG dlf
4
DG
OT
5
4
PoDG
InG
bsc
3
AuD
SuG Op
6
3
PtA
CA1
S
Zo
AHiPM
IPRL
APir
9
PMCo
MM af 10
0
Interaural 3.40 mm* 7
6
5
Bregma -5.60 mm 4
3
2
1
0
1
2
3
4
5
6
7
6
7
+5
10
0
5
-5
-10
3
4
2
1
1
0
2
-15 Bregma 0 5
5
8
+15
+10
V2ML 1
RSA
V1M
10
0 Interaural +5
V1B
-5
0
2
cg
RSGb fmj
V2L
7
3
RSGa Zo
S
Post
hf
PtA
SuG
AuD
Op 6
7
Figure 43 V2MM
9
6
5
4
3
alv
DG
InG csc bsc LPMC
5
CA1
InWh
DMPAG
DLPAG
OT
5
PLi
DpWh
MGD
dlf Aq
Au1
PPT
DpG
alv
4
PoDG
SG
LPAG
CA3 AuV
MGV
4
dtg
ctg
IMLF
EW Dk
IMLFG
APT
PIL PaR
3 scp
hf
2
ml
RLi mtg IPDM
PP
Ect 7
SNL PRh
ELm
CA1
vtgx IF
6 TeA
Min
R
rf
MGM
CA2
PoT
DpMe
MA3
mlf
MZMG
SNR
PBP VTA PN
LEnt
S 3n
4n
1
mp
cp 3n
SNM
IPR IPC
8
DEn
SNCD
AHiPM
IPRL
APir 9
PMCo
af 10
0
Interaural 3.20 mm* 7
6
5
Bregma -5.80 mm 4
3
2
1
0
1
2
3
4
5
6
7
6
7
10 9
+5
0
-5
5
-10
4
3
2
1
1
0
2
-15 Bregma 0
7
Figure 44
5
5
1 V2MM
RSA
+15
+10
V2ML V1M
10
0 Interaural 8
6
5
4
3
+5
V1B
-5
0
2 RSGb
fmj
V2L RSGa
7
3
Zo
Post
S
SuG Op 6
AuD
DG
4
InG csc
InWh
bsc
alv 5
dlf
bic
MZMG
5 MGD
LPAG Su3C Su3
3PC
PP
RLi SNL
PaR
RPC
vtgx
rf
Ect
ml
IPDM
IPDL
IPR 1
cp
IPI
8 DEn
SNCV
VTA
PRh
CA1
DG
SNR
PBP
3n mtg CLi
7
SNCD
RMC
2
6
TeA
PIL
dtgx
scp
AuV
MGV
DpMe
3
mlf
3
CA3
MGM
IMLFG IMLF
ctg
CA2
SG
EW
dtg
hf
Au1
DpWh
DLPAG Aq
4
DT
DpG
DMPAG
PoDG
OT
SNM
AHiPM
LEnt
9
APir
IPL PMCo
IPC
af
10
0
Interaural 2.96 mm* 7
6
5
Bregma -6.04 mm 4
3
2
1
0
1
2
3
4
5
6
7
6
7
10
+5
0
-5
5
-10
3
4
2
1
1
0
2
6
5
4
3
-15 Bregma 0
Figure 45
V2MM V2ML 9
5
5
7
1
RSA V1M
10
0 Interaural 8
+15
+10
+5
0
V1B
-5
RSGb
2
fmj V2L RSGa
Zo Post
7
3
SuG
S
Op InG
AuD 4
6
bsc
DT
5
dlf
csc
DpG
DMPAG
DpWh
InWh
DLPAG
hf
Au1
CA1
5
PoDG
MGD
AuV
DG
Hil
Aq
LPAG
Su3C 4
bic
ctg
ltg
3PC
dtg
EW
SG
IMLF
Su3
mlf 3
mtg rs
RMC vtgx
IPDM ml
RRF MEntV
8
SNCD IPDL
LEnt
IPL
cp
s5
1
PaS
SNR
VTA IPR
7
PrS
CLi
2
PRh
S
RPC
scp
rf
Ect SubB
PaR dtgx
6
MGM
DpMe
IMLFG
3
TeA
MGV
9
IPC tfp
IPI
10
0
bas
Interaural 2.70 mm 7
6
5
Bregma -6.30 mm 4
3
2
1
0
1
2
3
4
5
6
7
6
7
10
+5
0
-5
5
-10
3
4
2
1
1
0
2
-15 Bregma 0 5
5
V2ML
RSA
1
V1M
+15
+10
V1B
10
0 Interaural 8
7
Figure 46 V2MM
9
6
5
4
3
+5
0
RSGb
-5
2
fmj
RSGa
Zo 7
V2L
SuG
3
Post
Op
S
InG InWh
6
4
DpG hf
DG
DMPAG
dlf
bsc bic
CA1
me5
Aq
ltg
LPAG
EW
3PC
ctg
MG
5
TeA
Me5
Su3C
ts 4
DpWh DLPAG
5
BIC Su3
6
DpMe
dtg
3
SubB
Ect PrS
mlf dtgx
3
rf
mtg
A8
scp 2
PPTg
MEnt
8
VTA
B9
LEnt
IPA
cp s5
RRF CLi xscp IPDM
rs
1
7
PRh
S
PaS
ml
m5
IPL 9
bp IPC
IPI Pn 10
0
tfp
Interaural 2.28 mm 7
6
5
Bregma -6.72 mm
bas 4
3
2
1
0
1
2
3
4
5
6
7
6
7
10 9
+5
0
-5
5
-10
2
1
1
0
+10
0
6
5
7
V2ML
V2MM
1
V1M
RSA
10 +5
4
3
Figure 47
5
5
+15
2
-15 Bregma 0
0 Interaural 8
3
4
V1B
-5
2
RSGb fmj
RSGa
Zo 7
3
SuG
Post
Op
V2L
InG InWh
6
DpG
CA1
bsc dlf
GrDG
DpWh
DMPAG DLPAG
hf
5
4
bic
Aq
me5 MG
Su3C
ts
LPAG
BIC 6
Su3 3PC
ctg
ltg
dtg
Ect DpMe
3
mlf
PrS
SubB
PRh
3
mtg rf
xscp
RRF
CLi
IPDM
cp B9
Dsc MEnt
PPTg Rbd VTA
rs
7
PaS
dtgx
A8
2
5
TeA
Me5
EW
4
S
DG
8
LEnt
IPA
tth 1
9
IPL
ml
s5
IPC
m5
IPI
bp
Pn
0
10
tfp
Interaural 2.20 mm 7
6
5
Bregma -6.80 mm
bas 4
3
2
1
0
1
2
3
4
5
6
7
6
7
10 9
+5
0
-5
5
-10
3
4
2
1
1
0
2
7
Figure 48
5
5
V2MM
1
V1M
RSA
+15
6
5
-15 Bregma 0
10
0 Interaural 8
4
3
+10
+5
0
V1B
-5
2
RSGb RSGa
fmj Zo 7
SuG
3
V2L
Op
Post
InG InWh 4
6
DpG bsc
hf
DpWh
DMPAG
dlf
5
5
DLPAG me5
bic
Aq
Su3C ltg
4
Me5
LPAG
DR
3PC dtg
DpMe
Ect
SubB
PaS
mlf A8 CLi
mtg
rf
7
ts Dsc
PPTg
xscp
MEnt
RR IPA B9
cp
8
LEnt
Rbd
ipt
rs
IPL
tth
bp
s5
PRh
RRF
PBG
1
6
PrS
Su3
I3
3
MiTg
2
S BIC
ts ctg
3
TeA
9
ml IPC IPI
m5 0
10
Pn tfp
Interaural 1.96 mm 7
6
5
Bregma -7.04 mm
bas 4
3
2
1
0
1
2
3
4
5
6
7
6
7
10
+5
0
-5
5
-10
3
4
2
1
1
0
2
6
5
4
3
-15 Bregma 0
Figure 49
V2MM 9
7
5
5
1
V1M
8
+15
+10
RSA
10
0 Interaural +5
0
V1B
-5
2
RSGb RSGa
Zo fmj
SuG Op
7
V2L
3
InG InWh 6
Post 4
DpG dlf
DMPAG
TeA
DpWh DLPAG
5
Aq bic
LPAG Me5
me5 ltg
4
DRD
ts ctg
BIC
3
Ect DpMe
SubB
PRh 7
CLi PPTg
xscp ipt
2
Rbd
rs
ll
Dsc
RR PL
MEnt LEnt
8
PnO
MnR RtTg
mcp
s5
6
PaS
PBG MiTg
Pa4
mlf
rf
Su3C
Su3
4
S
InCo
3PC
DRV
dtg
5
PrS
B9 tth
1
9
ml
lfp
Pn
m5 0
10
Pn
bp tfp
Interaural 1.70 mm 7
6
5
Bregma -7.30 mm
bas 4
3
2
1
0
1
2
3
4
5
6
7
6
7
10 9
+5
-5
0
5
-10
3
4
2
1
1
0
2
Figure 50
5
5
1
V2MM RSA
+15
7
-15 Bregma 0
V1M
10
0 Interaural 8
6
5
4
3
+5
+10
0
-5
V1B
RSGb
RSGa
Zo
V2L
SuG
fmj
7
2
3
Op InG InWh
6
Post 4
DpG TeA DMPAG
dlf
DpWh
PrS
DLPAG 5
BIC
LPAG bic
ECIC
me5
6
DRD
ll
DpMe
DRVL
ctg 3
dtg mlf
CLi xscp Rbd
Pa4
SPTg
MEnt ERS
rs PMnR
ll
MnR
8
VLL
RtTg
ml
lfp
9
RtTgP
tth
B9 bp
LEnt
PL
PnO
mcp
m5
7
Dsc
RR
ts
1
PBG
PPTg
ATg
2
PRh MiTg
DRV
rf
s5
Ect
PaS
Me5
VLPAG 4
5
InCo
Aq
10
0
Pn tfp
Interaural 1.36 mm 7
6
5
Bregma -7.64 mm
bas 4
3
2
1
0
1
2
3
4
5
6
7
6
7
10 9
+5
0
-5
5
-10
2
1
1
0
2
6
5
4
3
-15 Bregma 0
7
Figure 51 V2MM
5
5
1
V1M
+15
+10
RSA
10
0 Interaural 8
3
4
+5
0
V1B
-5
RSGb
2 RSGa
Zo V2L
SuG 7
fmj
3
Post
Op InG InWh DpG
6 DMPAG
TeA
PrS
4
ECIC
DpWh 1
DLPAG
2
1
InCo 5
BIC
Aq bic
me5
Me5 PRh
6
DRD DpMe
DRVL
dtg
MiTg PBG
mlf
MEnt
7
PPTg
xscp Rbd
2
Dsc
DRV
3
LEnt
SPTg
ILL PL
ts mcp
5
Ect
VLPAG
ll
4
PaS
LPAG
8
ATg PMnR
rs
VLL
PnO MnR
s5
9
1 m5
RtTg B9
DMPn tth ll
ml
DPPn
lfp
0 bp
Interaural 1.20 mm 7
6
5
RtTgP DLPn
10
LPn
MPn
VMPn
m5
VPPn
Bregma -7.80 mm
tfp bas
4
3
2
1
0
1
2
3
4
5
6
7
6
7
10 9
+5
0
-5
5
-10
2
1
1
0
2
5
4
3
6
7
-15 Bregma 0
Figure 52
5
5
+15
+10
1
+5
0
V1M
V2MM
10
0 Interaural 8
3
4
-5
V1B
RSA
2
RSGa fmj
7
V2L
Zo SuG Op
Post
InG InWh
6
TeA
DpG DpWh
InCo
DLPAG Aq
4
ECIC 2
DMPAG 5
3
PaS
5
Ect
LPAG BIC
me5
bic ll
4
DRVL
6 MiTg
DpMe
DRV
dtg
Dsc
CnF
DRD
4n
rf
Me5
VLPAG
PRh PBG
MEnt
mlf scp
cll
3
xscp
LEnt SPTg
ATg ts
2 mcp
ILL PL
MnR
8
PnO
PMnR
rs
s5 1
VLL
RtTgP m5
VLTg
RtTg
ll
7
PPTg
Rbd
9
tth RPO
ml lfp
0
10
bp tfp
Interaural 1.00 mm 7
6
5
Pn
Bregma -8.00 mm
bas 4
3
2
1
0
1
2
3
4
5
6
7
6
7
10 9
+5
0
-5
5
-10
2
1
1
0
2
6
5
4
3
-15 Bregma 0
7
Figure 53
5
5
+15
+10
1
+5
0
V1M
V2MM
10
0 Interaural 8
3
4
V1B
-5
Pi
2
RSA RSGa
V2L 3
7 TeA Post cic
PaS 4
6 1
ECIC
DMPAG
Ect
2
Dsc
3 DLPAG
5 Aq me5 4
PRh
Me5 VLPAG DRVL
4n
ll
5
LPAG
DRD dtg cll
3
DRV
scp
mlf
MEnt 6
CnF
LEnt
PPTg DLL Rbd
DRI
PL SPTg
VLL
VTg 2
7 ILL
8
mcp ll
PnO
MnR
m5
s5 tz
1
ts
rs
ll
PMnR
9
VLTg
vsc RtTg
ll
RtTgP tth ml
0
VLL ll
Tz
10
RPO
py
Interaural 0.70 mm 7
6
5
Bregma -8.30 mm
bas 4
3
2
1
0
1
2
3
4
5
6
7
6
7
10
+5
0
-5
-10
3
4
5
2
1
1
0
2
-15 Bregma 0
3
6
5
4
Figure 54
V1M V1B
8
7
5
5
2 V2L
10
0 Interaural 7
+15
+10
+5
0
DCIC
-5
RSA TeA
cic 6
3
Ect 4
PaS
DMPAG ECIC
ReIC CIC
PRh
Dsc
3 2 1
LPAG
5
5 MEnt
LEnt
2 me5
ll
4
Sag
Me5
6
VLPAG CnF
4n cll
LDTg dtg
3
scp
DTgP
vsc
mcp
LPBC LPBS
DRC
MPB
DMTg mlf
A7
LPBE VTg
KF
SubCD
PnR
ts
7
LDTgV
DRI
2
DLL
8
P5 s5
PnO
m5
PC5 SubCV
1
Pr5
9
rs MSO
RtTg
vsc
tz
A5
0
tth ml
Tz tz
py -1
10
RPO
SPO
LVPO MVPO
11
bas
Interaural 0.28 mm 7
6
5
Bregma -8.72 mm 4
3
2
1
0
1
2
3
4
5
6
7
6
7
10
+5
0
-5
-10
3
4
5
2
1
1
0
2
3
-15 Bregma 0
+15
+10
2
10
0 Interaural 7
V1B
5
5
+5
0
7
Figure 55 V1M
8
6
5
4
V2L
-5
3
RSA
DCIC cic
6
Ect
DMPAG
4
PaS PRh CIC
ReIC
ECIC 3 21
5
MEnt
5
LPAG 4n
2
MEnt
4
Sag
Me5
me5
ll
4n
6
LPBS
LPBC
LDTg
DRC
dtg 3
Cb
CnF
DLL
7
DTgP
scp
LPBE
vsc
VTg
mcp mlf 2
DRI
DMTg
A7
MPB LDTgV SubCD Su5 DMTg
KF
8 VCA
ts s5
1
PnR
m5
P5 Mo5 PnO
RtTg
PC5 Pr5VL
9
SubCV
rs
DPO
tz
0
A5 ml vsc
SPO
tth Tz
tz
MVPO
py
-1
MSO
10
LSO LVPO
11 bas
Interaural 0.20 mm 7
6
5
Bregma -8.80 mm 4
3
2
1
0
1
2
3
4
5
6
7
6
7
10
+5
0
-5
-10
3
4
5
2
1
1
0
2
3
Figure 56 2
1
+15
+10
+5
0
V2L
2
10 -5
3
cic
7
V1B
Cb
5
5
0 Interaural 7
6
-15 Bregma 0 V1M
8
5
4
DCIC
RSA 3 Ect
PaS ReIC
PRh
ECIC
6 CIC
3
3
2
4
MEnt
1
5
5 4
2 4
LPBV
4n 4V
SMV
Sag
LPBI
LPBD
LC vsc 3
me5 DTgP
RL
Me5
DTgC
MPBE
Su5
KF
SubCA 2
mlf
PnR
ts
DMTg
SubCD P5
Mo5DL
m5
s5
7
LPBE
MPB DRC
2&3 LPBCr
LPBC
LDTg Bar
scp
mcp
6
8
VCA I5
Mo5VM
Pr5VL
RtTg
1
9
SubCV
PnC
A5
DPO rs 0
tth
6n
tz
RMg
PnV SPO
ml
Tz
tz vsc
LVPO
MVPO
py
-1
10
LSO MSO
11
bas
Interaural -0.16 mm 7
6
5
Bregma -9.16 mm 4
3
2
1
0
1
2
3
4
5
6
7
6
7
10 8
+5
0
-5
-10
2
1
+10
2
3
5
4
6
7
Figure 57
5
5
+15
1
0
-15 Bregma 0
2
V1M
Cb
V1B
10
0 Interaural 7
3
4
5
+5
0
V2L
RSA
-5 DCIC
3
PaS Ect PRh
MEnt
ReIC
6
CIC
4
ECIC
3
3 21
5
5
Sim 4 2
4 LPBV
4n 2&3
4V
scp
CGB
MPBE scpd
Su5
2
DTgP
Pr5DM
SubCA
8 Mo5DL P5 Mo5VM
SubCD
ts
PnR
RIP
VCA
I5
9
SubCV
PnC
A5
DPO
rs
RMg PnV
tth
SPO
ml
vsc
tz
Tz
10
LSO MSO
py -1
LVPO
11
MVPO
bas
Interaural -0.30 mm 7
6
5
PFl
Pr5VL
RtTg
m5
0
7
Me5 MPB
CGA mlf DMTg
s5
6 LPBD LPBC LPBE LPBCr
SMV LDTg LC Bar
DTgC
me5
mcp
1
PCTg
vsc
3
LR4V chp
DRC
LPBI
Bregma -9.30 mm 4
3
2
1
0
1
2
3
4
5
6
7
6
7
10 8
+5
0
-5
-10
2
1
1
0
2
3
6
5
4
-15 Bregma 0
7
Figure 58 5
5
5
2
Cx
10
0 Interaural 7
3
4
5
+15
+10
+5
0
4
-5
3 DCIC
6
4
CIC 3 Sim
prf
Crus1
ECIC 5
5
PCTg 3
4&5
2 4
6
plf
4V
O mlf
scpd P5
m5 s5 1
CGA II
Su5 I5
SubCD
VCA
Acs5 pd
SubCV
PnC
Jx5
9
Pr5VL
RIP
8vn
7n A5
tz
0
tz py
-1
10
LSO SPO Tz
ml vsc
DPO
PnV RMg tth
rs
MSO MVPO
bas
LVPO
11
Interaural -0.68 mm 7
6
5
8
SGl
Mo5
ts
ocb
Fl
Me5 SubCA
DMTg
7
MPB
PDTg
CGB 2
PCGS CGPn Bar
Sph
me5
PFl
LPBE
1 SMV
scp
LR4V
LPBV LPBC
LC
vsc
mcp
3
LPBC LPBV
Pr 5D M
LPBE
Bregma -9.68 mm 4
3
2
1
0
1
2
3
4
5
6
7
6
7
10 8
+5
0
-5
-10
3
4
5
2
1
1
0
2
3
6
5
4
-15 Bregma 0
Figure 59
5
5
7
5
2 Cx
10
0 Interaural 7
+15
+10
+5
-5
0
3
4 DCIC
4
6 ECIC
3
prf
psf
Sim
Crus1 5
5
2
4
6 LPBV
PBW plf
vsc 1
4V
mcp
3
scp
LC
SMV Sph Bar PDTg
LR4V me5 CGB 2
sp5
ts
ocb 8vn
0
tz vsc
PnC
SubCV
9 Pr5VL
Acs6 DPO 10
PnV SPO
LSO
Tz MSO
py
-1
VCA
Acs5 pd
RMg tth ml RPa
tz
8
Mo5
A5
rs
Pr5DM
SubCD DMTg
RIP 7n
Fl
MPB
Me5
II
mlf
m5
LVPO
11
MVPO
bas
Interaural -0.80 mm 7
6
5
7
PCGS
SubCA
O
CGA
P5
1
PFl
Bregma -9.80 mm 4
3
2
1
0
1
2
3
4
5
6
7
6
7
10 8
+5
0
-5
-10
2
1
+10
2
3
2
SimA
-5
0
7
5
10 +5
6
5
4
Figure 60
5
5
+15
1
0
-15 Bregma 0
0 Interaural 7
3
4
5
SimB
4
3
pcuf
prf
4
6 Sim
psf 3
Crus1
5
5
pfs 4
6
2 mcp
plf
icp
unc
LPBV
3 LR4V
me5 prb
8vn
plf
veme
CGG
LC
SMV
4V
PDTg
PFl
MPB
1
vsc scp
CGA
Bar
Me5
MVeMC
CGB
Pr5DM
2 6
mlf ocb
7
SuVe Fl PCGS
SGl 8 VCA
P5
Pa6 PCRtA
1
sp5
8cn
ts
7n
IS
IRt
pd
I8
9
Pr5VL
PnC rs
0
Acs6
A5
RMg
tz tz
vsc
tth ml
RPa
py
-1
10
PnV
MSO SPO
LSO
Tz LVPO
bas
11
MVPO
Interaural -1.04 mm 7
6
5
Bregma -10.04 mm 4
3
2
1
0
1
2
3
4
5
6
7
6
7
10
+5
0
-5
-10
3
4
5
2
1
1
0
-15 Bregma 0
2
3
6
7
Figure 61
prf 8
6
5
4
simf
5
5
2 5
10
0 Interaural 7
+15
+10
+5
0
-5
3 4
Sim
pcuf 6
4
Crus1
psf
5
3 5
pfs 4
6 2 unc
PFl
scp
plf 3
plf
DC
4V
prb
MVeMC
VCA
8
PCRtA DMSp5
6
Sp5O
Pa6
8cn
PnC
ts
9
IRt
Acs7
rs
7
RMg tth ml
vsc
8Gn
Pr5VL
SuS P7 A5
Gi tz
I8
IS
pd
0
LVe
EVe
7n
sp5 1
mlf
Fl
MVePC
SGe CGPn
ocb
g7
2
SGl
SuVe
SMV
8vn
7
LC
1 icp
LR4V
GiA
LPGi
RPa
10
7 CPO
py
-1
11
bas
Interaural -1.30 mm 7
6
5
Bregma -10.30 mm 4
3
2
1
0
1
2
3
4
5
6
7
6
7
10
+5
0
-5
-10
3
4
5
2
1
1
0
-15 Bregma 0
2
3
6
5
4
Figure 62
6 simf
8
+15
+10
+5
0
2
5
10
0 Interaural 7
prf
5
5
7
-5
3 Sim 4 psf
6
4
pcuf Crus1
5
3
5
2
pfs
4
Lat
6
unc
PFl
scp
1
3
A4
SuVe
7
LC plf
SMV
icp
LR4V
MVePC
4V
8vn
MVeMC
mlf
6
prb
IS
pd
1
6n
9
SuS
P7 RMg GiA tth ml
vsc
PCRtA DMSp5
Acs7
Gi
tz rs
8
Sp5O
IRt
ts
GrC
VCP
Pa6
sp5
0
VCA
SGe
g7
2
Fl
DC
LVe
LPGi
7
A5
10
PPy
RPa
py -1
11
bas
Interaural -1.52 mm 7
6
5
Bregma -10.52 mm 4
3
2
1
0
1
2
3
4
5
6
7
6
7
10
+5
0
-5
-10
3
4
5
2
1
1
0
-15 Bregma 0
2
3
6
5
4
7
Figure 63
6 prf
8
5
5
2
simf Sim
10
0 Interaural 7
+15
+10
+5
0
5
-5
3 psf
4 4
6 pcuf Crus1
5
5 pfs
2&3 Lat
4
6
IntA scp
jx 1
LR4V
VeCb
SuVe
A4
3 icp SMV
LVe
Pr
8vn
g7
mlf CI
lvs
8n
7
PFl
MVePC 4V
2
Y
DC
MVeMC
8
6
GrC
Sol VCP
sp5
IS
DPGi
PCRtA
IRt
pd
1
Acs7
ts
SuS
Gi P7
rs 0
RMg
tz ml
vsc
GiA
RPa
LPGi
DMSp5 9
Sp5O
A5 10
7
PPy
py
-1
11 bas
Interaural -1.80 mm 7
6
5
Bregma -10.80 mm 4
3
2
1
0
1
2
3
4
5
6
7
6
7
10
+5
0
-5
-10
3
4
5
2
1
1
0
-15 Bregma 0
2
3
6
5
4
6
7
Figure 64
prf 8
5
5
10
0 Interaural 7
+15
+10
2
+5
0
5 Sim
-5
3 psf 4 4
6 Crus1 pcuf
5
5 pfs
2&3 IntA
4 Lat
scp Y
1
LR4V
3
VeCb
MVePC
SMV Pr
icp
DMSp5D DMSp5V
IRt Acs7
pd ts
PCRtA
9
Sp5O
Gi
tz rs
0
8
VCP
IS
DPGi
1
7
GrC
SolRL
sp5
PFl
DC
SpVe X
MVeMC
CI mlf
g7
8n
LR4V
LVe
4V 2
Inf
Y
A4
das
icp
SuVe
6
Lat
RMg
vsc
GiA
LPGi
7
10 P7
A5
ml PPy
RPa
py
-1
11
bas
Interaural -2.00 mm 7
6
5
Bregma -11.00 mm 4
3
2
1
0
1
2
3
4
5
6
7
6
7
10
+5
0
-5
-10
3
4
5
2
1
1
0
2
3
5
4
6
-15 Bregma 0
Figure 65
6 8
7
5
5
2 prf
7
+15
+10
psf
10
0 Interaural +5
0
-5
3
Sim 4&5 Crus1
6
4
5
5 IntDL
pcuf
IntDM
4
IntA
IntA
Lat
2&3 VeCb LR4V
jx
A4
4V
das
SMV
SolIM
SolRL
asc7
VCP
CI pd
DMSp5D PCRtA
DPGi IRt Acs7
ts Gi ROb
rs 7
RMg vsc
GiA
-1
IS
7DM
P7 7DL 7DI
LPGi
7VI
GrC 9
Sp5O
10
7L
7VM
PPy
ml
C1
8
mlf
1
0
X
MVeMC
Pr
sol sp5
PFl
MVePC SpVe
4V 8n
7
DC
LVe 1
icp 2
LatPC
Y
D M Sp 5V
3
6
Inf
RVL
py
11
RPa bas
Interaural -2.30 mm 7
6
5
Bregma -11.30 mm 4
3
2
1
0
1
2
3
4
5
6
7
6
7
10 8
+5
0
-5
-10
3
4
5
2
1
1
0
2
3
4
5
6
-15 Bregma 0
Figure 66
5
5
7
simf
2
6
psf
10
0 Interaural 7
+15
+10
+5
0
Sim
-5
3
prf Crus1
6
4&5
4
icf 5
5 MedDL Crus2 IntDM
IntA
2&3 IntP
4 IntPPC
6
Lat
Med IntPPC
3
LatPC 7
DC 1
LR4V
ECu
2
SpVe
MVePC
icp 8n SolRL sp5
sol
4V
SolIM SolM
C3 B4 mlf
SolVL
1
PFl
X 8
MVeMC Pr CI
IS IRt
DPGi
pd
DMSp5D PCRt DMSp5V
ts
9 Sp5O
Amb Gi ROb
0
P7
rs RMg
PPy
ml
C1
vsc
-1
5
RVL 11
bas
Interaural -2.60 mm 6
7
RPa
py
7
LPGi
GiA
10
7
4
3
2
1
0
Bregma -11.60 mm 1
2
3
4
5
6
7
6
7
10 8
+5
0
-5
-10
3
4
5
2
1
1
0
2
3
5
4
6
-15 Bregma 0
7
Figure 67
5
5
2 6
10
0 Interaural 7
+15
+10
+5
0
prf
-5
3
Crus1
6
4
5
5 icf Med 4
Crus2 IntP
plf
6 Cop
PFl
10 3
7 MVePC
4V
icp
SolIM SolM
2
sol sp5 SolVL
Pr C3 B4 mlf EF CI pd
1
C eM MV
DPGi
ROb
ECu X 8
PFl
PCRt
IRt
ts
9
Sp5I Amb
Gi
rs
0
SpVe
DM Sp 5D DM Sp 5V
LR4V
Bo
10n
10 ml
C1
IOD GiV
MRVL
vsc
RVL LPGi 11
-1 py
RPa
IOM
IOPr
Interaural -2.80 mm 7
6
5
Bregma -11.80 mm 4
3
2
1
0
1
2
3
4
5
6
7
6
7
10 8
+5
0
-5
-10
3
4
5
2
1
1
0
2
3
5
4
6
-15 Bregma 0
7
Figure 68
5
5
2 6
10
0 Interaural 7
+15
+10
+5
0
prf
-5
3
6
4
Crus1
icf
5
5 Crus2 plf
4
6 Cop
10
PFl
3
7 LR4V
icp C3
sol 2 sp5
C eM MV SolM
Pr
B4 mlf
SolVL
SpVe
MVePC
4V
EF CI
ECu X 8 DMSp5
SolIM
DPGi PCRt
pd
Sp5I
IRt
1
9
Gi
ts
Amb ROb
0 rs
10
Bo RVL
C1
ml
vsc
IOD
GiV LPGi
MRVL
-1
py
11
IOPr
RPa
IOM
Interaural -2.96 mm 7
6
5
Bregma -11.96 mm 4
3
2
1
0
1
2
3
4
5
6
7
6
7
10 8
+5
0
-5
4
5
-10
3
2
1
1
0
2
3
4
5
6
-15 Bregma 0
7
Figure 69
5
5
2 6
10
0 Interaural 7
+15
+10
+5
0
-5
3 Crus1
7
4
6 icf 8 Crus2
5
5
9
4
6 PM
plf Cop
10
3
7
LR4V icp
X FVe
SolM
sp5
2
SpVe
MVe
4V sol SolIM
Pr
C3 C2
IRt
1
8
DMSp5
B4 mlf EF CI DPGi
SolVL
ECu
PCRt Li
Sp5I
9
pd ts rs
0
Amb
Gi
PrBo
GiV
C1
ml
ROb
vsc -1 py
IOM
RPa
10
RVL
IOD
LPGi 11
IOPr
Interaural -3.30 mm 7
6
5
Bregma -12.30 mm 4
3
2
1
0
1
2
3
4
5
6
7
6
7
10 8
+5
0
-5
-10
2
1
1
0
2
3
4
5
6
-15 Bregma 0
7
Figure 70
5
5
+15
+10
2
10
0 Interaural 7
3
4
5
+5
0
6
-5
3 Crus1 7
icf
6
4 ppf
Crus2
8
5
5
sf 9
4
6
plf PM 10
pms
3
Cop 7 ECu
SolIM sol
2
Pa5
FVe
MVe
icp
Cu
4V
SolM
In
SolVL
C3 12 B4 Ro mlf CI DPGi
sp5
C2
X 8
E5
DMSp5
10 PCRt
Sp5I
IRt
1
9
PMn ts Gi rs
dsc/oc
0
Li
Amb
RVRG ml
ROb
C1 vsc
10
RVL GiV IOD
LPGi
IOM
-1
IODM py
RPa
11
IOPr
Interaural -3.72 mm 7
6
5
Bregma -12.72 mm 4
3
2
1
0
1
2
3
4
5
6
7
6
7
10 8
+5
0
-5
-10
2
1
1
0
2
3
4
5
6
-15 Bregma 0
7
Figure 71
5
5
+15
+10
2
10
0 Interaural 7
3
4
5
+5
0
6
-5
3
pms Crus1 icf
7
6
4
ppf Crus2 8
5
5
sf 9
4
6
plf Cop
PM
pms 10
3
7 ECu
icp sol
Pa5
SolM
MVe
4V
SolIM
2
Cu X
C2 In C3 12 10 Ro mlf DPGi
sp5
SolVL
PCRt
IRt
1
Pa5
5 Sp DM
8
E5
Sp5I
9
PMn rs 0
RVRG C1/A1
dsc/oc
GiV
Gi
ts
12n
Amb
10
RVL/CVL
ml
ROb
IODM
LPGi
vsc IOD -1
11
RPa IOM
py
IOPr
Interaural -3.80 mm 7
6
5
Bregma -12.80 mm 4
3
2
1
0
1
2
3
4
5
6
7
6
7
10 8
+5
0
-5
-10
2
1
1
0
2
3
4
5
6
-15 Bregma 0
7
Figure 72
5
5
+15
+10
2
10
0 Interaural 7
3
4
5
+5
0
-5
3 pms 7
6
4
ppf Crus2 8
5
5 sf apmf
9
PM
uf
4
plf
pms 3
10 cu
chp sol SolIM SolI
sp5
7
ECu
SolDM
SolG
icp 2
6
Cop
9
Z PSol
C2 SolM 4V
Pa5 8
10
SolCe
Cu
SolVL
12 Sp5I mlf ROb
1
Ro
PCRt PMn
RVRG
9
IRt
ts
Gi
Amb
12n
rs 0 dsc/oc
ml IOVL
C1/A1 vsc
IOD
IOPr
py
-1
RPa IOB
IOC
10
LRtS5
IOBe RVL/CVL LRt
LRtPC 11
IOA
Interaural -4.24 mm 7
6
5
Bregma -13.24 mm 4
3
2
1
0
1
2
3
4
5
6
7
6
7
10 8
+5
0
-5
-10
2
1
1
0
2
3
4
5
6
-15 Bregma 0
7
Figure 73
5
5
+15
+10
2
10
0 Interaural 7
3
4
5
+5
0
-5
3
pms 7
6
ppf
4
Crus2
8 5
5 sf apmf 9
PM
4
6 pms
3 cu
SolIM sol
ECu
4V
SolCe 10
SolI
7
10
SolG SolDM
sp5
2
Cop
plf
C2 SolM
8 SolVL
12 ROb
1
mlf
rs
LRtS5
ml
IOPr
10
IOBe
IOVL
vsc -1
Amb
RVL/CVL
ts 12n
9
IRt
PMn Gi
C1/A1
Sp5I
PCRt
Ro
RVRG
dsc/oc
0
Pa5
PSol Cu
IOC RPa IOB
py
IOD
LRt LRtPC 11
IOA
Interaural -4.30 mm 7
6
5
Bregma -13.30 mm 4
3
2
1
0
1
2
3
4
5
6
7
6
7
10 8
+5
0
-5
-10
2
1
1
0
2
3
4
5
6
-15 Bregma 0
7
Figure 74
5
5
+15
+10
2
10
0 Interaural 7
3
4
5
+5
0
-5
3
7
pms
ppf
6
4
8 Crus2 5
5
sf 9
apmf
PM
Cop
4
6
9 pms 3
7 10
ECu
SolDM
cu
Gr
SolIM
Cu
AP
2
sol SolI SolCe
sp5
A2
PSol
SolC
SolM CC
12
1
rs
dsc/oc
0
ROb ts
LRtS5
C1/A1
12n
vsc
-1
MdD
InM
9
IRt
PMn
Amb
Sp5I
MdV
IOK
10
RVL/CVL
ml
py
8
Sp5C
SolVL
Ro
mlf RVRG
10
IO Be
RPa
IOC
IOD IOA
LRt LRtPC
IOB
11
Interaural -4.68 mm 7
6
5
Bregma -13.68 mm 4
3
2
1
0
1
2
3
4
5
6
7
6
7
10 8
+5
0
-5
-10
2
1
1
0
2
3
4
5
6
-15 Bregma 0
7
Figure 75
5
5
+15
+10
2
10
0 Interaural 7
3
4
5
+5
0
-5
3
7 6
4
ppf 8 pf
pms Crus2
8 sf
5
5
apmf PM 4
6
9 Cop
pms 3
7
ECu
cu AP
sp5
2
Gr SolDM
gr
SolI
A2
sol
Cu 8
SolC 10
ia
SolVL
SolIM CC SolM 12
1
Sp5C MdD
IRt
Ge5
Ro
0
rs LRtS5
dsc
ROb mlf
A1
12n ml
IOK
ts
MdV IOBe
py
-1
Amb
9
10
RVL/CVL
IOD IOC IOB IOA
RPa vsc
PMn
Sp 5I
RVRG CVRG
LRt LRtPC 11
Interaural -4.80 mm 7
6
5
Bregma -13.80 mm 4
3
2
1
0
1
2
3
4
5
6
7
6
7
10 8
+5
0
-5
-10
2
1
1
0
2
3
4
5
6
-15 Bregma 0
7
Figure 76
5
5
+15
+10
2
10
0 Interaural 7
3
4
5
+5
0
-5
3
4
6
ppf
8 sf
5
5
9 4
6
PM pms
Cop 9
3
7
cu gr 2
sp5
Gr SolM
AP
Cu
SolDM
8
SolI
SolC A2 10 CC
sol
SolVL
Sp5C
SolIM 12
1
MdD
9
ia PMn rs
0
dsc
CVRG A1
12n
RAmb
mlf
ROb
ts
MdV
IOK
CVL
10
LRt IOBe RPa IOC IOA IOB py
vsc -1
LRtPC
11
Interaural -5.08 mm 7
6
5
Bregma -14.08 mm 4
3
2
1
0
1
2
3
4
5
6
7
6
7
10 8
+5
0
-5
-10
2
1
1
0
2
3
4
5
6
-15 Bregma 0
7
Figure 77
5
5
+15
+10
2
10
0 Interaural 7
3
4
5
+5
0
-5
3
4
6
8 5
5
sf
9 4
6 Cop
3
PM
7
9 Obex cu
Gr
2
8
10 Sol
sol A2
sp5
Cu
SolC
gr
CC Sp5C
MdD 12
1
9 IRt
CVRG 0
rs
mlf
A1 12n
dsc
ROb
MdV
LRtPC
pyx -1
10 LRt
ml vsc
CVL RAmb
ts
RPa
IOM
11
Interaural -5.30 mm 7
6
5
Bregma -14.30 mm 4
3
2
1
0
1
2
3
4
5
6
7
6
7
10 8
+5
0
-5
-10
3
2
1
1
0
2
3
4
5
6
-15 Bregma 0
7
Figure 78
5
5
+15
+10
2
10
0 Interaural 7
4
5
+5
0
-5
3
6
4
5
5
9
4
6
3
7
9
cu
2
gr
sol
sp5
Gr
MnA SolC A2
Sol
10 1
8
Cu
MdD
Sp5C 9
12 CC
0
mlf
CVRG
rs
A1
IRt MdV
ts
sc
IOM
RAmb
10
CVL pyx
LRt LRtPC
11
-1
Interaural -5.60 mm 7
6
5
Bregma -14.60 mm 4
3
2
1
0
1
2
3
4
5
6
7
5
4
3
2
1
0
-1
-2
-3
-4
-5
-6
-7
-8
-9
-10
-11
-12
-13
-14
-15
Bregma Bregma
10
9
Cg1
Cg1
RSA
1
RSGb
df
7
PrL
DG
PiRe
vhc
6
D3V gcc
SHi
TS
SFO
5
f DP
PVA PT
MS
4
MD
IAM Rh Ld
3
ac
CM
2 9 6
3PC 3
sumx IPF SuM
RLi vtgx
CLi
IF
MRe ME
IRe
1
10
Sph PDTg mlf
MnR
CI
RtTg
IPit
APit
-1
Lateral -0.10 mm 13
12
11
9
8
7
6
5
4
3
2
1
0
9
pyx 10
IO IO RPa
pyx bas
11
Figure 79
Interaural 10
Gr CC
GiV
GiA RMg
tz
tfp
8
ROb
Gi PnV
ml
py
14
12 mlf ts
Pn
gr
SolC
pd
RtTg
IPF PPit
InfS ArcMP
Obex AP
mlf
PnR
IPR
7
9
4V
IPC MM
Interaural
CGA
plf
4x
DTgP
Rbd
IPA
SMV
DTgC PMnR
xscp
sox 0
DR
4 mlf
dtgx
3V
5
Su3
MMn ox
sf
PAG
SubD SubV
VOLT
4
Aq
MA3
Pe
ppf
pcuf
ReIC
DMPAG
PVP IMD
PH
Pe
1
csc pc
PoMn
MnPO 2
3
8
Re
VDB
3
7
cic
SC
SCO PVP
IG
DCIC
hbc
MHb PV
IL
psf
Zo SuG
Mol
df
6c
4
dhc
cc
2
prf
scc
IG Cg2
6b
Pi
Cg1 bv
6a
5
RSGb 8
0
-1
-2
-3
-4
-5
-6
5
4
3
2
1
0
-1
-2
-3
-4
-5
-6
-7
-8
-9
-10
-11
-12
-13
-14
-15
Bregma Bregma
10
0
RSA 9
1
M2 RSGb
5
Pi 8
RSGa
Cg1 FrA
scc Cg2
7
IG
cc
PrL
df
6
rf
IG
PoDG DG
vhc
SFO 3V
LSD SFi
IL
MO
5
gcc
CA3
MHb LHb
sm
PVA
TS
MDM
PT 4
EPl
DP
GrO
PF
PVA
LSI
DTr
MS
AM
f
DTT AOP SL VTT
Ld
ICjM
APF ADP
AcbSh
0
AHA
MPA MPO
1
SPF
RI
AHP
DMD DMC
LA
VMPO
SCh ox
PH
PMD
VMH
SuM mt MM
fr mp
Interaural
uf 4V
Pr
SolC 10
In DPGi Ro
Gr Sol
12
lfp Pn
Pn
PMn
PnV
ml
GiV
GiA
tz
IO
RMg
APit
10
IO
pyx
py
-1
Lateral 0.40 mm 14
13
12
11
Figure 80
Interaural 11
10
9
8
7
6
5
4
3
2
8
9
Gi
PnC
RtTg tfp
7
RtTgP
ml
IPF
9
10
MVe
PN IP
6
plf
4x
1 mlfDTgP CLi Sph DTgC PMnR PDTg xscp VTg SGe CGA ATg DMTg g7 6 PMnR Pa6
dtgx scp
PPit IPit
3V
Arc
9
4V SMV
4
ML
sox RCh
5
2
DRVL LDTg
PBP VTA vtgx
mtg
Aq
Su3
mlf
IMLF
4
8
Med
3
VTRZ
DA
MPOC StHy
VDB Tu
Sub
PaAP PaLM PaAM PaPo VRe
ICj
2
Re
ac
3 sf
3PC
Dk
Rh
AOM
3
MA3
CM
ppf
cic
PAG PAG
3
7
pcuf
DCIC
pc
PVP PrC
psf
DpWh
csc DMPAG
MPT
prf
4
DpG sm
2
6c
Op InG InWh
CA1
6b
Zo
SuG
dhc
6a
1
0
-1
-2
-3
-4
-5
-6
5
4
3
2
1
0
-1
-2
-3
-4
-5
-6
-7
-8
-9
-10
-11
-12
-13
-14
-15
Bregma Bregma
10
RSA
M1
9
V2MM
M2 8
rf
V1M M2
scc
FrA
CA3
OB VO
5
Ld
LSV
DP
4
LSV ICjM BSTMA
AOP
ac
VP VTT mfba VP Tu
Al
BSTMPM BSTMP
StHy
HDB mfbb
ICj
1
MPA
PaPo
PF
ts scp
Interaural
Med
Pa4
LDTg
xscp
mlf
1 CGPn
4V
MVePC MVeMC
SMT LH SuM f
3n
mp IPF
cp
10
9
8
7
9
Gi ml
lfp tfp
TM PMV
6
5
8
IRt
6n PnV
Pn
APit
LPGi
Tz
GiA
4
3
2
1
0
10
MdV GiV IO
IO
py
11
Figure 81
Interaural 11
Cu cu
SolG sol
PnC
RtTg
Lateral 0.90 mm 12
7
DPGi
-1
13
MVe
10
asc7
ml
LM
VMH
DMTg
9 10 SolM
tz
14
plf
4V
SPTg vtgx PnO RtTgP
6
9
SMV/4x
g7
PMD
4
3
sf
dtg
RRF
R
RI
DM TC sox
ECIC
VLPAG me5
VTA
LA ox
ppf
CIC
mt
AHC
7
pcuf
2
SPF
VM ZI
3
5
IMLFG
AHP
AHA
SO
mcer 0
VM
psf
LPAG
MCPC
SubV
Rt
4
8
PC
PS
SI
2
PF fr
SubD VPPC
CST BAC f
AcbSh
prf
cic
DLPAG
pc
PF
AM
E/OV
6
PrC PCom
IAD
PLd
DTT 3
MDL MD
DCIC
DpWh
PPT OPT
LHbL sm PT
TS
AOM
AOV
pcf SFi
LSI
IL
bsc
3V
LSD
gcc
S
DG
2
6
6
SuG Op InG InWh DpG
hf
vhc
PrL
lo
CA1
CA2
Cg2
5
RSGa Zo
dhc cc
AOB
6
1
RSGb
IG
Cg1 7
0
-1
-2
-3
-4
-5
-6
5
4
3
2
1
0
-1
-2
-3
-4
-5
-6
-7
-8
-9
-10
-11
-12
-13
-14
-15
Bregma Bregma
10
V2MM
RSA
PtA
0
9
1
V1M
M1 fmj RSGb M2
8
scc
rf FrA
alv
cg
cc
Cg1
AOB
CA1
CA2
7
GrA
MiA
LO
lo
LSD
VO E
LSV
Pir aci E/OV AOV
AVVL
DEn BSTM
BSTL 3
AcbC
AOP
PS
mfba 2
VP
AcbSh
SI
1
Tu
HDB mfbb
ICj
scp
PeF
Interaural
MTu
4x
SNCD LH MT PMV
SOR
RRF
scp LC
PnO
SubCD
tfp
3n
Pn lfp Pn
PnC
Tz
8
7
6
5
4
3
2
9
10
Gi
MdV
7
SPO
LPGi C1
LRt IOD
11
Figure 82
Interaural 9
cu
P7 ll
Lateral 1.40 mm 10
Cu
IRt
tz
11
8
ECu
MdD
-1
12
cu sol SolIM SolVL PCRt
MVPO
13
7
10
VLTg
APit
14
plf
SolM
asc7
cp
LM VTM
4V
sf 9
MVeMC
7n
SNR
6
IntP
MVePC SubCA
rs
SNCD
Med VeCb
SpVe
PPTg
ml VTA
scp SPTg me5
PaR R
LH sox
Cop IntA
Me5
F
SubI
mfb
ox
5
2
me5
4n
Eth PR
ZI
LPO VLH VLPO
4
ppf
LPB VPPC
VM
sm
SO 0
VL
DpMe
SPFPC
SM
CB
3
Me5
ctg
Rt
BSTLV
VP
PF
PC
VA
acp
aca
7
InCo
CL
AM
st
psf
MedDL iml
LSV
3
ECIC pcuf
DpG
APTD OPT
Sim
ECIC CIC
PPT
6
prf 4
AVDM
CPu
AOD
OT LPMR
AD LDDM
3V
LSI
5
AOE
DG
vhc
fmi
bsc
PoDG
6
DCIC
SuG Op InG InWh
S
hf
CA3
4
Zo
RSGa
PrL LV
6
dhc
2
5
1
0
-1
-2
-3
-4
-5
-6
5
4
3
2
1
0
-1
-2
-3
-4
-5
-6
-7
-8
-9
-10
-11
-12
-13
-14
-15
Bregma Bregma
10
V2MM
PtA
9
0
V1M 1
S1Tr S1HL fmj
M1
8
rf
M2
LO fmi
lo AOD
5
fi
lo
DEn
Po
ic
AOP
Eth Sc
Rt
VPM VM
IPAC acp
AcbC
LPO SM
VP
AcbSh VP CB mfba Tu ICj
al
HDB mfbb
ml PBP
SubI
mfb MCLH LH VLH
SIB
F
PPTg
al
SNR
rs
mfb cp
MTu SO opt sox SOR
lfp
a 3n
Interaural
VLTg
tfp APit
ll
Mo5
VLL
Pn
Lateral 1.90 mm 14
13
12
SolVL
Sp5C MdD 9
7
LSO
CVL
Amb RVL C1 LPGi
P7
10
LRt 11
Figure 83
Interaural 11
10
9
8
7
6
5
4
3
2
1
8
DMSp5
PCRt
IRt
tz
-1
sp5 Ge5
7n
RPO MVPO
X
SolIM
DPO
A5
7
ECu Cu
SpVe
PCRtA
SubCV
Cop
LR4V
SuVe Me5 me5 MVeMC ocb
PnO A7 P5
6
IntP
LVe DC as
scp
Su5
SubCD ERS
IntA
LPB
MPB
5
ppf
2 vsc
PaR RRF
SNCD STh
4n
MiTg
SPFPC
ZI
sm
2
PM
3
CnF
DpMe
BSTL
aca
Pir
1
APTV
VL
4
apmf
pcuf ECIC
BSTMPM
ic
3
0
DpG InCo
VA
AcbC
Crus2
4
PCTg
st
Pir
AOV
Crus1 icf
CIC
InWh
3
psf
Sim
prf
DCIC
AVVL Ang CPu
aci
OT PPT APTD OPT
BSTS
C1
AOL
LPMR
LD
AVDM
VO
bsc
DG
6
5
Zo SuG Op InG
Hil
LV
6
4
S
CA3
AOB
Post
hf
CA2
cc
7
6
RSGa
cg alv
FrA
2
RSA
CA1
0
-1
-2
-3
-4
-5
-6
5
4
3
2
1
0
-1
-2
-3
-4
-5
-6
-7
-8
-9
-10
-11
-12
-13
-14
-15
Bregma Bregma
10
9
PtA
S1Tr
0
1
V2ML V1M
S1HL
alv
8
cc
M2
FrA 7
CA1
fi
rf
LDVL
LP
BSTS AOL
5
VO
LGP Pir
3
aca
LSS
acp
mfba/VP
1
Tu
ICj
sox opt AA LOT
APTV
ic
RR
SNCD
AHiPM
LVe
7
Cop
8
A5 RPO
Sp5I
DMSp5
PCRtA
Sp5C
m5
mcp
Interaural
LR4V ECu icp SpVe sp5
PC5 Mo5 ll
BAOT
ppf
DC
8n
DG
Me
SuVe MVeMC
VLL
LV
6
IntP
LPBEscp
PL ll
cp
SNR
PM
LPB PPTg MPB
RRF
5
IntA
2 vsc
ll
MiTg
REth
STh
SI
HDB mfb
apmf
3
PCTg DLL
ZIV
MGP
IPAC
VP
icf pcuf
DpMe
ZID B
LAcbSh VP
ml
eml
4
Crus2
4 InCo
SPFPC
Crus1
prf
CIC InWh
SubB
ic B
AcbC 2
VPM
VPL Rt
psf
InG
Po
VL
lo DEn
5
PPT
Cl
4
0
OT
Sim
ECIC 321
ECIC
CPu
Pir
3
RSA
SuG Op
APTD
str
Po
st
Post
DG bsc
fmi
LO
S Zo
CA3
LV
RSGa
hf
CA2
6
2
fmj
M1
rs
7n
A5
LSO tz
9
PCRt
P7 7
RVL
10
LRt LRtPC
-1
11
Lateral 2.40 mm 14
13
12
Figure 84
Interaural 11
10
9
8
7
6
5
4
3
2
1
0
-1
-2
-3
-4
-5
-6
5
4
3
2
1
0
-1
-2
-3
-4
-5
-6
-7
-8
-9
-10
-11
-12
-13
-14
-15
Bregma Bregma
10
PtA
9
V2ML
1
S1Tr
V1M
S1FL
8
alv
M1
hf S bsc
fmi
6
fi BSTS
AID rf
AIV
LO 5
LDVL
Cl 4
Po VPL
B
ZIV
DEn LAcbSh
2
MGP
B
STh
opt MCPO
bv
1
mfba/VP ICj
3 AA LOT
Tu
Interaural
Crus2
icf
5
MeAD
ltg
MePD
SubB
SNL
Sag
PBG
pcuf
4n RL
MiTg
ILL
SNCD
vsc
PCGS
Pr5DM
8vn icp ocb X
m5
DG
MePV
LR4V Cop
8
Pa5
9
s5
Sp5I
Sp5O
MeAV
7
ppf
sp5
Pr5VL
mcp
PMCo
LatPC
DC
ll
LV AHiPM
PM
Lat Y
VLL
cp
6
IntA 2&3
DLL
SNR
sox
AL
SI
VP
prf
4
BIC
PIL
ZID
B ic
acp
MGM
ml
LGP Pir
str
SG
VPM
ec 3
5 ECIC
Po
Rt CPu
4
Crus1
bsc Op
eml
VO
Sim
Zo LPMC OT
3
psf
RSA
DG
LPLR
st
lo
Post
Hil
CA3
LV
2
fmj
CA2
cc
M2
0
V1B CA1
7
0
tz
7n
Sp5C
LRtPC
tz
10
sp5
rs
-1
11
Lateral 2.90 mm 14
13
12
Figure 85
Interaural 11
10
9
8
7
6
5
4
3
2
1
0
-1
-2
-3
-4
-5
-6
5
4
3
2
1
0
-1
-2
-3
-4
-5
-6
-7
-8
-9
-10
-11
-12
-13
-14
-15
Bregma Bregma
10
9
S1Tr
V2ML
V2L
PtA
1
V1M
S1DZ S1FL
8
alv CA1 fmj
CA2
cc
7
hf
M2 LV
CA3 LP
fi
AI
Hil PoDG
LDVL
DLG
st VPM
Cl
rf
CPu
4
5
ec
B
DEn
MGP
2
LSS
Pir
acp IPAC
SI
CeM cst
1
AA CxA
Tu Interaural
BMA
LV Me MePD I
AHiPM
BM
Lat LatPC
cp opt
6
SNL
mcp
sox
lo
Crus2
PP
ZIV
VCA
8n VCP
LR4V icp
s5
S
7
PM
DC
CA3 CA1
5
icf
2&3
SubB
ZID
Crus1
pcuf
4n
4
Sim prf
4
bic
MGV
eml
ic
B
bic BIC
VPL
LGP
PaS
MGD
eml
VO
3
str
psf
MEnt
PaS
LPMC
5
0
Post
DG
bsc
3
RSA
S
fmi
LO
2
V1B
M1
6
0
8
Cop
E5 9
Sp5O sp5
PMCo
ACo
tz
Sp5I 10
lo
-1
11
Lateral 3.40 mm 14
13
12
Figure 86
Interaural 11
10
9
8
7
6
5
4
3
2
1
0
-1
-2
-3
-4
-5
-6
5
4
3
2
1
0
-1
-2
-3
-4
-5
-6
-7
-8
-9
-10
-11
-12
-13
-14
-15
Bregma Bregma
10
1
9
PtA
V2L V1B
S1BF
8
2
S1FL alv
7
cc
M1
Or Rad
Py
S1J
LMol Mol GrDG
CA2 CA3
6
fi
5
psf
Rt
4
ic
CPu Cl LGP
LO rf
eml/VPL
B 2
acp
VEn LSS
Pir lo
1
CeC I
I
AA
BMA
BL
PaS
I
mcp
Fl
Cop LR4V
7
PM
DC
LEnt CA1
Crus2 6
Fl
CA2
st BSTIA
icf
4&5
DG
CA3
LV
CeL CeM
IPAC
MEnt
sox opt
cst
5
prf
LT
ic
DEn
Sim
PrS
DG
VLGMC
SubG
ec
Dsc
MGV
B
4
Crus1
Hil bsc
AI
S
VLGPC
str
3
fmj hf
DLG
ec
3
V2L
CA1
LP
st
0
0
VCA
S
AHi
tz
BMP
8
VCP 8n
9
PMCo PLCo
Interaural
10
ACo CxA
-1
11
Lateral 3.90 mm 14
13
12
Figure 87
Interaural 11
10
9
8
7
6
5
4
3
2
1
0
-1
-2
-3
-4
-5
-6
5
4
3
2
1
0
-1
-2
-3
-4
-5
-6
-7
-8
-9
-10
-11
-12
-13
-14
-15
Bregma Bregma
10
9
0
1
PtA V2L 8
V1B
S1BF
2
alv 7
V2L
S1J
M1
CA2 cc
LV
6
fi CA3
ec CPu
rf
3
B
CA3
st DEn
2
LSS Pir
1
0
I
6
DG
Crus2 MEnt
PFl
DG
7
PoDG
LV CA2
8
S
CA1
BLA
BLP
LEnt
BMP
VEn
lo
Ce
AStr acp
5
4&5 MG
PrS
opt
Crus2
prf
Dsc
SubG
LGP
VO
icf
PoDG
VLGPC
4
ec
4
Crus1
VLGMC
Rt
ic
PRh
hf
DLG
AI
Cl
fmj S
st 5
3
psf
CA1
9
AHiAL
BMA
Interaural
CxA
PLCo
PMCo 10
-1
11
Lateral 4.20 mm 14
13
12
Figure 88
Interaural 11
10
9
8
7
6
5
4
3
2
1
0
-1
-2
-3
-4
-5
-6
5
4
3
2
1
0
-1
-2
-3
-4
-5
-6
-7
-8
-9
-10
-11
-12
-13
-14
-15
Bregma Bregma
10
0
9
1
8
2
V2L
S1BF
3
7
S1ULp
alv Crus1
CA1
S1J
6
cc
M1
S 5
fi ec
CA3 Dsc
DI
MEnt
B
st
Cl AIV 2
acp BLA LaVM
CA1
BLP
8
LEnt
APir
BMP
Pir
7
S
CA2
VEn
1
0
CA3
LaVM
DEn
PrS
LV
LaDL
rf
6
PFl
DG
LGP AID
5
pfs
opt
CPu
3
Crus2
Sim
ic
4
4
psf
LV
GI
Crus1
CA2
9
PMCo
BLV
lo
Interaural
10
PLCo
11
-1
Lateral 4.60 mm 14
13
12
Figure 89
Interaural 11
10
9
8
7
6
5
4
3
2
1
0
-1
-2
-3
-4
-5
-6
5
10
+5
4
3
-5
0
-10
2
-1
-2
-3
-4
-5
-6
-7
-8
-9
-10
-11
-12
-13
-14
-15
Bregma -9.60 mm
5
5
0
0
-15 Bregma 0
7
6
1
Interaural +15 +10
10 +5
0
7
6
-5
APir 5
5
Pir BLV PLCo
CxA
4
4
PMCo
BM
oc/dsc
ACo 3
LOT
VLL
0
7
A5
VTM LH MTu PMV TC TM VMH DM Arc 3V
MSO RPO DPO
APit Pn
PPit
1
Gi ROb PMn
PnV
tfp
1
GiA
0
pd 1
lfp
Te 3n
SOR 2
bp
m5 3
2
MdV
ml
Me
CVL
P7
PnC
RtTg
IPit
sox
Tu
RVL
Amb
Tz
SOR
TC RCh
3
LRtS5
LVPO
BAOT 2
1
Sp5C
8n
MePV
Me
ll RPO VLL
SubCV rs
s5
MePV
IRt P7
Amb
2
PCRt 7n
Sp5O
tz
Sp5I
sp5
3
ACo PMCo
CxA
4
4
PLCo af
Pir
5
5
APir 6
6
7
7
Interaural 0.40 mm 14
13
12
11
Figure 90 10
9
8
7
6
5
4
3
2
1
0
-1
-2
-3
-4
-5
-6
5
10
+5
4
3
-5
0
-10
2
-1
-2
-3
-4
-5
-6
-7
-8
-9
-10
-11
-12
-13
-14
-15
Bregma -9.22 mm
5
5
0
0
-15 Bregma 0
7
6
1
Interaural +15 +10
10 +5
0
7
6
-5
APir
Pir
5
5
VEn
BLV
BMP 4
4
BMA
CxA
PMCo
AHiAL
ACo
3
LOT Tu
2
MeAV
VP
ICj
HDB
7n AHiPM
MePV
VLL
AAV MTu
SO
TM
Te
SCh
TC Pe
0
VMH
LM
PnO
PMD
DM
P7
PCRt
Acs7
PnC
Pn
MMn
RIP
2
PMn
12 mlf
pd
pd
1
MdV
Gi ROb
tfp
MdD
IRt
RtTg
MM
3V
3
7n
Acs6/7 PMV
ox
SubCV
VLTg
LH
1
Sp5I
Sp5O
Ge5 Sp5C
0
ml
ML 1
1
lfp sox
2
TM
opt AAV
ll
m5
4n
A5
bp
BAOT MeAV MePV
LOT
3
Acs6/7
3n
5Gn
Acs7 7n PCRtA
rs m5
Pr5
s5
sp5 tz
ACo
2
3
oc
dsc
PMCo 4
PLCo
lo
4
BLV af
VEn
5
5
6
6
7
7
Interaural 0.78 mm 14
13
12
11
Figure 91 10
9
8
7
6
5
4
3
2
1
0
-1
-2
-3
-4
-5
-6
5
10
+5
4
3
-5
0
-10
2
-1
-2
-3
-4
-5
-6
-7
-8
-9
-10
-11
-12
-13
-14
-15
Bregma -9.10 mm
5
5
0
0
-15 Bregma 0
7
6
1
Interaural +15 +10
10 +5
0
7
6
-5
Pir
5
BLP
VEn BLV 4
CxA AAV
3
ACo
2
4
oc/dsc
AHi tz DG
Me
MePV PMCo VLL
VP
ICj
HDB
1
DM
LA MPO
Pe
PCRt
SubCV LH
ox
Sp5O
Pr5VL
m5
TC
VMH
LM
PMV
3
Ge5 Sp5C
Sp5I
Pn
SO
SO LPO
0
BMP BL
BMA
LOT Tu
5
APir
2
MdD
Acs7 IRt
TM RtTg PnO
ML PMD DTM MMn MM 3V
PnC
Gi
Pn
2n
1
ROb
MdV 12 CC
mlf
pd
0
ml
1
lfp VLTg
3n
opt sox
2
1
tfp
f
m5
4n
mfb
ll bp
s5
A5 rs m5
7n PCRtA
2
Pr5VL sp5
3
ACo 4
3
tz
PMCo
ocb
BMA
lo
VEn BLV 5
4
APir
5
af
6
6
7
7
Interaural 0.90 mm 14
13
12
11
Figure 92 10
9
8
7
6
5
4
3
2
1
0
-1
-2
-3
-4
-5
-6
5
10
+5
4
3
-5
0
-10
2
-1
-2
-3
-4
-5
-6
-7
-8
-9
-10
-11
-12
-13
-14
-15
Bregma -8.82 mm
5
5
0
0
-15 Bregma 0
7
6
1
Interaural +15 +10
10 +5
0
6
-5
DEn
Pir 5
BLP VEn BLA I I BMA IM
4
CxA ICj
Tu
2
AA VP
LPO
1
TC Pe
IPR
MM MMn
Pn
IPI IPC
PnC
RtTg
2
SO
Ro
MdV
1
SolC
12
mlf
CC
ml
3n cp
sox opt
DPGi ROb
Gi
0
Sol
f
mfb
2
Acs7
pd
AHC ML
1
MdD
IRt
Acs5
PnO Pn
PCRt
PCRtA 7n
VLTg RtTgP IPL
3V
MPO
3
VLL
PMD
PMV
Sp5C
Sp5O
Pr5VL
DG
DM
MPA LTer AVPe VMPO
Sp5I
CA3
LM
PeF
LH LA
0
tz AHi
SubCV VLH
HDB
ICj
4
oc/dsc
PMCo
MCPO
5
APir
BMP
cst Me
LOT 3
7
lfp
VLTg
mfb ll
rs
m5
7n
P5
A5
1
asc7
Acs5
2
m5
mcp Me
3
ACo
PMCo
s5 VCA
BMA
3
sp5 VCP
AHi
lo
4
4
BMP VEn
5
APir
BL
af
5
LEnt
6
6
7
7
Interaural 1.18 mm 14
13
12
11
Figure 93 10
9
8
7
6
5
4
3
2
1
0
-1
-2
-3
-4
-5
-6
5
10
+5
4
3
-5
0
-10
2
-1
-2
-3
-4
-5
-6
-7
-8
-9
-10
-11
-12
-13
-14
-15
Bregma -8.60 mm
5
5
0
0
-15 Bregma 0
7
6
1
Interaural +15 +10
LEnt
10 +5
0
7
6
-5
DEn PFl BLP APir
5
VEn 4
BLA
I
Pir
SI 3
BMP
Ce
AA
S
4
AHi Me
icp
CA3
MePV
MCPO
DG
LV
VLL SI
CB ICj
LPO
HDB
1
MPA
PeF LA
MPO
AVPe
0
KF MCLH
Cir
DMD
AH
DMC
Pe
Pa
ICj
SNR MT SMT SNC PnO SuM IPL PH PMnR IPI MM 3V MnR IPR IPC fr IPRL mt mp IPF 3n ml
2
opt
4n
3
cst I
IRt PnC
10
12
mlf
CC
6
SolC
0
sol 1
cu
7n
2
m5 mcp
m5
sp5
3
tz 8n VCA VCP
I
4
DPGi
1
Sol In
RtTg
hf
AHi
MdD
7n
rs
ll
sox
lo
SubCV
2
PCRt
PCRtA
P5 Acs5
cp mfb
Mo5
PeF
f
3
Sp5C
Sp5O
I5
Acc LH
Sp5I
Pr5VL
VP
Tu 2
1
5
icp
oc/dsc 4
S VEn
af
APir
5
5
DEn 6
6
7
7
Interaural 1.40 mm 14
13
12
11
Figure 94 10
9
8
7
6
5
4
3
2
1
0
-1
-2
-3
-4
-5
-6
5
10
+5
4
3
-5
0
2
-10
-1
-2
-3
-4
-5
-6
Interaural +15 +10
-7
-8
-9
-10
-11
-12
-13
-14
-15
Bregma -8.42 mm LEnt
5
5
0
0
-15 Bregma 0
7
6
1
10 +5
7
6
-5
0
DEn
PFl La
5
VEn
BLA
S
CeC
Pir
4
I
VCP
Me MePD
CeM
3
VLL MCLH
LH
SI
1
HDB
ICj
STh
PeF
LPO
ICj
AHA AHCAHP Pa MPO
VTA
DMC SMT PH SuM 3V
Pe
AVPe
LH
DMD
MPA
VOLT
0
SNR SNC MT
IPL IPF IPR IPC
PnO
1
PnC
PMnR IPA MnR
PnR
Pa6
2
Acc
SI
lo
Sol 10 SolC
0
CC
asc7
1
rs
BSTIA
2
m5
ll mcp
hf
AHi
cst CeC
4
12
A7 cp
CeM
I
In
mlf 6
opt AA
DPGi
ts
al sox
VP 3
6
7n
mfb
MCPO
IRt
RtTg
f SI
MdD
SubC
ml
3n
1
PCRt
P5 IPDL VTA
Sp5C 2
PCRtA
Mo5
fr mp
mt
Sp5I
Sp5O
I5
PC5
3
Pr5DM
Pr5VL
MCPO
VP Tu
DG
CA3
SI
2
4
VCA
AA CB
5
BL
sp5
3
tz
icp
st LV
4
S
BMP
5
5
6
6
LEnt
7
7
Interaural 1.58 mm 14
13
12
11
Figure 95 10
9
8
7
6
5
4
3
2
1
0
-1
-2
-3
-4
-5
-6
5
10
+5
4
3
-5
0
-10
2
-1
-2
-3
-4
-5
-6
-7
-8
-9
-10
-11
-12
-13
-14
-15
Bregma -8.10 mm
5
5
0
0
-15 Bregma 0
7
6
1
7
LEnt Interaural +15 +10
10 +5
0
6
AIP
-5
PFl
CA1
5
VEn
Pir
4
IPAC
BLA AStr
3
Tu
4
MePD
A7
VP
AcbSh
LH
1
ICj
HDB
0
MPA MPO
DA Pa 3V
MnPO
CLi IPA
IF
MnR
1
f
2
DEn
4
VEn
g7
sol
A7
4n
mcp
1
MVeMC m5
2
Pr5DM
ll
cp
Pr5VL sp5
sp5 8n VC
hf
cst IPAC
0
EVe
rs
sox opt
acp
AP
4V
vsc
SI
1
10
Pr
6
vtgx
al ic
lo
MVeMC
PnR
sm
3
RtTg
Sol
DMTg
ts
3n ml
mfb
2
mlf
fr mt
Sp5C
PCRtA
SubCD
PnO PMnR
sumx
3V
Sp5I
cu Cu
RI
PH
3
Sp5O DMSp5
I5 Mo5
MT VTA
Pe
P5
SNCD
LH
SubI
LPO BSTMPL StHy
Pr5VL
icp
ocb 8n
Pr5DM
VLL PL
SNR
STh
SM
VCP
DG
CA3
AL MGP
SI
CB
S VCA
MeAD B
2
CA2
BSTIA
CeC
CeM DEn LAcbSh
5
La
DEn
icp
3
DC
st LV
4
AStr
5
5
alv 6
6
7
7
Interaural 1.90 mm 14
13
12
11
Figure 96 10
9
8
7
6
5
4
3
2
1
0
-1
-2
-3
-4
-5
-6
5
10
+5
4
3
-5
0
-10
2
1
0
-1
-2
-3
-4
-5
-6
-7
-8
-9
-10
-11
-12
-15 Bregma 0
7
-13
-14
-15
Bregma -7.80 mm
5
5
7
LEnt 6
0
Interaural +15 +10
10 +5
0
6
AIP
-5
5
BLA DEn
AStr BSTIA CeC CeL CeM MePD
Pir
4
VEn DEn
3
IPAC
LSS
2
B
MGP
SI
VP
AOP
1
PaPo
BSTMPL LPO StHy MPO MPA VDB MnPO
Tu Tu 0
Pe
DG
RR
PH
RLi
3
Rbd PMnR MnR
A7
acp IPAC
CeM
Pr 0
Cb
4V
CGA CGPn
Pr MVePC MVeMC
m5
1
SpVe
2
X ll
sp5
icp
vsc mcp
sox
3
DC
st
DEn
LR4V
hf
LV
5
SGe
1
Sol
MVePC
opt
cst
MVeMC
PnR
al
ic
2
SpVe
me5
mfb
Sp5I
LVe
SubCD SubCA
ts
xscp
3n ml
8vn
P5 Mo5
mlf
3
Pa5
8n
DMTg
cp
lo
4
PnO
CLi
LSS LAcbSh
ERS
fr
mtg
Pr5VL KF Pr5DM I5
PPTg
VTA
RI
PaMP
sm
VLL PL
RRF
Xi 3V
VCP
VCA
SNR SNCD
f
2
4
MEnt
MT
DA
5
CA3
STh
mt 1
PFl
S
ZI
3V PaLM
CA2
ZI SubI
SM
AcbSh
CA1
La
4
La
ec
5
alv 6
6
7
7
Interaural 2.20 mm 14
13
12
11
Figure 97 10
9
8
7
6
5
4
3
2
1
0
-1
-2
-3
-4
-5
-6
5
10
+5
4
3
-5
0
-10
2
1
0
-1
-2
-3
-4
-5
-6
-7
-10
-11
-12
-13
-14
-15
Bregma -7.60 mm
5
5
PRh 6
-9
-15 Bregma 0
7
0
-8
Interaural +15 +10
LEnt
10 +5
0
6
AIP
-5
CA1 La
Cl
5
Pir
CeL
SI
DG CA3
B
PoDG
PaS MEnt
2
SI
VP
AcbC
STh
VTT
ZIV
LH
PPTg
SL
ADP
Tu
MnPO
RI
VTA
ATg
RLi vtgx CLi xscp scp fr 3n
MnR ts
Pr
4V
chp
Su5
MVe
LVe
SuVe
ECu
SpVe
2
icp mcp
sox opt st
4
me5 scpd
1
cu
Cu
ll
ic
LGP
0
vsc
cp
lo
9
10
mlf
ml PBP
ic
1
MVePC
LC
acp
cu
Cu
MVeMC
SuVe
DR
f
VP
2
SpVe
DTg
PMnR
Pa5
ECu
LVe
DMTg
Rbd
sm SI
aca 3
3V
Re mt
LSS
2
3V
PH
R VTRZ
sp5
8n
Mo5 SubCA
PnO
RRF
F
mch
StA
1
VRe
Pa
Pe
VDB
0
VM
3
icp
KF
PL
RR
ZI
BSTLV BSTMP PS PDP BSTMV
AcbSh
DC
Pr5DM
VLL
SNR SNCD
SM 1
4
VCA MGP
AOP
Fl
PrS
IPAC
3
5
S
CeM
CPu
PFl
CA2
AStr
DEn 4
7
PCGS
Hil
3
DC
LR4V 4
LV 5
5
hf ec alv
6
6
7
7
Interaural 2.40 mm 14
13
12
11
Figure 98 10
9
8
7
6
5
4
3
2
1
0
-1
-2
-3
-4
-5
-6
5
10
+5
4
3
-5
0
2
-10
1
0
-1
-2
-3
-4
-5
-6
-7
-8
-11
-12
-13
-14
-15
Bregma -7.34 mm
5
5
Interaural +15 +10
10 +5
6
AIP
-5
0
CA1
LaDL 5
Cl
AIV
7
LEnt
PRh 0
-10
-15 Bregma 0
7
6
-9
S
CA2
5
AStr DG B
CPu
4
CA3
DEn Pir
B
LGP
3
IPAC
2
VP BSTM PS StA
AOP
1
AcbSh
VTT SL
ICjM
0
VDB
Pa
MnPO
SL
VRe
3V
SubV Re
PH
mt
MPB
Rbd CLi xscp
SubCA
LC
DR VTg
PDTg O mlf
PMnR
ATgMnR
MVe SuVe LVe
scp
Rt acp
cp ll
3
ic
4
st
10
9
0
SpVe
1
ECu LR4V
2
icp
vsc
lo
1
4V
slim me5
2
Cu
chp
1
LDTgV
3n
SpVe MVePC
Bar
ml
2
Me5
SuVe LVe
scp
sm
aca
X ECu
RI RLi
icp
PL
SPTg
fr
f
3
RRF
RPC RMC
3V
mch
1
RLH
F
DC
VCA
LPB
PPTg
VM
BSTMPI
ADP
RR
SNCD
Rt
BSTMP
4
ILL SNR
ZI ZID
SM
BSTLV
AcbC
SNL
ZIV
SI AcbC
PoDG
mcp
STh
MGP
PrS PaS MEnt
mcp
Cop
LR4V
sox
3
Fl
opt
PFl
4
LV hf
5
ec
5
alv
6
6
7
7
Interaural 2.66 mm 14
13
12
11
Figure 99 10
9
8
7
6
5
4
3
2
1
0
-1
-2
-3
-4
-5
-6
5
10
+5
4
3
-5
0
2
-10
1
0
-1
-2
-3
-4
-5
-6
-9
-10
-11
-12
-13
-14
-15
Bregma -7.10 mm
5
5
Interaural +15 +10
10 +5
AIP
6
-5
0
LEnt
CA1
LaDL
S
CA2
5
AIV
5
Cl PFl
MEnt 4
PoDG PrS CA3 DG PaS
B DEn
CPu LGP
Pir
3
2
AOV
B
VPL ZI
AOP AcbSh
VTT
ICjM
0
Ld SL
3V
Sub SPF
Re
MiTg
RI
scp
VTg
mt
SubCA DTgP
mlf
2
IPAC
0
10
4V
9 1
MVe
me5 SuVe LVe
scp LPB vsc
acp PBG
lo
MVe
1
LC
ml
ic
3
1
Bar
scp
sm
aca
SpVe LC
DRC
PaR aci
2
ECu
LVe
LDTg Sph
DTgC
Rbd
scp
fr
3
Cop
SuVe
MPB Me5
SPTg
RLi dtgx CLi xscp
DC
LPB
PL
R
3V
Rh Re
f
ac
ILL
RRF
mch
1
LR4V VCA
PPTg
VM
VRe
ADP VDB MnPO
SNL
F
SM
BSTMA
SNR SNCD
ZID
Rt
BSTMPM
AcbC
1
SubG
4
Fl
MGP
B BSTMPL BSTL BSTMPI
7
Ect
PRh 6
-8
-15 Bregma 0
7
0
-7
ll
Cb
cp
icp
2
DC 3
mcp
sox 4
rf
st
5
4
opt
LV
5
hf
ec alv
6
6
7
7
Interaural 2.90 mm 14
13
12
11
Figure 100 10
9
8
7
6
5
4
3
2
1
0
-1
-2
-3
-4
-5
-6
5
10
+5
4
3
-5
0
2
-10
1
0
-1
-2
-3
-4
-5
-6
-7
-10
-11
-12
-13
-14
-15
Bregma -6.82 mm
5
5
Interaural +15 +10
DI
10 +5
-5
0
6
AIP
CA1
CA2
Cl
DEn
Pir
LGP
CPu
SubG ZI
B
3
VPL Rt
2
AcbC AOV AOP
1
0
VA BSTMA
BSTMPI BSTMPM
AcbSh
DTT
SHi ICjM Ld SL
VTT
BSTMPL
VDB MnPO
ac
3V
Re
1
REth PPTg DpMe
PaR
VPPC
Rh
2 SMV
10
4V
9
0
4x scp
PaR
1
Med
me5 icp
ml
LVe
lo
LR4V
2
IntP
LatPC mcp
ll
3
Lat PIL
ic 4
1
1
vsc 3
2
DTgP mlf
fr
2
Cop
VeCb
Me5
LDTg
DR
sm
LV
Y SuVe MPB
mt
aci
IntP
LPB
DpMe
4
cst
AOV
3
2&3
LVe
LDTgV
IMLFG RI Dk SPFPC EW 3V MA3
mch
f
DLL
VL
Sub
ADP
Lat
SubB MiTg
R
VRe PVA
PBG
ZID
VM
4
PM
PaS
PP
VPM
BSTLI
BSTLJ BSTLP
MEnt
PrS
LT
B
5
PFl
PoDG DG
CA3
4
LEnt
S
5
AI
7
PRh
Ect 0
-9
-15 Bregma 0
7
6
-8
rf st
4
opt
LV
5
ec
5
hf alv
6
6
7
7
Interaural 3.18 mm 14
13
12
11
Figure 101 10
9
8
7
6
5
4
3
2
1
0
-1
-2
-3
-4
-5
-6
5
10
+5
4
3
-5
0
-10
2
1
0
-1
-2
-3
-4
-5
0
Cl
LGP
LT
B
-14
-15
AOV AcbC
BSTMPL BSTMPI BSTMPM BSTLD
BSTLJ
AcbSh
VM
DTT
ICjM SHi SL
LSV
Ld VDB MnPO
CST BAC PVA ac 3V
AM
Sub
Re
Rh
IMLF Dk
MA3 EW
3V
mlf
fr
st
LV
aci
sm
LVe
LPB scp
PB
VeCb
1
LDTg 1
2 4V
dtg
ts
mt
1
CnF Pa4 4 mlf DR
3
Cop
IntP
2
PPTg PaR
IMLFG
PF RI CM
DLL LatPC
Eth
VPPC
f
ADP
MiTg
DpMe
VA
BSTMA
3
2&3
REth SPFPC
VL
4
Lat
PBG
SubB
VPM
5
PM
PIL
VPL
Rt
0
SMV 4n
scp Me5 me5
PaR
9
10
1
4V
scp
2
2
ppf ml
vsc
ll PIL
3
lo
3
mcp
eml MGV
ic
bic
rf
4
7
6
PaS
SubG
B DEn
0
-13
MEnt
PrS
DG
ZID
Pir
AOP
-12
PFl PoDG
B
CPu
AOM
-11
S
CA3
VO
4
1
-10
LEnt
CA1
CA2
5
2
-9
PRh
AI
3
-8
DI
10 +5
Ect
TeA
Ect
GI Interaural +15 +10
-7
Bregma -6.60 mm
5
5
6
-6
-15 Bregma 0
7
0
-5
4
opt st LV
5
5
hf
ec
alv
6
6
7
7
Interaural 3.40 mm 14
13
12
11
Figure 102 10
9
8
7
6
5
4
3
2
1
0
-1
-2
-3
-4
-5
-6
5
10
+5
4
3
-5
0
-10
2
-1
-2
-3
5
5
0
0
0
-6
-7
-8
-9
-10
-11
-12
-14
-15
7
PRh CA1
6
LEnt
CA2
-5
-13
Bregma -6.38 mm
Ect
TeA
DI
10 +5
-5
Ect AuV
GI Interaural +15 +10
-4
-15 Bregma 0
7
6
1
S AI
5
B
Cl
CA3 SubG
B
VO
3
VPL
B
PBG MiTg SubB
Pir DEn 2
DEn OV
AcbC
BSTMA
AOV
1
AOM
SHi
DTT
AcbSh ICjM Ld MS
0
VA BAC
LSV
PC
Re CST PVA MnPO
VPM
Rt
BSTLJ BSTLD BSTMPL BSTMPI BSTMPM
ac
Eth
IAMRh CM
3V f
PF RI
MD CM imvc
1
OV
LV
mt
sm
aci
3
2&3 LVe LPB LPBI
2
IntP
Med
Me5
IMLFG IMLF Dk MA3 EW 3V
1
LDTg 4
3
4V
mlf dtg
1
2 SMV
DR
fr
AOM
DLL
CnF
DpMe PC
Lat
PPTg
VL
AM Sub
4
Cop
APTV
Sc
Po
PM
PaS
MGV
ZID VLGMC MGM PoT REth
LGP CPu
MEnt
PrS
DG 4
5
PFl
PoDG
me5
10
9
0
1
4n
OPC
LVe IntA
vsc
st
2
2
ppf
RL 3
lo
3
eml
rf
4
ll
bic
ic
4
st 5
opt fi
5
hf ec
LV
6
alv
6
7
7
Interaural 3.62 mm 14
13
12
11
Figure 103 10
9
8
7
6
5
4
3
2
1
0
-1
-2
-3
-4
-5
-6
5
10
4
+5
3
-5
0
-10
2
1
0
-1
-2
-3
-4
10 +5
TeA
AuV
S2 Interaural +15 +10
-7
-8
-9
-10
-11
-12
GI LEnt
CA2
AI
S
4
LGP
CPu
3
AOL
PoT
Crus1
Sim
4
PaS
MGV
VLGPC
VPM
MEnt PrS
DG
Rt
BIC
MGM
PM Lat
Sag
MiTg
Eth BSTMPI BSTLD BSTMPM BSTMA
2
AcbC AcbSh
1
VPL
B
Cl
PoDG
VLGMC
SubG
B
AOM
VA AV
LSV
DP
PT PVA 3V
SHi
DTT
Ld MS MnPO
0
PC
PC
AM
LSI
VL
OPC
SCom
CM IAM CM
PoMn 3V
PAG
Su3C IMLF Su3 Dk 3PC EW
Aq
1
PAG
Med 2
4V
DR
E/OV
fr
mt
sm
LV
aci
0
4n/me5 ctg
1
4n
st
2
9
SMV
f 1
Cop
CnF Me5
PF
MD
2
IntP
LPBI
DpMe
Sc
3
IntA
PPTg
APTV
Po
5
Crus2
CA3
LO
7
6
CA1
5
VO
-15
PRh
DI
Pir
-14
Ect
-5
0
-13
Bregma -6.10 mm
5
5
6
-6
-15 Bregma 0
7
0
-5
2
ltg
ll
lo 3
3
ic
rf
bic eml
4
prf st
5
4
icf psf
opt fi LV
5
hf
ec alv
6
6
7
7
Interaural 3.90 mm 14
13
12
11
Figure 104 10
9
8
7
6
5
4
3
2
1
0
-1
-2
-3
-4
-5
-6
5
10
+5
4
3
-5
0
2
-10
1
0
-1
-2
-3
-4
-5
-6
-7
-8
-9
-10
-11
-12
-15 Bregma 0
7
5
5
AuV
-14
-15
Bregma -5.82 mm
PRh
TeA
-13
7
Ect
S2 6
0
10
Interaural +15 +10
+5
-5
0
LEnt
CA1
GI CA2
DI
6
S Crus1
5
CA3 VLGPC
AI
4
3
Pir
PLi
VO
AOL
2
BSTMPI BSTMPM
AOD
AV
PC
LSV
1
DP
MS
0
PT TS MnPO PVA f 3V
BSTMA
CM
PVP
DR
9
2
Aq
0
SMV
IAD fr
LV
1
ts
CL st
me5
IntDM
iml
2
4n
2
ppf
ll
ltg
lo rf
3
1
Med
PAG Aq
3V
2
Cop IntP
CnF Me5
PoMn
IMD
sm
1
IntA
DpMe
MD
IAM
3
PM
InWh
MCPC
AM
LSI DTT SHi Ld
Lat
Sag
PF
MDL
4
4&5
BIC
APTV
Po Eth OPC
VL
VA
Crus2
PaS MGM
VPM
5
Sim
MEnt
PrS
VPL
LGP
CPu
Cl
VLGMC MGV
Rt LO
PoDG DG
3
bic
eml str
ic
4
st
prf
icf psf
opt
4
apmf
fi
5
5
hf
ec
LV alv
6
6
7
7
Interaural 4.18 mm 14
13
12
11
Figure 105 10
9
8
7
6
5
4
3
2
1
0
-1
-2
-3
-4
-5
-6
5
10
+5
4
3
-5
0
-10
2
1
0
-1
-2
-3
-8
+5
0
LMol ProS Mol GrDG
GI
-5
Rad Py Or
Cl
CPu
LGP VPM
LO VO
-13
-14
-15
AOD
AVDM AM
LSV
1
LSI DP
DTT SHi
0
Ld
MS
PT
TS
CL MDL
ECIC
SC DpMe
2
PrC 3V
dlf
1
Me5 PAG
PVP
IMD
Cop
CnF MCPC
Med
DR
Aq
Aq
2
3
SMV
pcuf
9
8
0
fr
sm
LV
3
Lat
Sag
PF
IVF 1
4
4&5
BIC
APTV
MDC
CM
Crus2
Sim
IntA
MDM
PVA
3V f
5
Crus1
Ang
BST AVVL
1
me5
st
CIC
SC
2
2
ppf 4n
lo
3
eml
rf
bic
ic str
4
fi
bsc CA3
icf
LV
4
apmf psf
Hil
5
ec
prf
PaS
PrS opt
st
7
6
PrS PaS
PLi Po
VL
IL
-12
LEnt
MEnt
DG
DLG MGV MGD SG
Rt VPL VLGPC
3
3
-11
S
PoDG
VLGMC
4
MO
-10
PRh Ect
AI
Pir
-9
TeA
10
5
2
-7
AuV
Au1
AuV
S2 Interaural +15 +10
-6
Bregma -5.60 mm
5
5
0
-5
-15 Bregma 0
7
6
-4
5
hf
CA2 CA1 alv
6
6
7
7
Interaural 4.40 mm 14
13
12
11
Figure 106 10
9
8
7
6
5
4
3
2
1
0
-1
-2
-3
-4
-5
-6
5
10
+5
4
3
-5
0
-10
2
-1
-2
-3
-4
5
5
6
0
10 +5
-6
-7
-8
-9
0
TeA Ect
VLGMC VLGPC
4
CA3
Rt
DG
IGL
VPM
LO Cl
VO
AVDMIAD
LSI SFi SHi
fmi
MDM IMD
PVA CM D3V
Crus1 Sim
4
4&5
3
PM
ECIC
DpG InCo
PCom
1
Me5
PrC PVP
PAG Aq
pv
3V
2
Cop
MedDL
CIC
DpWh
PF
SMV
2
pcuf
0
pc
CL
sm
cg
CL MDL MDC
PT
TS Ld MS SFO f
Crus2
InWh
AVVL
LSV
PrS
InG
APT
1
DP DTT
PLi
5
Dsc
BIC
Po
VL BST
1
7
PaS
SG LP
AOD
MEnt
MGD
LGP
DLO
IL
-15
6
PoDG
DLG
VPL
CPu
MO
-14
CA2
AI
0
-13
CA1
GI
-5
-12
PRh LEnt
S
2
-11
Bregma -5.32 mm
5
3
-10
AuV
Au1
AuV
S2 Interaural +15 +10
-5
-15 Bregma 0
7
0
1
fr
1
me5 LV
Pir
iml
st
2
ppf
2
lo 3
rf eml
bic
str
3
prf
icf psf
apmf
bsc
4
ic
4
opt
st
fi
5
5
hf
ec
LV alv
6
6
7
7
Interaural 4.68 mm 14
13
12
11
Figure 107 10
9
8
7
6
5
4
3
2
1
0
-1
-2
-3
-4
-5
-6
5
10
+5
4
3
-5
0
-10
2
-1
-2
-3
5
5 0
0
0
-6
-7
-8
-9
-10
-11
-13
-14
-15
TeA
7
Ect PRh LEnt
CA1
-5
CA2
5
CA3 PoDG
VLGMC
6
S
S1J
5
-12
Bregma -5.10 mm
AuV
GI
10 +5
-5
Au1
AuV
S2 Interaural +15 +10
-4
-15 Bregma 0
7
6
1
Crus1
MEnt
Crus2 4
LGP
AI
DLG MGD LP
VPM
LO
Po
BSTS
AOD
1
LSD
IL
LSI
DTT SHi
SFi SFO TS
PVA
f vhc
fmi
InG InWh
APT CL MDL
PF
Dsc
prf
4&5
ECIC
3
PM MedDL
DpG
2
CIC
Cop
InCo
DpWh
PCom
4
Sim
PaS 1 2 3
BIC
1
Me5
MDC
PT
Ld MS
0
PrC MDM PVP SCO PV IMD pc 3V
PAG 2 SMV
Aq
3
pcuf
prf
8
0
D3V fr
sm
cg
1
VL
AVVL AVDM AD
VO
MO
SG
PLi
Cl 2
PrS
DG
VPL
Rt
CPu
DLO
3
IGL
me5
1
LV
2
2
st
lo
eml
rf
3
3
bic ic
4
str
bsc
st fi
5
4
opt
ec
LV
5
hf alv
6
6
7
7
Interaural 4.90 mm 14
13
12
11
Figure 108 10
9
8
7
6
5
4
3
2
1
0
-1
-2
-3
-4
-5
-6
5
10
4
+5
3
-5
0
2
-10
1
0
-1
-2
-3
-4
-5
-6
-7
-8
-9
-10
-11
-15 Bregma 0
5
Au1
AuD 6
0
+5
6
CA1
CA2
5
S
5
S1J
MEnt
CA3 4
Rt LDVL
CPu DLO
BSTS
LPLR
LPMC
2
AVVL
AOD
LDDM
AVDM VO
AD
LSI
1
SFi
LSD MO
PrL
IL
0
LPMR
MHb
cg fmi
Crus1 Crus2
3
ECIC 4
2
CIC InCo 1
PAG
SCO pc csc
pcf
ReIC
8
7
4&5
3
prf
0
ppf
MPT
vhc
LV
Sim 5
D3V
D3V sm
1
PaS
DpWh
PCom
LHb
SFO
f
1 2 3 BIC
DpG
PVA
gcc SHi
PrS
InWh
APT
CL MDL
MD
TS
IG
InG
OT
Po Cl
4
PoDG DG
DLG
AI
LO
7
PRh
S1ULp
3
-15
Ect
-5
0
-14
TeA
S2
10
Interaural +15 +10
-13
Bregma -4.74 mm
7
5
-12
1
fi 2
2
lo rf
3
ic
st
Hil
opt fi
ec
icf
psf
ic
4
5
3
bic
bsc
str
4
hf
LV
5
alv 6
6
7
7
Interaural 5.26 mm 14
13
12
11
Figure 109 10
9
8
7
6
5
4
3
2
1
0
-1
-2
-3
-4
-5
-6
5
10
+5
4
3
-5
0
2
-10
1
0
-1
-2
-3
-4
-5
-6
-7
-8
-9
-10
-11
-15 Bregma 0
5
6
10
Interaural +15 +10
+5
5
S1J
CA3
PoDG
DLG BSTS
Cl
LO
LPLR
VO
Rt LDVL
MO IL
PrL
SFi
IG gcc
0
cg
SHi
4
f
TS
SFO D3V
Crus1 Sim
3
Crus2
5
ECIC
4 2
CIC
DpG
PPT
InCo 1
DpWh
OPT
PAG
MPT
MHb
PaS
InWh
APTD
LHb
PVA
1 23 InG
CL MDL
LSI
LSD
PrS
LPMC
OT LPMR
AVDM
AD
1
MEnt
DG
AVVL LDDM
OB
1
5
Hil CPu
2
6
S
4
AI
pcuf 4&5
3
ReIC
csc
prf
8
0
SCO hbc
vhc sm
fmi
1
LV
2
7
PRh
CA1
CA2
DLO
-15
Ect
S1ULp
3
-14
TeA
S1BF
-5
0
Au1
AuD
S2 0
-13
Bregma -4.60 mm
7
5
-12
2
lo
fi
rf 3
icf
bsc
ic
3
bic
psf
st ic 4
fi
4
hf
ec
5
opt
5
LV alv
6
6
7
7
Interaural 5.40 mm 14
13
12
11
Figure 110 10
9
8
7
6
5
4
3
2
1
0
-1
-2
-3
-4
-5
-6
5
10
+5
4
3
-5
0
-10
2
1
0
-1
-2
-3
-4
-5
-6
-7
-8
-9
-10
-11
-15 Bregma 0
-12
-13
-14
-15
Bregma -4.28 mm
7
7
5
5
Au1 6
0
10
Interaural +15 +10
+5
Ect PRh
S1ULp
5
6
S2
-5
0
TeA
AuD
CA2
5
CA1 S
S1J
MEnt
CA3
4
Crus1
PoDG DLG
AI 3
2
LO
OPT LSD
MO
PrL
IL
IG
0
InG
PPT
InWh
2
3
5
3 ECIC
Crus2
4
2
1
DpG
LSI
MHb
SHi gcc
Sim
CIC
DG
TS vhc SFO
PAG ReIC
cic
D3V sm
1
OT APTD
AD
VO
1
LP
LD
Cl
1
SuG/Zo Op
LPMC
DLO
PaS
PrS
DG
CPu
4
3
7
prf
pcuf 4&5
0
hbc 1
cg fmi LV
2
2
opt
3
icf
bic
bsc
psf
fi
3
4
4
hf ec 5
5
alv
dcw
6
6
7
7
Interaural 5.72 mm 14
13
12
11
Figure 111 10
9
8
7
6
5
4
3
2
1
0
-1
-2
-3
-4
-5
-6
5
10
+5
4
3
-5
0
2
-10
-1
-2
-3
-4
-5
-6
-7
-8
-9
-10
-11
-12
-13
-14
-15
Bregma -4.10 mm
5
5
6
0
-15 Bregma 0
7
0
1
+5
-5
0
Au1
AuD
S2
10
Interaural +15 +10
TeA 6
Ect
S1BF S1ULp
5
M1
PRh
CA1
CA2
S1J 4
MEnt PoDG
3
DLG
CPu
DLO
LD
Cl
12
PaS
1
LSD PrL
LSI
Cg2 IG
MO 0
SHi
TS
gcc
DG vhc SFO
Rad
MHb
Sim
3
Crus2
ECIC
3
2
CIC
InWh VO
4
Crus1
InG
OT
LO
PrS
DG SuG/Zo Op
LP
2
5
S
CA3
AI
7
1
SuG
DpG PAG
D3V
cic
hbc
ReIC
pcuf 4&5
3
prf
6
0
sm 1
1
fmi
cg
LV 2
2
bsc
bic
fi
3
psf 3
4
4
dhc
hf
ec 5
5
alv dcw
6
6
7
7
Interaural 5.90 mm 14
13
12
11
Figure 112 10
9
8
7
6
5
4
3
2
1
0
-1
-2
-3
-4
-5
-6
5
10
4
+5
3
-5
0
-10
2
1
0
-1
-2
-3
-4
-5
-6
-9
-10
-11
-12
-13
-14
-15
Bregma -3.86 mm
5
5
Au1 0
-8
-15 Bregma 0
7
6
-7
Interaural +15 +10
S2
10 +5
TeA
6
S1BF
-5
0
V2L
AuD
Ect
S1ULp
5
5
PRh
CA1
CA2 S1J
4
M1
S
DG
CA3
PrS
CPu
PaS
Zo SuG
DLO 2
ECIC 32
Op LO
InWh DpG
LSD
Cg2 IG
MO
0
CA1
CA3 PrL
5
1
2
4 1
DCIC PAG
PiRe
TS vhc
cc
CIC
InG
DG
VO
3
Sim
AI
1
4
MEnt Crus1
PoDG 3
7
3
cic
pcuf
4
prf
5
6
0
ReIC 1
1
LV
fmi
cg
bic
chp
2
2
fi
psf
bic
3
3
dhc
4
4
fmj
hf
ec
alv 5
5
dcw 6
6
7
7
Interaural 6.14 mm 14
13
12
11
Figure 113 10
9
8
7
6
5
4
3
2
1
0
-1
-2
-3
-4
-5
-6
5
10
+5
4
3
-5
0
-10
2
-1
-2
-3
-4
-5
Interaural +15 +10
0
-7
-8
-9
S1BF
-5
-12
-13
-14
-15
Ect
5
CA1
S1J
CA2
M1
PRh
4
4
S
M2
PoDG CPu
LO
Crus1 PrS
Hil
CA3
PaS MEnt
FrA VO
2
PrL
LSD
Cg2
4
InG InWh
Op CA1 Rad
1
Sim
5
CIC
SuG CA3
3
ECIC
Zo
DG
MO
7
6
TeA
S1ULp
2
-11
V2L
S2 AuD
5
3
-10
Bregma -3.60 mm
Au1
10 +5
-6
AuD
5
5
0
0
-15 Bregma 0
7
6
1
1
DCIC
TS
IG
FC
cc
0
PAG
cic
df
3
0
ReIC prf
pcuf 1
7
6
5
4
1
fmi LV
cg 2
2
chp
Crus2 fi
bic
3
hf 4
dhc
3
fmj
4
ec alv
5
5
dcw 6
6
7
7
Interaural 6.40 mm 14
13
12
11
Figure 114 10
9
8
7
6
5
4
3
2
1
0
-1
-2
-3
-4
-5
-6
5
10
+5
4
3
-5
0
2
-10
1
0
-1
-2
-3
-4
-5
-6
-15 Bregma 0
7
-7
-8
-9
-10
-11
-12
-13
-14
-15
Bregma -3.38 mm
AuD
5
5
7
Au1 6
0 Interaural +15 +10
AuD
10 +5
-5
0
V2L
6
S1BF
5
TeA
S1ULp S1J
4
5
Ect
CA1
PRh
CA2
4
M1 M2
3
CPu
RSA
S
PoDG Hil
PrS
PaS
3
Sim
CA3 ECIC
DG 2
Crus1
FrA
Zo CA3
SuG
1
2
DCIC CIC
1
CA1 PrL
Cg2
FC
IG
cc
0
df
cic
ReIC
3
pcuf
4
prf
5 psf
6
0
1
1
fmi
LV
cg
2
2
fi
3
3
hf dhc
fmj
ec
4
4
dcw alv
5
5
6
6
7
7
Interaural 6.62 mm 14
13
12
11
Figure 115 10
9
8
7
6
5
4
3
2
1
0
-1
-2
-3
-4
-5
-6
5
10
+5
4
3
-5
0
-10
2
-1
-2
-3
-4
-5
-6
-7
-8
-9
-10
-11
-12
-13
-14
-15
Bregma -3.10 mm
5
5
0
0
-15 Bregma 0
7
6
1
Interaural +15 +10
AuD
10 +5
0
6
V2L
-5
TeA
S1BF 5
7
5
S1ULp Ect CA1
S1J 4
4
M1
CA2
Crus1
M2
RSA
3
PrS
2
PaS
FrA
S
DG
CA3
2
DCIC
CA1 Zo/SuG
1
PrL
Cg2
3
Sim
CPu
IG
FC
cc
0
1
Op
cic
df
4
5
prf
0
dhc
1
1
fmi 2
cg
LV
2
2
3 1
hf
3
3
dhc
fmj 4
4
dcw
alv
5
5
6
6
7
7
Interaural 6.90 mm 14
13
12
11
Figure 116 10
9
8
7
6
5
4
3
2
1
0
-1
-2
-3
-4
-5
-6
1 2
1 2 3 4
dl
3 4 C1
py
LSp
LatC
7 9
9
8
LSp
py
5
10 IMM
6
9
C7
1-10 CeCv dl IML
spinal cord layers central cervical nucleus dorsolateral fasciculus intermediolateral cell column IMM intermediomedial cell column LatC lateral cervical nucleus LSp lateral spinal nucleus py pyramidal tract
py 10 IMM
7
9
8 9
9
Figure 117a*
1 2 3 4
6
CeCv IMM 10
7 9
C4 5
5
LSp
dl
8 9
9 9
1 2 3
dl
dl
4
LatC
C2
dl C5
6
CeCv10 7 8
9
9
IMM
5
10
9
dl LSp
py
5
IMM
9
10
C6
1 2 3 4
1 2
py IMM
7
10
LSp IML
5 6
9
7
8
9 9
3
4
6 9
T1 dl
5
CeCv10
7 9
9
9
C3
8
IMM 8
9
1 2 3 4
LatC LSp
7
9
9
dl
py
6 9
8
C8
2 3
4
LSp
py
7 9 9 9 9
IMM
1
5
py
5
LSp
LSp
1 2 3 4
9
9
py IMM 8
9
10
* Fig 117a & 117b are reproduced from Molander and Grant (1995) with permission of the authors. Users of these figures should cite Molander, C. and Grant, G., 1995, Spinal cord cytoarchitecture. In G. Paxinos(Ed), The Nervous System, Second Edition, Academic Press, SanDiego.
1 dl
dl
1 2 3
4 LSp
4
T3 LSp
dl
2 3
5
LSp
D IMM
9
9
9
7
9
7
IMM 8
9
8
9
9
9 9
9
1 1
T5 dl
1
5
py D
LSp
5
IML
IML
py 7
D IMM 8
9
7
py
S2
10 7
5
LSp
3
5
LSp
py
2
4
L5
1
2 3 4
LSp
2 3
4
dl
L2
2 3
4
spinal cord layers central cervical nucleus dorsolateral fasciculus intermediolateral cell column IMM intermediomedial cell column LatC lateral cervical nucleus LSp lateral spinal nucleus py pyramidal tract
10
10 IMM
IMM
6 10
10
9
IMM
7
8
IMM
9
9
10
9
9
8
8
9
9
9
1 2 3 4
dl
LSp
py
S3
5 10
7 IMM
1
dl
3 4
D IMM 9
py
6
1
10 10
IMM
7
9
9
9
3 4
7
10
IMM
9 8
8 9
9
L6
2
5 LSp
6
IML
7
3
py
py IML
dl
4
5
5
L3
2
1
LSp
2 3
4 LSp
T10
8
1
dl
9
LSp
5
8 9
S4
2
7
9
IMM 8
9
10
Figure 117b* 1-10 CeCv dl IML
6
6
8
S1
5 LSp
9
dl
py
4
IMM
9
10
2
3
5
10
7
8
dl
py
IML
1
L4
4
D
py 7
L1 py
5 IML
1 2 3
* Fig 117a & 117b are reproduced from Molander and Grant (1995) with permission of the authors. Users of these figures should cite Molander, C. and Grant, G., 1995, Spinal cord cytoarchitecture. In G. Paxinos(Ed), The Nervous System, Second Edition, Academic Press, SanDiego.
Go to START PAGE 5
4
3
2
1
0
-1
-2
-3
-4
-5
-6
-7
Bregma
-8
-9
-10
-11
-12
-15
Pineal 6
5
6 6
Corpus Callosum
4
Inferior Superior Colliculus Colliculus
Hippocampus
7 3
3V Fornix
Posterior Commissure
8 Cerebellum
4V
2
Thalamus
Septum
9
Midbrain
1
Anterior Commissure Olfactory Tubercle
-14
Lambda
Cerebral Cortex
Olfactory Bulb
-13
Preoptic Area
Hypothalamus
4V
Pons
9
10
Medulla Oblongata
Optic Chiasm Spinal Cord
Pituitary
Lateral 0.40 mm 14
13
12
11
Interaural 10
9
8
7
6
5
4
3
2
1
0
-1
-2
-3
-4
Click on sagittal diagram to go the corresponding coronal diagram
-5
-6
Go to START PAGE 7
6
5
4
3
2
1
0
1
2
3
6
5
4
7
Corpus Callosum Somatosesnory Cortex Barrel Field
Hippocampus Lateral Ventrical
S2
Auditory Cortex
Mediodorsal Nu
Internal Capsule
VPM
Caudate Putamen (Striatum)
VPL
Thalamus
Hypothalamus
Amygdala Optic Tract
Amygdala
Fornix Piriform Cortex
Lateral Hypothalamus 3rd Ventricle 7
6
5
4
3
2
1
Ventromedial Hy Nu 0
1
2
3
4
5
6
7
Click on Coronal diagram to go the corresponding sagittal diagram
Go to START PAGE
Bregma
10
9
1
Pineal
Cerebral Cortex
Hippocampus
6
Posterior Commissure
4V
Thalamus
Septum
Olfactory Tubercle
1
Preoptic Area
Cerebellum
5
2
9 1
Anterior Commissure
2
4
8
6
Midbrain
3
3
7 3
Fornix Olfactory Bulb
2
4
Inferior Superior Colliculus Colliculus
3V
5
6 6
Corpus Callosum
4
6
5
8
7
0
4V
10
9 7
8
Hypothalamus
Pons
Medulla Oblongata
9
Optic Chiasm 0
Interaural Pituitary
-1
Spinal Cord
10
11
Lateral 0.40 mm
Click on sagittal diagram to go the corresponding horizontal diagram
PREFACE: FOURTH EDITION The Compact Third Edition of The Rat Brain in Stereotaxic Coordinates presented revised drawings of 76 coronal sections of the brain. The Fourth Edition includes these coronal diagrams, but in addition presents the fully revised sagittal and horizontal figures and the photographs on which all the diagrams are based. We are brain cartographers, and, like our geographer colleagues, our central aim is to provide precise coordinates and accurate identification of features of interest. In this fourth edition of our atlas, we have used the proven stereotaxic reference system that we constructed for the first edition (Paxinos and Watson, 1982). This reference system is now universally recognized as the optimum grid for stereotaxic work in the rat brain. We have completely revised the identification of brain structures in order to produce an atlas that will be useful beyond the end of this century.
Features of the Fourth Edition •
The most accurate stereotaxic reference system available displayed in three planes • Completely revised diagrams of 10 sagittal and 27 horizontal sections that previously appeared in the second edition of this atlas (Paxinos and Watson, 1986) • Includes the 1997 revisions of the 76 coronal diagrams (Paxinos and Watson, 1997) augmented by two new drawings of coronal sections at the level of the anterior diencephalon • Each diagram is accompanied by a matching photograph of the section on which it is based • Delineations assisted by consideration of separate sets of brain sections stained for parvalbumin, calbindin, calretinin, SMI-32, tyrosine hydroxylase, and NADPH diaphorase (Paxinos et al., in press [a,b]), the rat nervous system textbook (Paxinos, 1995), (Paxinos and Watson 1997), and other recent neuroanatomical literature • Spinal cord drawings from the atlas of Molander and Grant (1995) • Diagrams available on CD-ROM for printing at different magnifications
Reproduction of Atlas Figures in Other Publications As authors, we are happy for our atlas figures to be reproduced in other publications, but we expect our work to be suitably acknowledged. If coordinates from the atlas are used, they should be acknowledged as in the following example: “Bregma 1.60 mm (Paxinos and Watson, 1998).” Permission to reproduce the figures contained in the atlas can be obtained from the publisher: Academic Press Permissions Department 6277 Sea Harbor Drive Orlando, FL USA 32887 Telephone: (407) 345-3990 Fax: (407) 352-8860. When requesting permission, please identify all the figures you wish to reproduce. Allow four weeks for your request to be processed. We recommend that you use the nomenclature and abbreviation scheme that we developed for this book. This scheme has been developed on a systematic basis (see below) and is now widely recognized.
ACKNOWLEDGMENTS We are indebted to Lewis Tsalis for outstanding accuracy and speed in entering our drawings into the computer using Adobe Illustrator. We thank Paul Halasz for his excellent work in designing and assembling the CD-Rom version of this atlas. We thank Hong-Qin Wang for preparation of excellent quality photographic plates. We thank David Kopf for providing us with his extremely accurate stereotaxic instrument. We thank Kodak Australia for assistance with the provision of photographic paper. We thank Fine Science Tools Inc (Vancouver, Fax: 415-349-3729) for providing us with precision forceps used for the preparation of specimens. We thank Faulding Imaging for providing us with an Olympus Provis Research Microscope system at a reduced price We thank Professor Kevin McConkey, Head of the School of
Psychology at the University of New South Wales, and Professor Gerard Sutton, Vice Chancellor of the University of Wollongong, for their generous support. We thank Professor David Tracey for allowing us to use facilities in the School of Anatomy. We thank Apple Australia for providing equipment to assist with digitizing the drawings for this atlas. G.P. Thanks Elly for direct help as well as tolerance during construction of this and previous editions of this atlas.
INTRODUCTION There are many reasons why the rat is the most commonly selected subject for research in mammalian neuroscience. First, rats are the right size: neither too small for accurate stereotaxic localization of discrete brain areas nor too large for cost-effective laboratory management. Second, rats are generally hardy animals and are resistant to infections. Third, a number of inbred strains are available commercially; so, animals of consistent size can be used
for stereotaxic procedures. When the first edition of The Rat Brain in Stereotaxic Coordinates was published in 1982, it was the first atlas to be based on the flatskull position. It offered a choice of bregma, lambda, or the midpoint of the interaural line as the reference point. Although the coordinates were developed from study of adult male Wistar rats with weights ranging from 270 to 310 g, the atlas can be successfully used with male or female rats, with weights ranging from 250 to 350 g (Paxinos et al., 1985). The present atlas presents 78 photographs and accompanying diagrams of coronal sections of the brain, at intervals that average 0.25 mm. The sections were cut from unfixed brains that were frozen. The diagrams in this atlas were originally based on the study of Nissl- (cresyl violet) and acetylcholinesterase- (AChE) stained sections. The mapping of the sections was assisted by the use of our sections showing the distribution of a number of antibody-based and enzyme-based stains (parvalbumin, calbindin, calretinin, SMI-32, tyrosine hydroxylase, and NADPH diaphorase). A comprehensive atlas based on chemical markers will be published by Academic Press (Paxinos et al., in press [a,b]).
TABLE 1 Craniometric and stereotaxic data (means ± S.D.) for rats of different sex, strain, and weight AP
Mean
AP
AP
DV
AP
AP
weight I – incisor bar (g)* (mm)
I–B
I–L
I–B
I – Acb
B – ac
(mm)
(mm)
(mm)
(mm)**
(mm)**
290
9.1 ± 0.3
0.3 ± 0.3
10.0 ± 0.2
11.7
0.0
300 270 290 282
9.2 8.9 9.1 9.3 ± 0.2
0.2 0.0 0.2 0.5 ± 0.3
10.1 10.0 10.1 10.0 ± 0.1
11.6
0.1
9.4 ± 0.4
0.3 ± 0.6
9.8 ± 0.2
11.9
0.0
–1.2
299
9.0 ± 0.2
0.7 ± 0.2
10.1 ± 0.1
11.7
0.1
180
7.7 ± 0.4
–0.4 ± 0.3
9.9 ± 0.2
10.2
–0.1
436 –2.7 ± 0.3
9.7 ± 0.3
0.6 ± 0.3
10.7 ± 0.4
12.4
–0.1
DV
I – 7n Subject (mm)** ‘Atlas’ Wistar –1.3 –3.3 ± 0.4 Coronal plates Sagittal plates Horizontal plates Female Wistar –1.2 –3.2 ± 0.5 Hooded 290 –3.9 ± 0.6 Sprague –1.2 –3.9 ± 0.5 Juvenile Wistar –1.6 –2.0 ± 0.4 Mature Wistar –0.8
* S.D.s. ≤ 20 g. ** S.D.s. ≤ 0.4 mm. ac, anterior commissure; Acb, accumbens nucleus; AP, anterior-posterior; B, bregma; DV, dorsal-ventral; 7n, facial nerve; I, interaural line; L, lambda. Reprinted with permission from J. Neuroscience Methods. 13 (1985) 139-143.
It also presents photographs and fully revised diagrams of 10 sagittal and 27 horizontal sections.
Stereotaxic Surgery In establishing the stereotaxic coordinate system for this atlas we studied sections from over 100 rats. To prepare these sections, we positioned the skull in a standard way (the flat-skull position) and marked the vertical and horizontal planes with needle tracks. We placed anesthetized rats in a Kopf small-animal stereotaxic instrument, and the incisor bar was adjusted until the heights of lambda and bregma were equal. This flat-skull position was achieved when the incisor bar was lowered 3.3 ± 0.4 mm below horizontal zero (Table 1). Because the point of intersection of the lambdoid and sagittal sutures is variable, we have chosen to define lambda as the midpoint of the curve of best fit along the lambdoid suture (see skull diagram). This redefined reference point is considerably more reliable than the true lambda (the point of intersection of the sagittal and lambdoid sutures), and it is located 0.3 ± 0.3 mm anterior to the interaural line. We defined bregma as the point of intersection of the sagittal suture with the curve of best fit along the coronal suture. When the two sides of the coronal suture meet the sagittal suture at different points, bregma usually falls midway between the two junctions. The anteroposterior position of bregma was 9.1 ± 0.3 mm anterior to the coronal plane passing through the interaural line, but for the brain represented in this atlas bregma is deemed to lie at 9.0 mm. The top of the skull at bregma and lambda was 10.0 ± 0.2 mm dorsal to the interaural zero plane. To confirm the stereotaxic orientation of sections in the brain used for this atlas, reference needle tracks were made perpendicular to the horizontal and coronal planes. For brains sectioned in the coronal plane, vertical needle insertions were made at 2.0 mm intervals through the brain, except for the penetrations at 0.7 mm anterior to the interaural line, which was chosen to avoid rupture of a venous sinus. Ten such needle tracks appear on coronal plates of this atlas. Three horizontal needle insertions perpendicular to the coronal plane were made from the posterior of the brain at 1.0, 3.0, and 5.0 mm above the interaural line and approximately 1.0 mm lateral to the midline. The reference tracks from the horizontal needles appear as small holes in coronal sections. For brains sectioned in the sagittal plane, vertical needles were inserted in both hemispheres at 3.0 mm posterior to the interaural
line and at 1.0 and 2.0 mm lateral to the midline. A second pair was inserted 11 mm anterior to the interaural line at 1.0 and 2.0 mm lateral to the midline. Horizontal needle tracks perpendicular to the coronal plane were made at 5.0 mm and 6.0 mm dorsal to the interaural line and 2.0 mm lateral to the midline. Horizontal needle tracks perpendicular to the sagittal plane were made at 5.0 mm dorsal to the interaural line and 2.0 mm and 8.0 mm anterior to it. For brains sectioned in the horizontal plane, two vertical reference tracks were made by inserting a needle at 2.0 and 9.0 mm anterior to the interaural line and approximately 1.4 mm lateral to the midline. These reference tracks appear as pinholes in the horizontal sections. Five horizontal needle tracks perpendicular to the coronal plane were made by inserting needles at 1.0, 3.0, 5.0, 7.0, and 8.0 mm above the interaural lines.
Histology After surgery, the animals were deeply anesthetized and decapitated, and their brains were frozen on dry ice within 3 min of decapitation. For the coronal plane, brains were divided into two blocks at a plane 3.0 mm anterior to the interaural line prior to placement on the freezing microtome stage. At the level of the blocking some sections were lost and it was necessary to insert three plates (Figs. 42–44) from another brain. Brains remove from the skull for sectioning on the horizontal or sagittal planes initially presented a problem in that they assumed the shape of the stage on which they were positioned. To avoid this distortion, the brains were frozen in the skull, and the skull bones were then prized off the frozen brains. Spinal cord segments were obtained from 9 rats and were fresh frozen in propane cooled with liquid nitrogen. Representative sections from the major regions of the spinal cord are included in the atlas (Plates 117a,b). None of these plates are accompanied by a drawing, but their approximate location in the Mollander and Grant (1995) spinal cord atlas is given and the diagrams from the Mollander and Grant atlas are reproduced with permission of the authors. Frozen brains were sectioned on an American Optical Cryocut microtome at 40 µ m. Sections were obtained parallel to the stereotaxic planes by adjusting the angle of cutting until the needle tracks encountered were judged to be parallel to the plane of section. Sections were taken directly from the cryotome knife on
uncoated slides with the help of an anti-roll device. At each 0.5 mm interval, three sections were taken for staining with cresyl violet or for the demonstration of AChE. Staining was carried out on the same day as cutting. The two stains were used in an alternating fashion in relation to the section intervals. One of these sections at each interval was presented in the first edition of the atlas. In the second edition we interpolated an additional section between the 0.5 mm interval sections in most cases. In the present atlas, the interpolated sections commence after Fig. 11. An attempt was made to select interpolated sections close to the midpoint of the interval of the plates in the first edition of the atlas, but such sections often were not available, and the closest suitable section was selected. Because of this process of selection of interpolated sections, the regular alternation of Nissl- and AChE-stained sections was broken.
8 h, and then allowed to dry. Subsequently, they were dehydrated for 5 min in 100% alcohol, then immersed in xylene and coverslipped with Permount. The stock solution was a 50 mM sodium acetate buffer at pH 5.0 which was made 4.0 mM with respect to copper sulphate and 16 mM with respect to glycine. This was done by adding 6.8 g of sodium acetate, 1.0 g of copper sulphate crystals, and 1.2 g of glycine to 1.0 L of water and lowering the pH to 5.0 with HCl. We found that fresh, unfixed tissue from the frozen brains showed a substantially stronger reaction for both stains than tissue fixed with formalin, paraformaldehyde, glutaraldehyde, or alcohol. A detailed protocol of the staining procedures may be obtained from George Paxinos (http://www.psy.unsw.edu.au/~ paxinos).
Cresyl Violet Staining
Photography
Slides were immersed for 5 min in each of the following: xylene, xylene, 100% alcohol, 100% alcohol, 95% alcohol, and 70% alcohol. They were dipped in distilled water and stained in 0.5% cresyl violet for 15–30 min. They were differentiated in water for 3–5 min and then dehydrated through 70% alcohol, 95% alcohol, 100% alcohol, and 100% alcohol. They were then put in xylene and coverslipped. To make 500 mL of 0.5% cresyl violet of about pH 3.9, mix 2.5 g of cresylecht violet (Chroma Gesellschaft, Postfach 11 10, D-73257, Kongen, Germany, Fax number: 49-7024-82660), 300 mL of water, 30 mL of 1.0 M sodium acetate (13.6 g of granular sodium acetate in 92 mL of water), and 170 mL of 1.0 M acetic acid (29 mL of glacial acetic acid added to 471 mL of water). Mix this solution for at least 7 days on a magnetic stirrer, then filter.
AChE Histochemistry The method for the demonstration of AChE followed the procedures of Koelle and Friedenwald (1949) and Lewis (1961). Slides were incubated for 15 h in 100 mL of stock solution (see below) to which had been added 116 mg of S-acetylthiocholine iodide and 3.0 mg ethopropazine (May & Baker). The slides were rinsed with tap water and developed for 10 min in 1% sodium sulphide (1.0 g in 100 mL of water) at pH 7.5. They were then rinsed with water and immersed in 4% paraformaldehyde in phosphate buffer for
The drawings of the brain were traced from photographs of stained brain sections which were taken with a Nikon Multiplot macrophotographic apparatus on 4 × 5 inch Kodax Plus X film. High contrast (grade 4) Ilfospeed paper was used for the Nissl sections, whereas lower contrast (grade 2) paper was used for the AChE sections.
Drawings As far as possible, we have attempted to make the drawings accurately represent the photographs. Small adjustments have been made to some sections in which the midline or cerebral cortex were distorted, but otherwise the drawings depict the asymmetries present in the sections. When part of an atlas section was missing or severely distorted, the missing part was drawn in after consideration of sections obtained from other brains. Fiber tracts in the drawings are outlined by solid lines, and nuclei and cell groups are outlined by broken lines. In general, each abbreviation is placed in the center of the structure to which it relates; where this is not possible, the abbreviation is placed alongside the structure and a leader line is used. The abbreviations for fiber tracts and fissures are almost always positioned on the
SKULL DIAGRAM Dorsal and lateral views of the skull of a 290 g Wistar rat. The positions of bregma, lambda, and the plane of the interaural line are shown above the lateral view. The distance between the horizontal plane passing through the interaural line is shown on the right of the lateral view. The distance between the incisor bar and the horizontal plane passing through the interaural line is shown on the left of the lateral view. Lambda (midpoint of the curve of best fit along the lambdoid suture) is 0.3 mm anterior to the coronal plane passing through the interaural line.
left side of the figure, and the abbreviations for nuclei and other cell groups are generally positioned on the right side. The outlines of the ventricles and aqueduct are filled in with solid black. The drawings were entered into a Power Mac using Adobe Illustrator 6.
passing through the interaural line. The numbers on the top margin show the anteroposterior distance from the coronal plane passing through bregma.
Horizontal Drawings
Stereotaxic Reference System Two coronal and two horizontal zero-reference planes are used in these drawings; one coronal plane and one horizontal plane are related to the interaural line and the other two are related to bregma. Lambda is located 0.3 ± 0.3 mm anterior to the interaural line, and it can be used as an alternative reference point in conjunction with the dorsoventral coordinate of bregma. The position of the stereotaxic reference points and planes are indicated on the skull diagram. The stereotaxic reference grid shows 0.2 mm intervals.
Coronal Drawings In each of the coronal drawings, the large number at the bottom shows the anteroposterior distance of the corresponding plate from the vertical plane passing through the interaural line. The large number at bottom right shows the anteroposterior distance of the plate from bregma. The small numbers on the left margin show the dorsoventral distance from the horizontal plane passing through the interaural line. The numbers on the right margin show the dorsoventral distance from the horizontal plane passing through bregma and lambda on the surface of the skull. The numbers on the top and bottom margins show the distance of structures from the midline.
Sagittal Drawings The large number at the bottom left of each drawing shows the distance of the corresponding plate from the midline. The numbers on the left margin show the dorsoventral distance from the horizontal plane passing through the interaural line. The numbers on the right margin show the dorsoventral distance from the horizontal plane passing through bregma and lambda on the surface of the skull. The numbers on the bottom margin show the anteroposterior distance from the coronal plane
The large number at the bottom left of each drawing shows the dorsoventral distance of the corresponding plate from the horizontal plane passing through the interaural line. The large number at the top right shows the dorsoventral distance of the TABLE 2 Coordinates of the bed nucleus of the anterior commissure and the trochlear nucleus obtained from the three planes Bed nucleus of the ant. comm.
Trochlear nucleus
Plane
A-P
D-V
Lat
A-P
D-V
Lat
Coronal Sagittal Horizontal
8.2 8.0 8.1
3.4 3.4 3.4
0.9 0.9 0.9
1.7 1.8 1.8
3.4 3.5 3.4
0.4 0.4 0.4
plate from the horizontal plane passing through the bregma and lambda on the surface of the skull. The numbers on the bottom margin show the anteroposterior distance from the coronal plane passing through the interaural line. The numbers on the top margin show the anteroposterior distance from the coronal plane passing through bregma. The numbers on the left and right margins show the distance of structures from the midline. Values ventral to the interaural horizontal zero or posterior to either the interaural line or bregma are preceded by a minus sign.
An Example of Use of the Stereotaxic Reference System In this example, we will consider the insertion of an electrode into the basolateral amygdaloid nucleus. Figure 31 shows that the center of the basolateral amygdaloid nucleus is 6.2 mm anterior to the interaural line, 1.5 mm dorsal to it, and 5.0 mm lateral to the midline. The nucleus is 2.8 mm posterior to bregma, 8.5 mm ventral to it, and 5.0 mm lateral to the midline.
Stereotaxic Accuracy In most cases, the position of a structure is represented to an accuracy of less than 0.5 mm. Although we used medium-sized (average 290 g) male Wistar rats in the construction of this atlas, we recognize that researchers often use animals of different sex, strain, and weight. Because of this, we have estimated the error that will occur if this atlas is used with female Wistar rats, male hooded (Long Evans) rats, male Sprague Dawley rats of 290-g weight, juvenile (180 g) Wistar rats, and mature (436 g) Wistar rats. The results of these estimations are shown in Table 1 (reproduced from Paxinos et al., 1985). It is evident from these studies that no substantial stereotaxic error will occur when rats of different sex and strain are chosen, provided that the rats are of similar weight to those on which the atlas is based (290 g). For example, for rats of different sex and strain but of similar weight, the anteroposterior distance between the interaural line and bregma is between 9.0 and 9.4 mm. Similarly, the dorsoventral distance between the interaural line and the surface of the skull at bregma and lambda is very stable (9.8–10.1 mm). By contrast, craniometric data for juvenile (180 g) and mature (436 g) Wistar rats differ substantially from those of other groups. The anteroposterior distance between the interaural line and bregma is 7.7 mm in the juvenile and 9.7 mm in the mature rats (9.0 mm in 290-g male rats). Lambda is 0.4 mm posterior to the interaural line in the juvenile rats and 0.6 mm anterior to this line in the mature rats (0.3 mm anterior in 290-g rats). Unexpectedly, the dorsoventral distance between the interaural line and bregma for juvenile rats (9.9 mm) was almost the same as that of 290-g rats (10.0 mm). In the mature rats, the interaural line to bregma vertical distance was 10.7 mm. In female rats, as well as in hooded, juvenile (180 g), mature (436 g) and 290-g Wistar rats, bregma was found to be above the most forward crossing fibers of the anterior commissure. This is the point at which the posterior limbs of the anterior commissure appear. These data confirm the observation of Whishaw et al. (1977) that bregma is more stable than the interaural line for positioning of electrodes in brain structures close to, or anterior to, bregma. However, data from insertion of needles aimed at the level where the facial nerve leaves the facial genu (Fig. 60 in this atlas) show that the interaural reference point is more stable than bregma for localization of such posterior structures. Therefore, if juvenile or mature rats are used, greater accuracy can be achieved if bregma is used as the reference point for work with rostral structures and the interaural line for work with caudal structures. A further
improvement in accuracy can be obtained by taking into account the actual location of the accumbens nucleus (anterior part of Acb shown on Fig. 9) and the genu of the facial nerve (Fig. 60). In agreement with Slotnick and Brown (1980), we noticed that coordinates of structures were closer to target if the coordinates given by the interaural and bregma reference systems were averaged. In studying the drawings of coronal sections in this atlas, it should be noted that the sections in Figs. 1–3, 42-44, and 69–78 were taken from rat brains different from the one pictured in the
The Brain Blocker ␣ ␣ Designed toeproduce r the plane of section of The Rat Brain in Stereotaxic Coordinates (PA 001; David Kopf Instruments, P.O. Box 636, Tujunga, CA 91043).
remaining coronal drawings. This supplementation was necessary because of distortion of the olfactory bulbs and caudal medulla in the brain from which most of the sections were taken, and because of the loss of a number of sections at the level at which the brain was blocked.
Use of the David Kopf Stereotaxic Instrument and Brain Blocker In our work on this and other stereotaxic atlases we found the David Kopf Small Animal Stereotaxic instrument of high precision. However, no atlas or stereotaxic instrument will compensate for using bregma and lambdoid points inappropriately. These reference skull marks are the midpoints of the curve of best fit along the coronal and the lambdoid suture, respectively. They are not necessarily the points of intersection of these sutures with the midline suture.
Researchers usually wish to block the brain at the same coronal (or sagittal) plane as the atlas plane (flat skull position) so that they can determine most readily the location of their electrode placements and identify structures according to the atlas. The brain blocker depicted in the accompanying photograph allows the blocking of the brain at the stereotaxic plane or the slicing of the brain at 1-mm intervals. After blocking, the brain needs to be placed on a chuck with surface parallel to the cryotome knife. For cryotomes without zero-tilt position, this can be achieved by freezing some mounting medium directly onto the chuck and cutting through the mounting medium to create an aligned surface on which to position the blocked tissue.
structures in atlases of the rat (Paxinos and Watson, 1986), mouse (Franklin and Paxinos, 1996), monkey (Paxinos et al., in press), and human (Paxinos et al., 1990; Mai et al., 1997). Atlas users may wish to reflect on the construction of the abbreviations for acetylcholinesterase (AChE) and magnesium (Mg) to get a good idea of how our list was produced. The abbreviations used in the present and in our other work were developed using the following principles:
Nomenclature
3. The general principle used in the abbreviations of the names of elements in the periodic table was followed: the capital letter representing the first letter of a word in a nucleus is followed by the lower case letter most characteristic of that word (not necessarily the second letter; e.g., Mg = magnesium; Rt = reticular thalamic nucleus).
There is a critical need for a stable neuroanatomical nomenclature to accurately and efficiently convey information between neuroscientists. However, many terms are still used to describe a single structure, and, in some cases, the same term is used for completely different structures. We urge you to consider the merits of our system of nomenclature because it is systematic and derived after extensive consultations with neuroanatomy experts. In considering the merit of a particular term over synonyms, we have chosen terms that have been ratified by modern usage, particularly usage by experts in that field. We have used anglicized versions of terms rather than older latinized versions wherever possible, and we have in all but a handful of cases avoided the use of eponyms.
Principles of Construction of Abbreviations Neuroscience communities concerned with different systems have developed identical abbreviations for completely different structures; for example SO stands for both supraoptic nucleus and superior olive, SC for suprachiasmatic nucleus and superior colliculus, and IC for inferior colliculus and internal capsule. In dealing with the entire nervous system (as increasingly more researchers do) these parochial abbreviation schemes become impossible to implement. An additional complication arises when homologous structures are nonetheless named or abbreviated differently in different species. We have made an effort to establish homologies and are using the same abbreviations for homologous
1. The abbreviations represent the order of words as spoken in English (e.g., DLG = dorsal lateral geniculate nucleus). 2. Capital letters represent nuclei, and lower case letters represent fiber tracts. Thus, the letter “N” has not been used to denote nuclei, and the letter “t” has not been used to denote fiber tracts.
4. Compound names of nuclei have a capital letter for each part (e.g., LPGi = lateral paragigantocellular nucleus. 5. If a word occurs in the names of a number of structures, it is usually given the same abbreviation (e.g., Rt = reticular thalamic nucleus; RtTg = reticulotegmental nucleus of the pons). Exceptions to this rule are made for well-established abbreviations such as VTA. 6. Abbreviations of brain regions are omitted where the identity of the region in question is clear from its position (CMn = centromedian thalamic nucleus; not CMnTh). 7. Arabic numerals are used instead of Roman numerals in identifying (a) cranial nerves and nuclei (as in the Berman, 1968, atlas), and (b) layers of the spinal cord. While the spoken meaning is the same, the detection threshold is lower, ambiguity is reduced, and they are easier to position in small spaces available on diagrams.
The Basis of Delineation of Structures in This Atlas For the third edition, we completely reviewed our delineations of all areas of the brain. Our primary guide was an extensive collection of histochemically stained sections (monoclonal antibodies and
enzyme-based stains; Paxinos et al., in press [a,b]). Our work has been made easier by the availability of an excellent rat brain atlas published by Swanson (1992). We have also made extensive use of other publications from our laboratory (Paxinos, 1995; Paxinos and Huang, 1995; Paxinos et al., 1994) as well as of authoritative studies published in the Journal of Comparative Neurology and other journals. We present below a brief account of the basis of delineation of structures. We have not repeated here the rationale for the delineation of structures presented in the second edition (Paxinos and Watson, 1996). Readers may wish to refer to that book or consult the work of Swanson (1992) and Kruger et al. (1995) for the history of identification of many structures in the rat brain.
Olfactory System Refer to Shipley et al. (1995) for a general description of the olfactory system. We based our delineations in part on the work of de Olmos et al. (1978). The existence of the semilunar nucleus was established on the basis of NADPH-diaphorase histochemistry (Paxinos et al., in press [a]). We acknowledge assistance of R. Harlan and P.-Y. Wang in the identification of this structure (Ahima and Harlan, 1990; Wang and Zhang, 1995).
Basal Ganglia and Basal Forebrain Refer to Heimer et al. (1995) and Fallon and Loughlin (1995) for a general description of the basal ganglia and to Alheid et al. (1995) for a discussion of the substantia innominata and extended amygdala. Immunoreactivity for parvalbumin and the neurofilament protein SMI-32 identifies the ventral pallidum (Paxinos et al., in press [a]). We retained the term substantia innominata and identified dorsal, ventral (as in Grove, 1988), and basal components with the assistance of G. Alheid. The basal component is marked by some positivity in tyrosine hydroxylase but is negative for SMI-32 (although surrounding areas are positive). The concept of ventral pallidum, first proposed by Heimer and his associates, has been the guiding principle for structure/function relations of the basal forebrain (Barragan and Ferreyra-Moyano, 1995; Heimer et al., 1997). The researchers at the University of Virginia and Universidad Nacional de Cordoba have recently carved
out of the substantia inominata another big territory, the sublenticular extended amygdala (Alheid et al., 1995). Franklin and Paxinos (1997) adopted the new scheme for their mouse brain atlas. We retained the name substantia inominata (for the part remaining after the removal of the ventral pallidum) in keeping with earlier editions of this atlas. The dorsal substantia inominata roughly corresponds to the sublenticular extended amygdala, central part, while the ventral substantia inominata corresponds to the sublenticular extended amygdala, medial part. The area previously called fundus striati resembles the striatum proper in some respects and the accumbens shell in others. Given that the use of the term fundus striati creates problems with primate homologues, we followed the advice of G. Alheid and called it the lateral accumbens shell. The remaining accumbens is delineated in accordance with Zaborszky et al. (1985) and Heimer et al. (1991). We followed Alheid et al. (1995) in the identification of the interstitial nucleus of the posterior limb of the anterior commissure (IPAC). The reticular part of the substantia nigra can be divided into a ventrolateral and a dorsomedial component on the basis of parvalbumin and calbindin distribution (Paxinos et al., in press [b]). The remainder of the substantia nigra and the ventral tegmental area were delineated according to the work of McRitchie et al. (1996).
Septum, Hypothalamus, and Neurosecretory Nuclei Refer to Simerly (1995), Armstrong (1995), Jakab and Leranth (1995), and Oldfield and McKinley (1995) for a general description of these structures. Jutting ventrolaterally from the anterodorsal preoptic nucleus is a strip which is negative for parvalbumin which we have called the alar nucleus. The alar nucleus displays substance P positive cell bodies but little reactivity in its neuropil (Larsen, 1992). In the preoptic area we followed Simerly (1995) and Simerly et al. (1984) except for the identification of the ventromedial and ventrolateral preoptic nuclei, for which we followed Elmquist et al. (1996) and Sherin et al. (1996). The compact part of the medial preoptic nucleus is negative for substance P (see Fig. 7 of Halliday et al., 1995, in which this structure is visible but not labeled). In the lateral hypothalamus we identified a ventrolateral hypothalamus nucleus on the basis of NADPH-diaphorase reactivity
(Paxinos et al., in press [a]). This nucleus is caudal to the ventrolateral preoptic nucleus and dorsal to the supraoptic nucleus. The ventral part of dorsomedial nucleus is marked by densely stained cell bodies and terminals in NADPHdiaphorase preparations (Paxinos et al., in press [a]). The gemini nucleus is a conspicuous nest of a NADPH-diaphorase cell bodies (Paxinos et al., in press [a]). The parasubthalamic nucleus is present in the rat (Wang and Zhang, 1995), but it is not as impressive as the homologous structure seen in the mouse brain (Franklin and Paxinos, 1996). The arcuate nucleus was delineated according to the work of Magoul et al. (1994). See Paxinos and Watson (1986) for the identification of the striohypothalamic, magnocellular lateral hypothalamic, terete, and subincertal nuclei.
Amygdala and Bed Nucleus of Stria Terminalis Refer to Alheid et al. (1995) for a general description of the amygdala and the bed nucleus of the stria terminalis. The anterodorsal part of the medial nucleus of the amygdala and the basomedial nucleus are defined by the presence of intense NADPH-diaphorase reactivity (Paxinos et al., in press [a]). The lateral part of the central nucleus of the amygdala is marked by the presence of tyrosine hydroxylase fibers and AChE negativity (Paxinos et al., in press [a]).
Thalamus Refer to Price (1995) for a general description of thalamic nuclei. See Paxinos and Watson (1986) for the identification of the ethmoid, retroethmoid, subgeniculate, and precommissural nuclei. We have reverted to the use of the term ventral posterior nucleus, parvicellular part (Paxinos and Watson, 1982) for the nucleus that we previously named the gustatory nucleus of the thalamus (Paxinos and Watson, 1986). We made this change on the advice of C. Saper that gustatory input is more medial in this nucleus, and autonomic-related inputs can be found at more lateral parts of this structure (Yasui et al., 1989).
Hippocampal Region Refer to Amaral and Witter (1995) for a general description of the hippocampal region. The postsubicular area was identified on the basis of the work of Van Groen et al. (1992).
Cortex There have been two comprehensive cortical parcellation schemes in recent decades. The first one was presented by Zilles (1985) and was constructed on the original stained sections of the present atlas (updated by Zilles and Wree, 1995). In the second edition of our atlas we used the cortical parcellations of Zilles (1985). The second comprehensive cortical delineation scheme was presented by Swanson (1992). The Zilles (1985) and Zilles and Wree (1995) works differ significantly from the Swanson (1992) scheme. The atlas of chemical markers (Paxinos et al., in press [a,b]) enabled us to make a decision on the strengths of the two schemes. On this basis we have retained many of the features of the sensory, motor, and insular areas proposed by Zilles (1985). However, we have curtailed the rostral spread of Zilles’s occipital areas and delineated the sensory representation of the trunk region and parietal association area in line with Swanson (1992). We have retained the perirhinal cortex at caudal levels (along with Zilles, 1985) because there is a characteristic NADPH-diaphorase reactivity associated with this area. However, we have delineated the ectorhinal cortex and temporal association area in accordance with Swanson (1992). Strong parvalbumin immunoreactivity is present in layer 4 of the primary somatosensory cortex. SMI-32 immunoreactivity formed distinctive patches in layer 4 of the barrel field and forelimb and hindlimb regions. The primary auditory area was identified on the basis of reduced calbindin immunoreactivity in the deep layers. All the auditory areas were marked by the presence of SMI32 positive cells in the superficial layers. AChE marked the location of the prelimbic and agranular insular cortices. NADPH-diaphorase assisted in defining the agranular insular, perirhinal, and retrosplenial granular cortices. Additionally, NADPH-diaphorase immunoreactivity indicated the ventral part of the medial entorhinal cortex. Calretinin immunoreactivity assisted in delineation of the lateral entorhinal cortex where the outer part of layer one is densely stained. The dorsolateral orbital cortex was delineated in accordance with
the work of Ray and Price (1992). The retrosplenial agranular cortex was delineated according to the work of Van Groen and Wyss (1992). On the advice of Laura Kus we introduced the term frontal association cortex for the frontal cortex that others allocated to the secondary motor cortex (Swanson, 1992; Zilles, 1985). This designation is in agreement with microstimulation data (Neafsey et al., 1986).
Reticular Formation Refer to Jones (1995) for a general description of the reticular formation. The intermediate reticular zone was first identified in the rat (Paxinos and Watson, 1986), but is seen to advantage in the human brain (Paxinos and Huang, 1995). The intermediate reticular zone at levels of the caudal pole of the facial nerve nucleus is marked by NADPH-diaphorase positive cells. The lateral paragigantocellular nucleus is conspicuous in NADPHdiaphorase preparations (Paxinos et al., in press [b]). We have identified the parapyramidal nucleus as the cell group dorsolateral to the pyramidal tract, which is outlined but not named in the second edition of this atlas (Paxinos and Watson, 1986). The identification of the epifascicular nucleus is based on the description of this nucleus in the human brain (Paxinos and Huang, 1995).
Periaqueductal Gray Refer to Beitz (1995) for a general description of the periaqueductal gray. The boundaries of periaqueductal gray cell columns were drawn according to Carrive (1993), Carrive and Paxinos (1994), and Paxinos and Huang (1995). Two nuclei lateral to the central gray pars alpha were identified on the basis of SMI-32 immunoreactivity; P.-Y. Wang identified these structures and named them central gray pars beta and central gray pars gamma (Paxinos et al., in press [b]).
Tegmental Nuclei For the identification of the anterior tegmental, microcellular tegmental, subpeducular tegmental, rabdoid, and epirubrospinal nuclei, see Paxinos and Watson (1986).
Raphe Nuclei We identified the raphe nuclei on the basis of 5-hydroxytryptamine sections prepared by G. Halliday and I. Tork (see also Halliday et al., 1995). We identified the raphe interpositus nucleus on the basis of the work of Buttner-Ennever et al. (1988).
Locus Coeruleus and Brainstem Catecholamine Cell Groups Refer to Aston-Jones et al. (1995) for the delineation of the locus coeruleus. We delineated the catecholamine cell groups by following Hokfelt et al. (1984) with assistance from our own tyrosine hydroxylase preparations (Paxinos et al., in press [b]).
Brainstem Nuclei Associated with the Respiratory Cardiovascular and Other Autonomic Functions Refer to Saper (1995) and Norgren (1995) for a general description of these nuclei. NUCLEUS OF THE SOLITARY TRACT. The posterior part of the nucleus of the solitary tract was delineated in accordance with the work of Whitehead (1990), Herbert et al. (1990), McRitchie (1992), and Altschuler et al. (1989). The rostral part of the nucleus of the solitary tract was difficult to delineate, but we recognize a rostrolateral subnucleus on the basis of NADPH-diaphorase positivity. VENTRAL RESPIRATORY GROUPS AND B ¨OTZINGER COMPLEX. These areas were delineated in accordance with Ellenberger et al. (1990), Kanjhan et al. (1995), and Cox and Halliday (1993). PARABRACHIAL NUCLEUS. The parabrachial nucleus is delineated in accordance with Fulwiler and Saper (1984), Herbert et al. (1990), Whitehead (1990), and Herbert and Saper (1990). The external part of the lateral parabrachial nucleus and medial parabrachial nucleus are marked by NADPH-diaphorase positive cells and fibers (Paxinos et al., in press [b]).
Oromotor Nuclei Refer to Travers (1995) for a description of the oromotor nuclei.
Precerebellar Nuclei and Red Nucleus Refer to Ruigrok and Cella (1995) for a general description of these structures. Within what has been previously called the pararubral area (Ruigrok and Cella, 1995) there is a circumscribed cell group which we called the pararubral nucleus. We have named the large cells below the minimus nucleus and above the lateral lemniscus the epilemniscal nucleus (Paxinos et al., in press [b]).
Cerebellum The identification of lobules, fissures, and deep cerebellar nuclei is based on the work of Voogd (1995).
Somatosensory System Refer to Tracey and Waite (1995) and Waite and Tracey (1995) for a general description of the somatosensory system. The general basis of delineation of these structures is described in Paxinos and Watson (1996). However, we followed Marfurt and Rajchert (1991) for the borders of the spinal trigeminal nucleus.
Visual System Refer to Sefton and Dreher (1995) for a general description of the visual system. The ventral tegmental visual relay zone was identified on the basis of the work of Giolli et al. (1985). The intergeniculate leaf was delineated on the basis of the work of Morin and Blanchard (1995).
Auditory System Refer to Webster (1995) for a general description of the auditory system. We used Faye-Lund and Osen (1985) as well as Malmierca et al. (1995) for the identification of areas of the inferior colliculus. The medial geniculate was delineated according to the work of LeDoux et al. (1985). For additional details on the basis of delineation of the components of the auditory system refer to Paxinos and Watson (1986).
REFERENCES Ahima, R. S., and Harlan, R. E. (1990). Charting of Type II glucocorticoid receptor-like immunoreactivity in the rat central nervous system. Neuroscience 39, 579–604. Alheid, G. F., de Olmos, J. S., and Beltramino, C. A. (1995). Amygdala and extended amygdala. In G. Paxinos (Ed.), The Rat Nervous System, 2nd ed. Academic Press, San Diego, pp. 495–578. Altschuler, S. M., Bao, X., Bieger, D., Hopkins, D. A., and Miselis, R. R. (1989). Viscerotopic representation of the upper alimentary tract in the rat: Sensory ganglia and nuclei of the solitary and spinal trigeminal tracts. J. Comp. Neurol. 283, 248–268. Amaral, D. G., and Witter, M. P. (1995). Hippocampal formation. In G. Paxinos (Ed.), The Rat Nervous System, 2nd ed., Academic Press, San Diego, pp. 443–493. Armstrong, W. E. (1995). Hypothalamic supraoptic and paraventricular nuclei. In G. Paxinos (Ed.), The Rat Nervous System, 2nd ed., Academic Press, San Diego, pp. 377–390. Aston-Jones, G., Shipley, M. T., and Grzanna, R. (1995). The locus coeruleus, A5 and A7 noradrenergic cell groups. In G. Paxinos (Ed.), The Rat Nervous System, 2nd ed., Academic Press, San Diego, pp. 183–212. Barragan, E. I., and Ferreyra-Moyano, H. (1995). Ventrostiopallidal functional interconnections with cortical and quasi-cortical regions. Brain Res. Bull. 37, 329–336. Beitz, A. J. (1995). Periaqueductal Gray. In G. Paxinos (Ed.), The Rat Nervous System, 2nd ed., Academic Press, San Diego, pp. 173–182. Berman, A. L. (1968). The Brainstem of the Cat: A Cytoarchitectonic Atlas with Stereotaxic Coordinates. University of Wisconsin Press, Madison. Buttner-Ennever, J. A., Cohen, G., Pause, M., and Fries, W. (1988). Raphe nucleus of the pons containing omnipause neurons of the oculomotor system in the monkey, and its homologue in man. J. Comp. Neurol. 267, 307–321. Carrive, P. (1993). The periaqueductal gray and defensive behavior functional representation and neuronal organization. Behav. Brain Res. 58, 27–47. Carrive, P., and Paxinos, G. (1994). The supraoculomotor cap: A region revealed by NADPH diaphorase histochemistry. NeuroReport 5, 2257–2260. Cox, M., and Halliday, G. M. (1993). Parvalbumin as an anatomical marker for discrete subregions of the ambiguous complex in the rat. Neurosci. Lett. 160, 101–105. De Olmos, J., Hardy, H., and Heimer, L. (1978). The afferent connections of the main and the accessory olfactory bulb formation in the rat: An experimental HRP study. J. Comp. Neurol. 181, 213–244. Ellenberger, H. H., Feldman, J. L., and Zhan, W.-Z. (1990). Subnuclear organization of the lateral tegmental field in the rat. II: Catecholamine neurons and ventral respiratory group. J. Comp. Neurol. 294, 212–222. Elmquist, J. K., Scammell, T. E., Jacobson, C. D., and Saper, C. B. (1996). Distribution of Foslike immunoreactivity in the rat brain following intravenous lipopolysaccharide administration. J. Comp. Neurol. 371, 1–19. Fallon, J. H., and Loughlin, S. E. (1995). Substantia nigra. In G. Paxinos (Ed.), The Rat Nervous System, Academic Press, San Diego, pp. 215–237. Faye-Lund, H., and Osen, K. K. (1985). Anatomy of the inferior colliculus in rat. Anat. Embryol. 171, 1–20. Franklin, K., and Paxinos, G. (1997). The Mouse Brain in Stereotaxic Coordinates. Academic Press, San Diego. Fulwiler, C. E., and Saper, C. B. (1984). Subnuclear organization of the efferent connections of the parabrachial nucleus in the rat. Brain Res. Rev. 7, 229–259. Giolli, R. A., Blanks, R. H. I., Torigoe, Y., and Williams, D. D. (1985). Projections of medial terminal accessory optic nucleus, ventral tegmental nuclei, and substantia nigra of rabbit and rat as studied by retrograde axonal transport of horseradish peroxidase. J. Comp. Neurol. 232(1), 99–116.
Grove, E. A. (1988). Efferent connections of the substantia innominata in the rat. J. Comp. Neurol. 277, 347–364. Halliday, G., Harding, A., and Paxinos, G. (1995). Serotonin and tachykinin systems. In G. Paxinos (Ed.), The Rat Nervous System, 2nd ed., Academic Press, San Diego, pp. 929–974. Heimer, L., Zahm, D. S., Churchill, L., Kalivas, P., and Wohltmann C. (1991). Specificity in the projection patterns of accumbal core and shell in the rat. Neuroscience 41, 89–125. Heimer, L., Harland, R. E., Alheid, G. F., Garcia, M. M., and De Olmos, J. (1997). Substantia inominata: a notion which impedes clinical-anatomical correlations in neuropsychiatric disorders. Neuroscience 76, 957–1006. Heimer, L., Zahm, D. S., and Alheid, G. F. (1995). Basal ganglia. In G. Paxinos (Ed.), The Rat Nervous System, 2nd ed., Academic Press, San Diego, pp. 579–628. Herbert, H., Moga, M., and Saper, C. (1990). Connections of the parabrachial nucleus with the nucleus of the solitary tract and the medullary reticular formation in the rat. J. Comp. Neurol. 293, 540–580. Hökfelt, T., Martensson, R., Bjorklund, A., Kleinau, S., and Goldstein, M. (1984). Distributional maps of tyrosine-hydroxylase-immunoreactive neurons in the rat brain. In A. Bjorklund and T. Hökfelt (Eds.), Handbook of Chemical Neuroanatomy, Vol. 2, Part 1. Elsevier, Amsterdam. Jakab, R. L., and Leranth, C. (1995). Septum. In G. Paxinos (Ed.), The Rat Nervous System, 2nd ed., Academic Press, San Diego, pp. 405–442. Jones, B. E. (1995). Reticular formation: Cytoarchitecture, transmitters, and projections. In G. Paxinos (Ed.), The Rat Nervous System, 2nd ed., Academic Press, San Diego, pp. 155–171. Kanjhan, R., Lipski, J., Kruszewska, B., and Rong, W. (1995). A comparative study of presympathetic and Bötzinger neurons in the rostral ventrolateral medulla (RVLM) of the rat. Brain Res. 699, 19–32. Koelle, G. G., and Friedenwald, J. S. (1949). A histochemical method for localizing cholinesterase activity. Proc. Soc. Exp. Biol. Med. 70, 617–622. Konig, J. F. R., and Klippel, R. A. (1963). The Rat Brain: A Stereotaxic Atlas of the Forebrain and Lower Parts of the Brain Stem. Williams and Wilkins, Baltimore. Kruger, L., Saporta, S., and Swanson, L. W. (1995). Photographic Atlas of the Rat Brain, Cambridge University Press, Cambridge. Larsen, P. J. (1992). Distribution of substance P-immunoreactive elements in the preoptic area and the hypothalamus of the rat. J. Comp. Neurol. 316, 287–313. LeDoux, J. E., Ruggiero, D. A., and Reis, D. J. (1985). Projections to the subcortical forebrain from anatomically defined regions of the medial geniculate body in the rat. J. Comp. Neurol. 242, 182–213. Lewis, P. R. (1961). The effect of varying the conditions in the Koelle method. Bibltheca Anat. Vol. 2, Karger, Basel, 11–20. Magoul, R., Ciofi, P. and Tramu, G. (1994). Visualization of an efferent projection route of the hypothalamic rat arcuate nucleus through the stria terminalis after labeling with carbocyanine dye (DiI) or proopiomelanocortin-immunohistochemistry. Neurosci. Lett. 172,134–138. Mai, J. K., Assheuer, J., and Paxinos, G. (1997). Atlas of the Human Brain. Academic Press, San Diego. Malmierca, M. S., Rees, A., Le Beau, F. E., and Bjaalie, J. G. (1995). Laminar organization of frequency-defined local axons within and between the inferior colliculi of the guinea pig. J. Comp. Neuro. 357(1), 124–44. Marfurt, C., and Rajchert, D. M. (1991). Trigeminal primary afferent projections to “NonTrigeminal” areas of the rat central nervous system. J. Comp. Neurol. 303, 489–511. McRitchie, D. A. (1992). Cytoarchitecture and chemical neuroanatomy of the nucleus of the solitary tract: Comparative and experimental studies in the human and the rat. Unpublished Ph.D. thesis, Univ. of New South Wales. McRitchie, D. A., Hardman, C. D. and Halliday, G. M. (1996). Cytoarchitectural distribution of
calcium binding proteins in midbrain dopaminergic regions of rats and humans. J. Comp. Neurol. 364, 121–150. Molander, C., and Gunnar, G. (1995). Spinal cord cytoarchitecture. In G. Paxinos (Ed.), The Rat Nervous System, 2nd ed., Academic Press, San Diego, pp. 39–44. Morin, L. P., and Blanchard, J. (1995). Organization of the hamster intergeniculate leaflet: NPY and ENK projections to the suprachiasmatic nucleus, intergeniculate leaflet and posterior limitans nucleus. Visual Neurosci. 12, 57–67. Neafsey, E. J., Bold, E. L., Haas, G., Hurley-Gius, K. M., Quirk, G., Sievert, C. F., and Terreberry, R. R. (1986). The organization of the rat motor cortex: A microstimulation mapping study. Brain Res. Rev. 11, 77–96. Norgren, R. (1995). Gustatory system. In G. Paxinos (Ed.), The Rat Nervous System, 2nd ed., Academic Press, San Diego, pp. 751–771. Oldfield, B. J., and McKinley, M. (1995). Circumventricular organs. In G. Paxinos (Ed.), The Rat Nervous System, 2nd ed., Academic Press, San Diego, pp. 391–403. Paxinos, G. (Ed.) (1995). The Rat Nervous System, 2nd. ed., Academic Press, San Diego. Paxinos, G., and Huang, X.-F. (1995). Atlas of the Human Brainstem. Academic Press, San Diego. Paxinos, G., and Watson, C. (1982) The Rat Brain in Stereotaxic Coordinates. Academic Press, Australia. Paxinos, G., and Watson, C. (1986). The Rat Brain in Stereotaxic Coordinates, 2nd ed. Academic Press, San Diego. Paxinos, G. and Watson C. (1997). The Rat Brain in Stereotaxic Coordinates, Compact 3rd ed. CD-Rom. Academic Press, San Diego. Paxinos, G. et al. (in press [a]). Chemoarchitecture of the Rat Forebrain. Academic Press, San Diego. Paxinos, G. et al. (in press [b]). Chemoarchitecture of the Rat Brainstem. Academic Press, San Diego. Paxinos, G., Ashwell, K.W., and Tork, I. (1994). Atlas of the Developing Rat Nervous System, Second edition, Academic Press, San Diego. Paxinos, G., Tork, I., Halliday, G., and Mehler, W. R. (1990). Human homologs to brainstem nuclei identified in other animals as revealed by acetylcholinesterase. In G. Paxinos (Ed.), The Human Nervous System, Academic Press, San Diego, pp. 149–202. Paxinos, G., Watson, C., Pennisi, M., and Topple, A. (1985). Bregma, lambda and the interaural midpoint in stereotaxic surgery with rats of different sex, strain and weight. J. Neurosci. Meth. 13, 139–143. Price, J. L. (1995). Thalamus. In G. Paxinos (Ed.), The Rat Nervous System, 2nd ed., Academic Press, San Diego, pp. 629–648. Ray, J. P. and Price, J. L. (1992). The organization of the thalamocortical connections of the mediodorsal thalamic nucleus in the rat, related to the ventral forebrain-prefrontal cortex topography. J. Comp. Neurol. 323, 167–197. Ruigrok, T. J. H., and Cella F. (1995). Precerebellar nuclei and red nucleus. In G. Paxinos (Ed.), The Rat Nervous System, 2nd ed., Academic Press, San Diego, pp. 277–308. Saper, C. B. (1995). Brain stem and cerebellum, central autonomic system: In G. Paxinos (Ed.), The Rat Nervous System, 2nd ed., Academic Press, San Diego, pp. 107–135. Sefton, A. J., and Dreher, B. (1995). Visual system. In G. Paxinos (Ed.), The Rat Nervous System, 2nd ed., Academic Press, San Diego, pp. 833–898. Sherin, J. E., Shiromani, P. J., McCarley, R. W., and Saper, C. B. (1996). Activation of ventrolateral preoptic neurons during sleep. Science 271, 216–219. Shipley, M. T., and McLean, J. H., and Ennis, M. (1995). Olfactory system. In G. Paxinos (Ed.), The Rat Nervous System, 2nd ed., Academic Press, San Diego, pp. 899–926. Simerly, R. B. (1995). Anatomical substrates of hypothalamic integration. In G. Paxinos (Ed.), The Rat Nervous System, 2nd ed., Academic Press, San Diego, pp. 353–376. Simerly, R. B., Swanson, L. W., and Gorski, R. A. (1984). Demonstration of a sexual
dimorphism in the distribution of serotonin-immunoreactive fibers in the medial preoptic nucleus of the rat. J. Comp. Neurol. 225, 151–139. Slotnick, B. M., and Brown, D. L. (1980). Variability in the stereotaxic position of cerebral points in the albino rat. Brain Res. Bull. 5, 135–139. Swanson, L. W. (1992). Brain Maps: Structure of the Rat Brain. Elsevier, Amsterdam. Tracey, D. J., and Waite, P. M. E. (1995). Somatosensory system. In G. Paxinos (Ed.), The Rat Nervous System, 2nd ed., Academic Press, San Diego, pp. 689–704. Travers, J. B. (1995). Oromotor nuclei. In G. Paxinos (Ed.), The Rat Nervous System, 2nd ed., Academic Press, San Diego, pp. 239–250. Van Groen, T., and Wyss, J. M. (1992). Connections of the retrosplenial dysgranular cortex in the rat. J. Comp. Neurol. 315, 200–216. Voogd, J. (1995). Cerebellum. In G. Paxinos (Ed.), The Rat Nervous System, 2nd ed., Academic Press, San Diego, pp. 309–350. Waite, P. M. E., and Tracey, D. J. (1995). Trigeminal sensory system. In G. Paxinos (Ed.), The Rat Nervous System, 2nd ed., Academic Press, San Diego, pp. 705–724. Wang, P. Y., and Zhang, F. C. (1995). Outlines and Atlas of Learning Rat Brain Slides. Westnorth University Press, China. Webster, W. R. (1995). Auditory system. In G. Paxinos (Ed.), The Rat Nervous System, 2nd ed., Academic Press, San Diego, pp. 797–831. Whishaw, I. Q., Cioe, J. D. D., Previsich, N., and Kolb, B. (1977). The variability of the interaural line vs the stability of bregma in rat stereotaxic surgery. Physiol. Behav. 19, 719– 722. Whitehead, M. C. (1990). Sibdivisions and neruon types of the nucleus of the solitary tract in the hamster. J. Comp. Neurol. 310, 554–574. Yasui, Y., Saper, C., and Cechetto, D. (1989). Calcitonin gene-related peptide immunoreactivity in the visceral sensory cortex, thalamus, and related pathways in the rat. J. Comp. Neurol. 290, 487–501. Zaborszky, L., Alheid, G. F., Beinfeld, M. C., Eidens, L. E., Heimer, L., and Palkovits, M. (1985). Cholecystokinin innervation of the ventral striatum: A morphological and radioimmunological study. Neurosci. 14, 427–453. Zilles, K. (1985). The Cortex of the Rat: A Stereotaxic Atlas. Springer-Verlag, Berlin. Zilles, K., and Wree, A. (1995). Cortex: areal and laminar structure. In G. Paxinos (Ed.), The Rat Nervous System, 2nd ed., Academic Press, San Diego, pp. 649–685.
5
4
3
2
1
0
-1
-2
-3
-4
-5
-6
-7
Bregma
-8
-9
-10
-11
-12
-13
-14
Lambda Bregma
10
9
6
5
8
Fornix Olfactory Bulb
Posterior Commissure
9 6
1
Anterior Commissure Olfactory Tubercle
2
5
2
Midbrain
3
4
8 Cerebellum
4V
Thalamus
Septum
3
7 3
3V
5
2
4
Inferior Superior Colliculus Colliculus
Hippocampus
6
6 6
Corpus Callosum 7
0
1
Pineal
Cerebral Cortex
4
-15
4V
9
10
7
8
Preoptic Area
Hypothalamus
1
Pons
Medulla Oblongata
9
Optic Chiasm 0
Interaural
Spinal Cord
Pituitary -1
10
11
Lateral 0.40 mm 14
13
12
11
Interaural 10
9
8
7
6
5
Sagittal Section of the Rat Brain A drawing of a section of the rat brain cut in a sagittal plane 0.4 mm lateral to the midline. The drawing was made from a photograph of a Nissl-stained sagittal section (Plate 78 in Paxinos and Watson, 1986). Almost all major regions of the brain can be seen in this section, so that it can be used as a guide to the position of the coronal sections of the brain (Figs. 1–76). A miniature version of this section is shown at the top left of Figs. 1–76 (the section plan) to mark the position of each coronal section. The only major regions of the brain not pictured here are the anterior part of the olfactory bulb, which has been cut off at the left of the section, and the subcortical nuclei (caudatoputamen, globus pallidus, and the amygdala), which are located about 3–5 mm lateral to this sagittal plane. Parts of the ventricular system of the brain can be seen in this section (represented in solid black). Note that the pituitary gland can be
4
3
2
1
0
-1
-2
-3
-4
-5
-6
seen ventral to the hypothalamus and the pineal gland can be seen dorsal to the superior colliculus. It should be noted that the boundaries between some of the brain regions pictured here are approximations, since the arbitrary classification of cell groups as belonging to one area or another does not always result in sharp lines of regional demarcation. The position of skull landmarks (bregma, lambda, and the interaural line) are shown in this figure. The top grid line indicates anteroposterior locations in relation to a coronal plane passing through bregma. The bottom grid line shows anteroposterior locations in relation to a coronal plane passing through the interaural line. The left vertical grid line shows dorsoventral locations in relation to a horizontal plane passing through bregma. The right vertical grid shows dorsoventral positions in relation to a horizontal plane passing through the interaural line.
Index of Abbreviations The abbreviations are listed in alphabetical order. Each abbreviation is followed by the structure name and the number of the figures on which the abbreviation appears. LSp lateral spinal nucleus 117a,b
1a layer of cortex 5 1b layer of cortex 5 2&3 cerebellar lobules 56-57, 63-66, 85-86, 101-103 2n optic nerve 13-17, 92 3 oculomotor nucleus 44-48, 79-80, 102-103 3n oculomotor nerve or its root 42-44, 81-83, 90-99 3PC oculomotor nucleus, parvicellular part 44-49, 79-80, 104 3V 3rd ventricle 18-39, 79-82, 90-108 4 trochlear nucleus 49, 79-80, 101-103 4&5 cerebellar lobules 58, 65-66, 87-88, 105-112 4n trochlear nerve or its root 43, 52-57, 82-83, 85-86, 91-92, 94, 96, 102106 4V 4th ventricle 56-73, 79-82, 96-104 4x trochlear decussation 79-82, 101 5Gn trigeminal ganglion 91 6 abducens nucleus 60-63, 80, 94-96 6a cerebellar lobule 19, 79-80 6b cerebellar lobule 19, 79-80 6c cerebellar lobule 79-80 6n root of abducens nerve 56, 62, 81 7 facial nucleus 61-66, 82-84, 90-91 7DI facial nucleus, dorsal intermediate subnucleus 65 7DL facial nucleus, dorsolateral subnucleus 65 7DM facial nucleus, dorsomedial subnucleus 65 7L facial nucleus, lateral subnucleus 65 7n facial nerve or its root 58-61, 82-85, 90-95 7VI facial nucleus, ventral intermediate subnucleus 65 7VM facial nucleus, ventromedial subnucleus 65 8cn cochlear root of the vestibulocochlear nerve 60-61 8Gn vestibulocochlear ganglion 61 8n vestibulocochlear nerve 63-66, 84, 86-87, 90, 94, 96-98 8vn vestibular root of the vestibulocochlear nerve 58-63, 85, 97 10 dorsal motor nucleus of vagus 70-78, 80-81, 94-96
10n vagus nerve or its root 67 12 hypoglossal nucleus 70-80, 91-95 12n root of hypoglossal nerve 71-77
A a artery 83 A1 A1 noradrenaline cells 71-78 A2 A2 noradrenaline cells 74-78 A4 A4 noradrenaline cells 62-65 A5 A5 noradrenaline cells 54-64, 83-84, 90-93 A7 A7 noradrenaline cells 54-55, 83, 95-97 A8 A8 dopamine cells 46-48 A11 A11 dopamine cells 32-34 A13 A13 dopamine cells 29-31 AA anterior amygdaloid area 25, 84-87, 93-95 AAD anterior amygdaloid area, dorsal part 22-24 AAV anterior amygdaloid area, ventral part 21-24, 91-92 ac anterior commissure 18-20, 79-81, 100-103 aca anterior commissure, anterior part 8-17, 82-84, 98-100 AcbC accumbens nucleus, core 9-16, 82-84, 98-104 AcbSh accumbens nucleus, shell 9-16, 80-83, 96-104 Acc accessory neurosecretory nuclei 28, 94-95 aci anterior commissure, intrabulbar part 1-7, 82-83, 100-104 ACo anterior cortical amygdaloid nucleus 22-31, 86-87, 90-93 acp anterior commissure, posterior part 18-22, 82-89, 96-100 Acs5 accessory trigeminal nucleus 58-59, 93-94 Acs6 accessory abducens nucleus 59-60, 91 Acs7 accessory facial nucleus 61-65, 91-93 AD anterodorsal thalamic nucleus 23-28, 82, 108-111 ADP anterodorsal preoptic nucleus 18-20, 80, 98-102 af amygdaloid fissure 35-44, 90-94 AH anterior hypothalamic area 94 AHA anterior hypothalamic area, anterior part 23-25, 80-81, 95 AHC anterior hypothalamic area, central part 25-28, 81, 93, 95 AHi anterior hypothalamic area 87, 92-95 AHiAL amygdalohippocampal area, anterolateral part 34-37, 88, 91 AHiPM amygdalohippocampal area, posteromedial part 36-44, 8486, 91 AHP anterior hypothalamic area, posterior part 26-29, 80-81, 95
AI agranular insular cortex 7, 86-88, 101-113 AID agranular insular cortex, dorsal part 8-16, 85, 89 AIP agranular insular cortex, posterior part 17-30, 96-101 AIV agranular insular cortex, ventral part 8-16, 85, 89, 99-100 AL nucleus of the ansa lenticularis 85, 96 Al alar nucleus 18, 81 al ansa lenticularis 26-31, 83, 95-97 alv alveus of the hippocampus 28-44, 82-89, 96-116 AM anteromedial thalamic nucleus 23-28, 80-82, 102-106 Amb ambiguus nucleus 66-75, 83, 90 AMV anteromedial thalamic nucleus, ventral part 23-27 Ang angular thalamic nucleus 30-31, 83, 106 AOB accessory olfactory bulb 2, 4, 81-83 AOD anterior olfactory nucleus, dorsal part 4-6, 82-83, 105-109 AOE anterior olfactory nucleus, external part 2-4, 82 AOL anterior olfactory nucleus, lateral part 2-6, 83-84, 104-105 AOM anterior olfactory nucleus, medial part 4-7, 80-81, 102-104 AOP anterior olfactory nucleus, posterior part 8-9, 80-83, 97-102 aopt accessory optic tract 41 aot accessory olfactory tract 28, 30 AOV anterior olfactory nucleus, ventral part 4-7, 81-83, 100-103 AP area postrema 74-76, 79, 96 APF anterior perifornical nucleus 21, 80 APir amygdalopiriform transition area 36-44, 89-94 APit anterior lobe of pituitary 79-83, 90 apmf ansoparamedian fissure 72-75, 83-84, 105-107 APT anterior pretectal nucleus 42-43, 107-109 APTD anterior pretectal nucleus, dorsal part 36-41, 82-84, 110-111 APTV anterior pretectal nucleus, ventral part 38-41, 83-84, 103-106 Aq aqueduct (Sylvius) 40-53, 79-80, 104-108 ar acoustic radiation 37-38 Arc arcuate hypothalamic nucleus 80, 90 ArcD arcuate nucleus, dorsal part 28-34 ArcL arcuate nucleus, lateral part 28-34 ArcLP arcuate hypothalamic nucleus, lateroposterior part 35-36 ArcM arcuate nucleus, medial part 28-34 ArcMP arcuate hypothalamic nucleus, medial posterior part 35-38, 79 as acoustic stria 83 asc7 ascending fibers of the facial nerve 65, 81-82, 93, 95 AStr amygdalostriatal transition area 23-26, 28-34, 88, 96-99
ATg anterior tegmental nucleus 50-52, 80, 98-99 Au1 primary auditory cortex 33-45, 106-115 AuD secondary auditory cortex, dorsal area 32-45, 109-116 AuV secondary auditory cortex, ventral area 32-45, 103-108 AV anteroventral thalamic nucleus 22, 28, 104-105 AVDM anteroventral thalamic nucleus, dorsomedial part 23-27, 8283, 106-110 AVPe anteroventral periventricular nucleus 18-20, 93-95 AVVL anteroventral thalamic nucleus, ventrolateral part 23-27, 8283, 106-110
B B basal nucleus (Meynert) 21-26, 28-32, 84-89, 96-104 B4 B4 serotonin cells 66-70 B9 B9 serotonin cells 46-51 BAC bed nucleus of the anterior commissure 21, 81, 102-103 BAOT bed nucleus of the accessory olfactory tract 26-29, 84, 90-91 Bar Barrington’s nucleus 56-60, 99-100 bas basilar artery 45-66, 79 BIC nucleus of the brachium of the inferior colliculus 46-52, 85-86, 104-109 bic brachium of the inferior colliculus 44-52, 86, 102-114 BL basolateral amygdaloid nucleus 32, 87, 92-93, 95 BLA basolateral amygdaloid nucleus, anterior part 25-33, 88-89, 9397 BLP basolateral amygdaloid nucleus, posterior part 29-39, 88-89, 9294 BLV basolateral amygdaloid nucleus, ventral part 29-31, 33-34, 89-92 BM basomedial amygdaloid nucleus 86, 90 BMA basomedial amygdaloid nucleus, anterior part 23-32, 86-88, 9193 BMP basomedial amygdaloid nucleus, posterior part 30-36, 87-89, 91-95 Bo Botzinger complex 67-68 bp brachium pontis (stem of middle cerebellar peduncle) 46-52, 9092 bsc brachium of the superior colliculus 36-48, 81-87, 106-112 BST bed nucleus of the stria terminalis 106-107 BSTIA bed nucleus of the stria terminalis, intraamygdaloid division
30-35, 87, 95-97 BSTL bed nucleus of the stria terminalis, lateral division 16-17, 82-83, 100 BSTLD bed nucleus of the stria terminalis, lateral division, dorsal part 18-19, 102-104 BSTLI bed nucleus of the stria terminalis, lateral division, intermediate part 20-21, 101 BSTLJ bed nucleus of the stria terminalis, lateral division, juxtacapsular part 18-20, 101-103 BSTLP bed nucleus of the stria terminalis, lateral division, posterior part 18-21, 101 BSTLV bed nucleus of the stria terminalis, lateral division, ventral part 18-20, 82, 98-99 BSTM bed nucleus of the stria terminalis, medial division 82, 99 BSTMA bed nucleus of the stria terminalis, medial division, anterior part 16-20, 81, 100-105 BSTMP bed nucleus of the stria terminalis, medial division, posterior part 81, 98-99 BSTMPI bed nucleus of the stria terminalis, medial division, posterointermediate part 21-22, 99-105 BSTMPL bed nucleus of the stria terminalis, medial division, posterolateral part 21-24, 96-97, 100-103 BSTMPM bed nucleus of the stria terminalis, medial division, posteromedial part 21-22, 81, 83, 100-105 BSTMV bed nucleus of the stria terminalis, medial division, ventral part 18-20, 98 BSTS bed nucleus of stria terminalis, supracapsular part 21, 83-85, 108-110 bv blood vessel 79, 85
C C1 C1 adrenaline cells 65-74, 82-83 C2 C2 adrenaline cells 69-73 C3 C3 adrenaline cells 66-71 CA1 field CA1 of hippocampus 29-47, 80-89, 96-116 CA2 field CA2 of hippocampus 29-44, 81-89, 96-116 CA3 field CA3 of hippocampus 25, 27-44, 80-89, 93-116 CB cell bridges of the ventral striatum 14-17, 82-83, 94-96 Cb cerebellum 55-57, 97, 100
CC central canal 74-79, 92-95 cc corpus callosum 16-38, 79-89, 113-116 Ce 88, 94 CeC central amygdaloid nucleus, capsular part 25-33, 87, 95-97 CeCv central cervical nucleus 117a,b CeL central amygdaloid nucleus, lateral division 26-33, 87, 97-98 CeM central amygdaloid nucleus, medial division 25-31, 86-87, 95-98 cg cingulum 11-43, 82-83, 107-116 Cg1 cingulate cortex, area 1 7-24, 79-82 Cg2 cingulate cortex, area 2 11-24, 79-81, 112-116 CGA central gray, alpha part 57-60, 79-80, 97 CGB central gray, beta part 57-60 CGG central gray, gamma part 60 CGPn central gray of the pons 58, 61, 81, 97 chp choroid plexus 57, 72, 98-99, 113-114 CI caudal interstitial nucleus of the medial longitudinal fasciculus 63-70, 79 CIC central nucleus of the inferior colliculus 54-58, 81-84, 106-115 cic commissure of the inferior colliculus 53-56, 79-81, 111-116 Cir circular nucleus 24, 94 CL centrolateral thalamic nucleus 28-35, 82, 105-110 Cl claustrum 7-27, 84-89, 98-112 CLi caudal linear nucleus of the raphe 44-50, 79-80, 96-100 cll commissure of the lateral lemniscus 52-54 CM central medial thalamic nucleus 24, 26-35, 79-80, 102-107 CnF cuneiform nucleus 52-55, 83, 102-106 Cop copula of the pyramis 67-77, 82-87, 99-108 cp cerebral peduncle, basal part 36-48, 81-86, 93-100 CPO caudal periolivary nucleus 61 CPu caudate putamen (striatum) 10-35, 82-89, 98-116 Crus1 crus 1 of the ansiform lobule 58-71, 83-89, 104-116 Crus2 crus 2 of the ansiform lobule 66-75, 83-89, 104-112, 114 csc commissure of the superior colliculus 40-45, 79-80, 109-110 CST nucleus of the commissural stria terminalis 20, 81, 102-103 cst commissural stria terminalis 26-31, 86-87, 93-97, 101 ctg central tegmental tract 39-50, 82, 104 Cu cuneate nucleus 70-78, 81-83, 96, 98-99 cu cuneate fasciculus 72-78, 81-82, 94, 96, 98 CVL caudoventrolateral reticular nucleus 71-78, 83, 90 CVRG caudoventral respiratory group 75-78
Cx cerebral cortex 58-59 CxA cortex-amygdala transition zone 18-29, 86-88, 90-93
D D dorsal nucleus 117a,b D3V dorsal 3rd ventricle 22-37, 79, 107-112 DA dorsal hypothalamic area 29-32, 80, 96-97 das dorsal acoustic stria 64-65 DC dorsal cochlear nucleus 61-66, 83-87, 96-100 DCIC dorsal cortex of the inferior colliculus 54-59, 79-83, 113-116 dcw deep cerebral white matter 111-116 DEn dorsal endopiriform nucleus 7-44, 82-89, 93-103 df dorsal fornix 18-39, 79-80, 114-116 DG dentate gyrus 25-31, 33-47, 79-89, 92-116 DHC nucleus of the dorsal hippocampal commissure 27-30 dhc dorsal hippocampal commissure 27-41, 79-82, 112-116 DI dysgranular insular cortex 11-31, 89, 101-105 Dk nucleus of Darkschewitsch 39-43, 80, 101-104 dl dorsolateral fasciculus 117a,b dlf dorsal longitudinal fasciculus 39-50, 106 DLG dorsal lateral geniculate nucleus 34-41, 86-88, 106-112 DLL dorsal nucleus of the lateral lemniscus 53-55, 84-85, 101-103 DLO dorsolateral orbital cortex 5-6, 107-113 dlo dorsal lateral olfactory tract 2-3 DLPAG dorsolateral periaqueductal gray 42-53, 81 DLPn dorsolateral pontine nucleus 51 DM dorsomedial hypothalamic nucleus 81, 90-93 DMC dorsomedial hypothalamic nucleus, compact part 32-33, 80, 94-95 DMD dorsomedial hypothalamic nucleus, dorsal part 30-34, 80, 9495 DMPAG dorsomedial periaqueductal gray 41-55, 79-80 DMPn dorsomedial pontine nucleus 51 DMSp5 dorsomedial spinal trigeminal nucleus 61-63, 68-71, 83-84, 96 DMSp5D dorsomedial spinal trigeminal nucleus, dorsal part 64-67 DMSp5V dorsomedial spinal trigeminal nucleus, ventral part 64-67 DMTg dorsomedial tegmental area 54-59, 80-81, 96-98 DMV dorsomedial hypothalamic nucleus, ventral part 33-34 Do dorsal hypothalamic nucleus 32
DP dorsal peduncular cortex 8-11, 79-81, 104-107 DpG deep gray layer of the superior colliculus 42-52, 80-83, 107-113 DPGi dorsal paragigantocellular nucleus 63-71, 80-81, 93-95 DpMe deep mesencephalic nucleus 40-52, 82-84, 101-106 DPO dorsal periolivary region 55-59, 83, 90 DPPn dorsal peduncular pontine nucleus 51 DpWh deep white layer of the superior colliculus 42-52, 80-81, 107110 DR dorsal raphe nucleus 48, 79, 98-99, 101-106 DRC dorsal raphe nucleus, caudal part 54-57, 100 DRD dorsal raphe nucleus, dorsal part 49-53 DRI dorsal raphe nucleus, interfascicular part 53-55 DRV dorsal raphe nucleus, ventral part 49-53 DRVL dorsal raphe nucleus, ventrolateral part 50-53, 80 Dsc lamina dissecans of the entorhinal cortex 47-54, 87-89, 107-108 dsc dorsal spinocerebellar tract 70-77, 90-94 DT dorsal terminal nucleus of the accessory optic tract 44-45 DTg dorsal tegmental nucleus 98 dtg dorsal tegmental bundle 40-55, 81, 102-103 DTgC dorsal tegmental nucleus, central part 56-57, 79-80, 100 DTgP dorsal tegmental nucleus, pericentral part 54-57, 79-80, 100101 dtgx dorsal tegmental decussation 44-47, 79-80, 100 DTM dorsal tuberomammillary nucleus 35-36, 92 DTr dorsal transition zone 7, 80 DTT dorsal tenia tecta 7-10, 80-81, 101-108
E E ependyma and subependymal layer 1-16, 81-82, 104 E5 ectotrigeminal nucleus 70-71, 86 ec external capsule 11-38, 85-89, 97-115 ECIC external cortex of the inferior colliculus 50-59, 81-85, 106-115 Ect ectorhinal cortex 31-57, 100-116 ECu external cuneate nucleus 66-75, 82-84, 98-100 EF epifascicular nucleus 67-69 ELm epilemniscal nucleus 42-43 eml external medullary lamina 26, 28-35, 84-87, 102-108 EPl external plexiform layer of the olfactory bulb 1-4, 80 EPlA external plexiform layer of the accessory olfactory bulb 3
ERS Eth EVe EW exc
epirubrospinal nucleus 50, 83, 97 ethmoid thalamic nucleus 38-39, 82-83, 102-105 nucleus of origin of efferents of the vestibular nerve 61, 96 Edinger-Westphal nucleus 40-47, 101-104 extreme capsule 11
F F nucleus of the fields of Forel 36-38, 82-83, 98-100 f fornix 18-39, 79-81, 92-110 FC fasciola cinereum 33, 40-41, 114-116 fi fimbria of the hippocampus 23-37, 83-89, 103-115 Fl flocculus 58-62, 87, 98-100 fmi forceps minor of the corpus callosum 7-12, 82-86, 107-116 fmj forceps major of the corpus callosum 42-52, 82-88, 113-116 fr fasciculus retroflexus 34-42, 80-81, 94-108 FrA frontal association cortex 4-5, 80-84, 114-116 Fu bed nucleus of stria terminalis, fusiform part 18-19 FVe F cell group of the vestibular complex 69-70
G g7 genu of the facial nerve 61-64, 80-81, 96 gcc genu of the corpus callosum 12-15, 79-81, 109-112 Ge5 gelatinous layer of the caudal spinal trigeminal nucleus 75, 83, 91-92 Gem gemini hypothalamic nucleus 35-38 GI granular insular cortex 9-31, 89, 102-108 Gi gigantocellular reticular nucleus 61-73, 79-82, 90-93 GiA gigantocellular reticular nucleus, alpha part 61-66, 79-81, 90 GiV gigantocellular reticular nucleus, ventral part 67-71, 79-81 Gl glomerular layer of the olfactory bulb 1-4 GlA glomerular layer of the accessory olfactory bulb 3 Gr gracile nucleus 74-80 gr gracile fasciculus 75-79 GrA granule cell layer of the accessory olfactory bulb 2-3, 82 GrC granular layer of the cochlear nuclei 62-65 GrDG granular layer of the dentate gyrus 35, 47, 87, 106 GrO granular cell layer of the olfactory bulb 1-4, 80
H hbc habenular commissure 36-39, 79, 110-112 HDB nucleus of the horizontal limb of the diagonal band 15-22, 8184, 91-96 hf hippocampal fissure 32-48, 81-88, 94-116 Hil hilus of the dentate gyrus 35, 45, 83, 85-87, 98, 106, 109-110, 114115
I I intercalated nuclei of the amygdala 25-26, 29-33, 86-88, 93-95 I3 interoculomotor nucleus 48 I5 intertrigeminal nucleus 56-58, 94-97 I8 interstitial nucleus of the vestibulocochlear nerve 60-61 ia internal arcuate fibers 75-76 IAD interanterodorsal thalamic nucleus 23-24, 26-27, 81, 105, 107 IAM interanteromedial thalamic nucleus 25-29, 79, 103-105 IBl inner blade of the dentate gyrus 36-37 ic internal capsule 18-38, 83-89, 96-110 icf intercrural fissure 66-71, 83-88, 104-107, 109-111 ICj islands of Calleja 9-20, 80-85, 91-96 ICjM islands of Calleja, major island 13-15, 80-81, 99-103 icp inferior cerebellar peduncle (restiform body) 60-72, 84-86, 94-101 IF interfascicular nucleus 40-43, 79, 96 IG indusium griseum 11-38, 79-81, 109-116 IGL intergeniculate leaf 36-39, 107-108 II intermediate interstitial nucleus of the medial longitudinal fasciculus 58-59 IL infralimbic cortex 8-10, 79-81, 106-111 ILL intermediate nucleus of the lateral lemniscus 51-53, 85, 99-100 IM intercalated amygdaloid nucleus, main part 27-28, 93 IMA intramedullary thalamic area 36-41 IMD intermediodorsal thalamic nucleus 29-34, 79, 105-108 IMG amygdaloid intramedullary gray 28-29 IML intermediolateral cell column 117a,b iml internal medullary lamina 27-35, 82, 105, 107 IMLF interstitial nucleus of the medial longitudinal fasciculus 39-45,
80, 102-104 IMLFG interstitial nucleus of medial longitudinal fasciculus, greater part 40-45, 81, 101-103 IMM intermediomedial cell column 117a,b imvc intermedioventral thalamic commissure 33, 103 In intercalated nucleus of the medulla 70-71, 80, 94-95 InCo intercollicular nucleus 49-52, 82-84, 107-110 Inf infracerebellar nucleus 64-65 InfS infundibular stem 34-36, 79 InG intermediate gray layer of the superior colliculus 42-52, 80-84, 107-114 InM intermedius nucleus of the medulla 74 IntA interposed cerebellar nucleus, anterior part 63-66, 82-85, 103106 IntDL interposed cerebellar nucleus, dorsolateral hump 65 IntDM interposed cerebellar nucleus, dorsomedial crest 65-66, 105 IntP interposed cerebellar nucleus, posterior part 66-67, 82-84, 101105 IntPPC interposed cerebellar nucleus, posterior parvicellular part 66 InWh intermediate white layer of the superior colliculus 42-52, 8084, 105, 107-114 IO inferior olive 79-81 IOA inferior olive, subnucleus A of medial nucleus 72-76 IOB inferior olive, subnucleus B of medial nucleus 72-76 IOBe inferior olive, beta subnucleus 72-76 IOC inferior olive, subnucleus C of medial nucleus 72-76 IOD inferior olive, dorsal nucleus 67-75, 82 IODM inferior olive, dorsomedial cell group 70-71 IOK inferior olive, cap of Kooy of the medial nucleus 74-76 IOM inferior olive, medial nucleus 67-71, 77-78 IOPr inferior olive, principal nucleus 67-73 IOVL inferior olive, ventrolateral protrusion 72-73 IP interpeduncular nucleus 80 IPA interpeduncular nucleus, apical subnucleus 46-48, 79, 95-96 IPAC interstitial nucleus of the posterior limb of the anterior commissure 16-17, 25-31, 83-84, 86-87, 96-100 IPACL interstitial nucleus of the posterior limb of the anterior commissure, lateral part 18-24 IPACM interstitial nucleus of the posterior limb of the anterior commissure, medial part 18-24 IPC interpeduncular nucleus, caudal subnucleus 42-48, 79, 93-95
IPDL interpeduncular nucleus, dorsolateral subnucleus 44-45, 95 IPDM interpeduncular nucleus, dorsomedial subnucleus 42-47 IPF interpeduncular fossa 40-41, 79-81, 94-95 IPI interpeduncular nucleus, intermediate subnucleus 44-48, 93-94 IPit intermediate lobe of pituitary 79-80, 90 IPL interpeduncular nucleus, lateral subnucleus 44-48, 93-95 IPl internal plexiform layer of the olfactory bulb 1-4 IPR interpeduncular nucleus, rostral subnucleus 42-45, 79, 93-95 IPRL interpeduncular nucleus, rostrolateral subnucleus 42-43, 94 ipt interpedunculotegmental tract 48-49 IRe infundibular reccess 79 IRt intermediate reticular nucleus 60-75, 77-78, 81-83, 90-95 IS inferior salivatory nucleus 60-66 IVF interventricular foramen 22, 106
J jx juxtarestiform body 63, 65 Jx5 juxtatrigeminal area 58
K KF Kˆlliker-Fuse nucleus 54-56, 94, 97-98
L LA lateroanterior hypothalamic nucleus 22-24, 80-81, 92-94 La lateral amygdaloid nu 95-98 lab longitudinal association bundle 30-31 LAcbSh lateral accumbens shell 11-15, 84-85, 96-97 LaDL lateral amygdaloid nucleus, dorsolateral part 26-36, 89, 99-100 Lat lateral (dentate) cerebellar nucleus 62-66, 85-86, 101-106 LatC lateral cervical nucleus 117a,b LatPC lateral cerebellar nucleus, parvicellular part 65-66, 85-86, 101102 LaVL lateral amygdaloid nucleus, ventrolateral part 30-34 LaVM lateral amygdaloid nucleus, ventromedial part 30-36, 89 LC locus coeruleus 56-62, 82, 98-100
LD laterodorsal thalamic nucleus 83, 111-112 Ld lambdoid septal zone 15-17, 79-81, 100-108 LDDM laterodorsal thalamic nucleus, dorsomedial part 28-33, 82, 109-110 LDTg laterodorsal tegmental nucleus 54-57, 80-81, 100-103 LDTgV laterodorsal tegmental nucleus, ventral part 54-55, 99, 101 LDVL laterodorsal thalamic nucleus, ventrolateral part 26-34, 84-86, 109-110 LEnt lateral entorhinal cortex 31-54, 87-89, 93-108 lfp longitudinal fasciculus of the pons 49-52, 80-83, 90-93 LGP lateral globus pallidus 18-33, 84-89, 98-108 LH lateral hypothalamic area 23-39, 81-83, 90-96, 98 LHb lateral habenular nucleus 28-31, 80, 109-110 LHbL lateral habenular nucleus, lateral part 32-36, 81 LHbM lateral habenular nucleus, medial part 32-36 Li linear nucleus of the medulla 69-70 ll lateral lemniscus 49-55, 82-85, 90-105 LM lateral mammillary nucleus 38-39, 81-82, 91-93 LMol lacunosum moleculare layer of the hippocampus 35, 87, 106 LO lateral orbital cortex 4-9, 82-87, 104-114 lo lateral olfactory tract 2-24, 81-89, 91-110 LOT nucleus of the lateral olfactory tract 22-26, 84-85, 90-93 LP lateral posterior thalamic nucleus 84, 86-87, 107-108, 111-112 LPAG lateral periaqueductal gray 41-55, 81 LPB lateral parabrachial nucleus 82-84, 99-103 LPBC lateral parabrachial nucleus, central part 54-58 LPBCr lateral parabrachial nucleus, crescent part 56-57 LPBD lateral parabrachial nucleus, dorsal part 56-57 LPBE lateral parabrachial nucleus, external part 54-58, 84 LPBI lateral parabrachial nucleus, internal part 56-57, 103-104 LPBS lateral parabrachial nucleus, superior part 54-55 LPBV lateral parabrachial nucleus, ventral part 56-60 LPGi lateral paragigantocellular nucleus 61-71, 81-83 LPLC lateral posterior thalamic nucleus, laterocaudal part 38-41 LPLR lateral posterior thalamic nucleus, laterorostral part 35-38, 85, 109-110 LPMC lateral posterior thalamic nucleus, mediocaudal part 38-43, 85-86, 109-111 LPMR lateral posterior thalamic nucleus, mediorostral part 32-38, 82-83, 109-110 LPn lateral pontine nucleus 51
LPO lateral preoptic area 18-22, 82-83, 92-97 LR4V lateral recess of the 4th ventricle 57-69, 83-87, 97-101 LRt lateral reticular nucleus 72-78, 82-84 LRtPC lateral reticular nucleus, parvicellular part 72-78, 84-85 LRtS5 lateral reticular nucleus, subtrigeminal part 72-75, 90 LSD lateral septal nucleus, dorsal part 12-22, 80-82, 108-114 LSI lateral septal nucleus, intermediate part 11-20, 80-82, 104-112 LSO lateral superior olive 55-60, 83-84 LSp lateral spinal nucleus 117a,b LSS lateral stripe of the striatum 10-24, 84, 86-88, 97-98 LSV lateral septal nucleus, ventral part 12-20, 81-82, 102-107 LT lateral terminal nucleus of the accessory optic tract 39-42, 87, 101102 LTer lemina terminalis 93 ltg lateral tegmental tract 45-49, 85, 104-105 LV lateral ventricle 10-38, 82-89, 94-116 LVe lateral vestibular nucleus 61-65, 83-84, 97-103 LVPO lateroventral periolivary nucleus 54-60, 90 lvs lateral vestibulospinal tract 63
M M1 primary motor cortex 7-34, 81-89, 112-116 M2 secondary motor cortex 6-34, 80-86, 114-116 m5 motor root of the trigeminal nerve 46-59, 84-85, 90-97 MA3 medial accessory oculomotor nucleus 40-43, 79-80, 101-103 mcer middle cerebral artery 81 mch medial corticohypothalamic tract 21-22, 98-101 MCLH magnocellular nucleus of the lateral hypothalamus 31-33, 83, 94-95 mcp middle cerebellar peduncle 49-60, 84-87, 93-102 MCPC magnocellular nucleus of the posterior commissure 39-41, 81, 105-106 MCPO magnocellular preoptic nucleus 18-25, 85, 93-95 MD mediodorsal thalamic nucleus 25-27, 35, 79, 81, 103-105, 109 MDC mediodorsal thalamic nucleus, central part 29-33, 106-108 MdD medullary reticular nucleus, dorsal part 74-78, 82-83, 91-95 MDL mediodorsal thalamic nucleus, lateral part 28-34, 81, 105-110 MDM mediodorsal thalamic nucleus, medial part 28-34, 80, 106-108 MDPL mediodorsal thalamic nucleus, paralaminar part 30
MdV medullary reticular nucleus, ventral part 74-78, 81-82, 90-93 ME median eminence 28, 79 Me medial amygdaloid nucleus 84, 86, 90, 92-95 Me5 mesencephalic trigeminal nucleus 46-60, 82-83, 99-108 me5 mesencephalic trigeminal tract 46-60, 81-83, 97-108 MeAD medial amygdaloid nucleus, anterodorsal part 23-31, 85, 96 MeAV medial amygdaloid nucleus, anteroventral part 28-29, 85, 91 Med medial (fastigial) cerebellar nucleus 66-67, 80-82, 101, 103-106 MedDL medial cerebellar nucleus, dorsolateral protuberance 66, 82, 107-108 MEE medial eminence, external layer 29-33 MEI medial eminence, internal layer 29-33 MEnt medial entorhinal cortex 46-57, 86-89, 97-114 MEntV medial entorhinal cortex, ventral part 45 MePD medial amygdaloid nucleus, posterodorsal part 30-35, 85-86, 95-97 MePV medial amygdaloid nucleus, posteroventral part 30-33, 85, 9092, 94 mfb medial forebrain bundle 22-39, 82-84, 92-97 mfba medial forebrain bundle, ‘a’ component 9-21, 81-85 mfbb medial forebrain bundle, ‘b’ component 15-21, 81-83 MG medial geniculate nucleus 46-47, 88 MGD medial geniculate nucleus, dorsal part 39-45, 86, 106-108 MGM medial geniculate nucleus, medial part 39-45, 85, 103-105 MGP medial globus pallidus 28-33, 84-86, 96-100 MGV medial geniculate nucleus, ventral part 39-45, 86-87, 102-106 MHb medial habenular nucleus 26-37, 79-80, 109-112 Mi mitral cell layer of the olfactory bulb 1-4 MiA mitral cell layer of the accessory olfactory bulb 3, 82 Min minimus nucleus 42-43 MiTg microcellular tegmental nucleus 48-52, 83-85, 100-104 ML medial mammillary nucleus, lateral part 37-39, 80, 91-93 ml medial lemniscus 32-75, 77, 79-85, 90-102 mlf medial longitudinal fasciculus 42-81, 91-103 MM medial mammillary nucleus, medial part 37-42, 79-80, 91-94 MMn medial mammillary nucleus, median part 37-38, 79, 91-93 MnA median accessory nucleus of the medulla 78 MnPO median preoptic nucleus 18-20, 79, 96-105 MnR median raphe nucleus 49-53, 79, 94-99 MO medial orbital cortex 4-7, 80, 106-114 Mo5 motor trigeminal nucleus 55, 58-59, 83-84, 94-98
Mo5DL motor trigeminal nucleus, dorsolateral part 56-57 Mo5VM motor trigeminal nucleus, ventromedial part 56-57 Mol molecular layer of the dentate gyrus 35, 79, 87, 106 mp mammillary peduncle 39-43, 80-81, 94-95 MPA medial preoptic area 18-23, 80-81, 93-97 MPB medial parabrachial nucleus 54-60, 83-84, 99-101 MPBE medial parabrachial nucleus external part 56-57 MPn medial pontine nucleus 51 MPO medial preoptic nucleus 23-24, 80, 92-97 MPOC medial preoptic nucleus, central part 21-22, 80 MPOL medial preoptic nucleus, lateral part 18-22 MPOM medial preoptic nucleus, medial part 21-22 MPT medial pretectal nucleus 38-41, 80, 109-110 MRe mammillary recess of the 3rd ventricle 36-38, 79 MRVL medial rostroventrolateral medulla 67-68 MS medial septal nucleus 13-18, 79-80, 103-108 MSO medial superior olive 54-60, 90 MT medial terminal nucleus of the accessory optic tract 40-41, 82, 9497 mt mammillothalamic tract 25-35, 39, 80-81, 94-104 mtg mammillotegmental tract 37-48, 80, 97 MTu medial tuberal nucleus 32-33, 82-83, 90-91 MVe medial vestibular nucleus 69-71, 80-81, 98-100 MVeMC medial vestibular nucleus, magnocellular part 60-68, 81-84, 96-98 MVePC medial vestibular nucleus, parvicellular part 61-68, 81-82, 97-99 MVPO medioventral periolivary nucleus 54-60, 82-83 MZMG marginal zone of the medial geniculate 40-44
N ns nigrostriatal bundle 26-39
O O nucleus O 58-59, 99 OB olfactory bulb 81, 110 Obex obex 77, 79
OBl outer blade of the dentate gyrus 36-37 oc olivocerebellar tract 70-74, 90-94 ocb olivocochlear bundle 58-61, 83, 85, 92, 96 ON olfactory nerve layer 1-3 Op optic nerve layer of the superior colliculus 42-52, 80-85, 111-114, 116 OPC oval paracentral thalamic nucleus 33-35, 103-105 OPT olivary pretectal nucleus 38-41, 81-83, 110-111 opt optic tract 26-41, 83-89, 91-111 Or oriens layer of the hippocampus 35, 87, 106 OT nucleus of the optic tract 39-44, 82-85, 109-112 OV olfactory ventricle (olfactory part of lateral ventricle) 1-9, 81-82, 103-104 ox optic chiasm 18-25, 79-82, 91-92
P P5 peritrigeminal zone 54-60, 83, 93-97 P7 perifacial zone 61-66, 82-84, 90-91 Pa paraventricular hypoth nucleus 94-96, 98-99 Pa4 paratrochlear nucleus 49-50, 81, 102 Pa5 paratrigeminal nucleus 70-73, 85, 97-98 Pa6 paraabducens nucleus 60-62, 80, 95 PaAM paraventricular hypothalamic nucleus, anterior magnocellular part 21-22, 80 PaAP paraventricular hypothalamic nucleus, anterior parvicellular part 21-25, 80 PaDC paraventricular hypothalamic nucleus, dorsal cap 26-27 PAG periaqueductal gray 39-40, 79-80, 104-114 PaLM paraventricular hypothalamic nucleus, lateral magnocellular part 26-27, 80, 97 PaMP paraventricular hypothalamic nucleus, medial parvicellular part 26-28, 97 PaPo paraventricular hypothalamic nucleus, posterior part 28-29, 8081, 97 PaR pararubral nucleus 42-45, 82-83, 100-102 PaS parasubiculum 45-57, 86-87, 98-116 PaV paraventricular hypothalamic nucleus, ventral part 26-27 PB parabrachial nucleus 102 PBG parabigeminal nucleus 48-52, 85, 100-103
PBP parabrachial pigmented nucleus 39-44, 80, 83, 98 PBW parabrachial nucleus, waist part 59 PC paracentral thalamic nucleus 23-34, 81-82, 103-105 pc posterior commissure 38-41, 79-81, 107-109 PC5 parvicellular motor trigeminal nucleus 54-55, 84, 95 pcf precommissural fornix 19, 21, 81, 109 PCGS paracochlear glial substance 58-60, 85, 98 PCom nucleus of the posterior commissure 39-41, 81, 107-109 PCRt parvicellular reticular nucleus 66-73, 82-84, 90-95 PCRtA parvicellular reticular nucleus, alpha part 60-65, 83-84, 91-96 PCTg paracollicular tegmentum 57-58, 83-84 pcuf preculminate fissure 60-65, 79-86, 106-108, 110-115 pd predorsal bundle 58-69, 79, 90-93 PDP posterodorsal preoptic nucleus 21, 98 PDTg posterodorsal tegmental nucleus 58-60, 79-80, 99 Pe periventricular hypothalamic nucleus 18-34, 79, 91-98 PeF perifornical nucleus 31-34, 82, 93-95 PF parafascicular thalamic nucleus 35-38, 80-82, 102-108 pf pyramidal fissure 75 PFl paraflocculus 57-68, 88-89, 94-103 pfs parafloccular sulcus 60-64, 89 PH posterior hypothalamic area 33-38, 79-80, 94-99 Pi pineal gland 53, 79-80 PIL posterior intralaminar thalamic nucleus 39-44, 85, 101-102 Pir piriform cortex 7-24, 27-38, 82-107 PiRe pineal recess 38-41, 79, 113 PL paralemniscal nucleus 49-53, 84, 96-100 PLCo posterolateral cortical amygdaloid nucleus (C2) 29-38, 87-91 PLd paralambdoid septal nucleus 16-17, 81 plf posterolateral fissure 58-62, 67-73, 79-82 PLi posterior limitans thalamic nucleus 39-43, 105-108 PM paramedian lobule 69-77, 83-87, 101-105, 107-108 pm principal mammillary tract 37-38 PMCo posteromedial cortical amygdaloid nucleus (C3) 32-44, 85-93 PMD premammillary nucleus, dorsal part 36-37, 80-81, 91-93 PMn paramedian reticular nucleus 70-76, 80, 90-91 PMnR paramedian raphe nucleus 50-53, 79-80, 94-99 pms paramedian sulcus 70-76 PMV premammillary nucleus, ventral part 35-36, 81-82, 90-93 PN paranigral nucleus 40-43, 80 Pn pontine nuclei 46-50, 52, 79-83, 90-93
PnC pontine reticular nucleus, caudal part 56-61, 80-82, 90-95 PnO pontine reticular nucleus, oral part 49-55, 81-83, 91-98 PnR pontine raphe nucleus 54-57, 79, 95-97 PnV pontine reticular nucleus, ventral part 56-60, 79-81, 90 Po posterior thalamic nuclear group 30-38, 83-85, 103-109 PoDG polymorph layer of the dentate gyrus 30-45, 80, 82, 86, 88, 98115 PoMn posteromedian thalamic nucleus 35, 79, 104-105 Post postsubiculum 42-53, 83-86 PoT posterior thalamic nuclear group, triangular part 39-43, 103-104 PP peripeduncular nucleus 40-44, 86, 101 ppf prepyramidal fissure 70-76, 79-85, 102-103, 105-107, 109 PPit posterior lobe of pituitary 79-80, 90 PPT posterior pretectal nucleus 40-43, 81-84, 110-111 PPTg pedunculopontine tegmental nucleus 46-53, 82-84, 97-104 PPy parapyramidal nucleus 62-66 PR prerubral field 36-40, 82 Pr prepositus nucleus 63-69, 80, 96-98 Pr5 principal sensory trigeminal nucleus 54, 91 Pr5DM principal sensory trigeminal nucleus, dorsomedial part 5760, 85, 95-98 Pr5VL principal sensory trigeminal nucleus, ventrolateral part 55-61, 85, 92-97 prb Probst’s bundle 60-62 PrBo pre-Bˆtzinger complex 69 PrC precommissural nucleus 37-38, 80-81, 106-108 prf primary fissure 58-68, 79-88, 104-116 PRh perirhinal cortex 31-57, 88, 98-115 PrL prelimbic cortex 5-10, 79-82, 109-116 ProS prosubiculum 106 PrS presubiculum 45-51, 87-89, 98-116 PS parastrial nucleus 18-20, 81-82, 98-99 psf posterior superior fissure 59-66, 79-89, 104-107, 109-113, 115 PSol parasolitary nucleus 72-74 PSTh parasubthalamic nucleus 35-36 PT paratenial thalamic nucleus 22-27, 79-81, 104-108 PtA parietal association cortex 35-43, 82-88 PV paraventricular thalamic nucleus 29-31, 79, 108 pv periventricular fiber system 36-38, 107 PVA paraventricular thalamic nucleus, anterior part 22-28, 79-80, 101-110
PVP paraventricular thalamic nucleus, posterior part 32-38, 79-80, 105-108 Py pyramidal cell layer of the hippocampus 35, 87, 106 py pyramidal tract 53-76, 79-81, 117a,b pyx pyramidal decussation 77-80
R R red nucleus 43, 65, 67, 72, 81-82, 98, 100-101 Rad stratum radiatum of the hippocampus 35, 87, 106, 112, 114 RAmb retroambiguus nucleus 76-78 Rbd rhabdoid nucleus 47-53, 79, 97-100 rcc rostrum of the corpus callosum 10 RCh retrochiasmatic area 25-27, 80, 90 Re reuniens thalamic nucleus 23-33, 79-80, 98-103 ReIC recess of the inferior colliculus 54-57, 79, 109-115 REth retroethmoid nucleus 40-41, 84, 101-103 rf rhinal fissure 4-50, 52, 80-89, 100-110 Rh rhomboid thalamic nucleus 25-32, 79-80, 100-103 RI rostral interstitial nucleus of medial longitudinal fasciculus 37-39, 80-81, 96-103 ri rhinal incisura 6-8 RIP raphe interpositus nucleus 57-59, 91 RL retrolemniscal nucleus 56, 85, 103 RLH red nucleus, lateral horn 99 RLi rostral linear nucleus of the raphe 40-44, 79, 97-100 RMC red nucleus, magnocellular part 42, 44-45, 99 RMg raphe magnus nucleus 56-66, 79-80 Ro nucleus of Roller 70-75, 80, 93 ROb raphe obscurus nucleus 65-77, 79, 90-93 RPa raphe pallidus nucleus 59-77, 79 RPC red nucleus, parvicellular part 41-42, 44-45, 99 RPO rostral periolivary region 52-54, 83-84, 90 RR retrorubral nucleus 48-50, 84, 97-99 RRF retrorubral field 45-48, 81-84, 97-100 rs rubrospinal tract 45-78, 82-85, 90-96 RSA retrosplenial agranular cortex 25-57, 79-86, 115-116 RSGa retrosplenial granular a cortex 42-53, 80-84 RSGb retrosplenial granular b cortex 25-51, 79-82 Rt reticular thalamic nucleus 23-36, 81-85, 87-88, 99-110
RtTg reticulotegmental nucleus of the pons 49-57, 79-81, 90-96 RtTgP reticulotegmental nucleus of the pons, pericentral part 50-53, 80-81, 93 RVL rostroventrolateral reticular nucleus 66, 68-71, 73-75, 83-84, 90 RVRG rostral ventral respiratory group 70-75
S S subiculum 41-49, 81-89, 94-116 S1 primary somatosensory cortex 25-28, 37-38 S1BF primary somatosensory cortex, barrel field 18-36, 87-89, 110, 112-116 S1DZ primary somatosensory cortex, dysgranular region 13-33, 86 S1FL primary somatosensory cortex, forelimb region 13-28, 85-87 S1HL primary somatosensory cortex, hindlimb region 18-28, 83-84 S1J primary somatosensory cortex, jaw region 9-16, 87-89, 108-116 S1JO primary somatosensory cortex, jaw region, oral surface 12-15 S1Tr primary somatosensory cortex, trunk region 29-34, 83-86 S1ULp primary somatosensory cortex, upper lip region 13-17, 89, 109-116 S2 secondary somatosensory cortex 16-34, 104-114 s5 sensory root of the trigeminal nerve 45-58, 85-86, 90-93 Sag sagulum nucleus 54-56, 85, 104-106 SC superior colliculus 41, 79, 106 Sc scaphoid thalamic nucleus 38, 83, 103-104 sc spinocerebellar tract 78 scc splenium of the corpus callosum 39-41, 79-82 SCh suprachiasmatic nucleus 22-24, 80, 91 SCO subcommissural organ 38-39, 79, 108-110 SCom subcommissural nucleus 39, 104 scp superior cerebellar peduncle (brachium conjunctivum) 30-46, 5264, 80-84, 98-102 scpd superior cerebellar peduncle, descending limb 57-58, 98 sf secondary fissure 70-77, 79-82 SFi septofimbrial nucleus 18-22, 80-81, 107-110 SFO subfornical organ 21-25, 79-80, 107-112 SG suprageniculate thalamic nucleus 39-45, 85, 106-108 SGe supragenual nucleus 61-62, 80, 97 SGl superficial glial zone of the cochlear nuclei 58, 60-61 SHi septohippocampal nucleus 10-17, 79, 101-112
SI substantia innominata 17, 24-29, 81-82, 84-86, 94-99 SIB substantia innominata, basal part 16-23, 83 SID substantia innominata, dorsal part 21-23 Sim simple lobule 57-66, 82-87, 89, 104-116 SimA simple lobule A 60 SimB simple lobule B 60 simf simplex fissure 61-63, 66 SIV substantia innominata, ventral part 22-23 SL semilunar nucleus 9-11, 80, 98-102 slim sulcus limitans 99 SM nucleus of the stria medullaris 23-24, 82-83, 96-100 sm stria medullaris of the thalamus 21-36, 80-83, 96-112 SMT submammillothalamic nucleus 36-37, 81, 94-95 SMV superior medullary velum 56-65, 79-81, 101-108 SNC substantia nigra, compact part 94-95 SNCD substantia nigra, compact part, dorsal tier 39-45, 82-85, 96-100 SNCV substantia nigra, compacta part, ventral tier 44 SNL substantia nigra, lateral part 40-44, 85-86, 99-100 SNM substantia nigra, medial part 40, 42-44 SNR substantia nigra, reticular part 38-39, 41-45, 82-85, 94-100 SNRDM substantia nigra, reticular part, dorsomedial tier 40 SNRVL substantia nigra, reticular part, ventrolateral tier 40 SO supraoptic nucleus 21-27, 81-83, 91-93 Sol nucleus of the solitary tract 63, 77-78, 80, 93-97 sol solitary tract 65-78, 81-82, 94, 96 SolC nucleus of the solitary tract, commissural part 74-80, 93-95 SolCe nucleus of the solitary tract, central part 72-74 SolDM nucleus of the solitary tract, dorsomedial part 72-76 SolG nucleus of the solitary tract, gelatinous part 72-73, 81 SolI nucleus of the solitary tract, interstitial part 72-76 SolIM nucleus of the solitary tract, intermediate part 65-76, 82-83 SolM nucleus of the solitary tract, medial part 66-76, 81-82 SolRL nucleus of the solitary tract, rostrolateral part1-10 64-66 SolVL nucleus of the solitary tract, ventrolateral part 66-76, 82-83 SOR supraoptic nucleus, retrochiasmatic part 28-32, 82-83, 90 sox supraoptic decussation 25-38, 79-87, 90-100 sp5 spinal trigeminal tract 59-78, 83-86, 90-98 Sp5C spinal trigeminal nucleus, caudal part 74-78, 83-85, 90-96 Sp5I spinal trigeminal nucleus, interpolar part 67-75, 84-86, 90-97 Sp5O spinal trigeminal nucleus, oral part 61-66, 85-86, 90-96 SPa subparaventricular zone of the hypothalamus 26-28
SPF subparafascicular thalamic nucleus 35-36, 80-81, 100 SPFPC subparafascicular thalamic nucleus, parvicellular part 37-41, 82-84, 101-102 Sph sphenoid nucleus 58-59, 79-80, 100 SPO superior paraolivary nucleus 54-60, 82 SPTg subpedencular tegmental nucleus 50-53, 81-82, 99-100 SpVe spinal vestibular nucleus 64-69, 82-84, 97-100 st stria terminalis 18-35, 82-89, 95-110 StA strial part of the preoptic area 18-20, 98-99 Stg stigmoid hypothalamic nucleus 28-29 STh subthalamic nucleus 34-37, 83-85, 95-99 StHy striohypothalamic nucleus 21-22, 80-81, 96-97 str superior thalamic radiation 36-39, 84-87, 105-109 Su3 supraoculomotor periaqueductal gray 44-49, 79-80, 104 Su3C supraoculomotor cap 44-49, 104 Su5 supratrigeminal nucleus 55-58, 83, 98 Sub submedius thalamic nucleus 26-29, 32, 80, 100-103 SubB subbrachial nucleus 45-49, 84-86, 101-103 SubC subcoeruleus nucleus 95 SubCA subcoeruleus nucleus, alpha part 56-59, 82, 97-100 SubCD subcoeruleus nucleus, dorsal part 54-59, 82-83, 96-97 SubCV subcoeruleus nucleus, ventral part 54-59, 83, 90-94 SubD submedius thalamic nucleus, dorsal part 30-31, 79, 81 SubG subgeniculate nucleus 36-38, 87-88, 100-104 SubI subincertal nucleus 30-34, 82-83, 96-97 SubV submedius thalamic nucleus, ventral part 30-31, 79, 81, 99 SuG superficial gray layer of the superior colliculus 42-52, 79-84, 111116 SuM supramammillary nucleus 36-38, 79-81, 94-95 SuML supramammillary nucleus, lateral part 39 SuMM supramammillary nucleus, medial part 39 sumx supramammillary decussation 37-39, 79, 96 SuS superior salivatory nucleus 61-63 SuVe superior vestibular nucleus 60-64, 83-84, 98-101
T TC tuber cinereum area 28-33, 81, 90-93 Te terete hypothalamic nucleus 33-35, 90-91 TeA temporal association cortex 35-54, 102-116
tfp transverse fibers of the pons 45-52, 79-83, 90-92 TM tuberomammillary nu 81, 90-92 TS triangular septal nucleus 21-26, 79-81, 105-114 ts tectospinal tract 46-79, 81, 95-98, 102, 105 tth trigeminothalamic tract 47-62 Tu olfactory tubercle 8, 10-21, 80-86, 90-98 TuDC olfactory tubercle densocellular layer 9 TuPl olfactory tubercle plexiform layer 9 TuPo olfactory tubercle polymorph layer 9 Tz nucleus of the trapezoid body 53-60, 81-82, 90 tz trapezoid body 53-64, 79-87, 90-95
U uf uvular fissure 72, 80 unc uncinate fasciculus 60-62
V V1B primary visual cortex, binocular area 42-57, 85-88 V1M primary visual cortex, monocular area 42-57, 81-86 V2L secondary visual cortex, lateral area 39-57, 86-89, 113-116 V2ML secondary visual cortex, mediolateral area 38-47, 84-86 V2MM secondary visual cortex, mediomedial area 37-53, 81-83 VA ventral anterior thalamic nucleus 25-28, 82-83, 101-105 vaf ventral amygdalofugal pathway 28 VC ventral cochlear nucleus 96 VCA ventral cochlear nucleus, anterior part 55-62, 86-87, 93-100 VCP ventral cochlear nucleus, posterior part 62-65, 86-87, 93-97 VDB nucleus of the vertical limb of the diagonal band 12-17, 79-80, 97-102 VeCb vestibulocerebellar nucleus 63-65, 82, 101-102 veme vestibulomesencephalic tract 60 VEn ventral endopiriform nucleus 18-34, 87-89, 91-97 vhc ventral hippocampal commissure 21-25, 79-82, 108-113 VL ventrolateral thalamic nucleus 28-32, 65, 67, 72, 82-84, 101-108 VLG ventral lateral geniculate nucleus 34-35 VLGMC ventral lateral geniculate nucleus, magnocellular part 36-39, 87-88, 103-108
VLGPC ventral lateral geniculate nucleus, parvicellular part 36-39, 87-88, 104-107 VLH ventrolateral hypothalamic nucleus 22-24, 82-83, 93 VLL ventral nucleus of the lateral lemniscus 50-53, 83-85, 90-98 VLPAG ventrolateral periaqueductal gray 50-54, 81 VLPO ventrolateral preoptic nucleus 19-21, 82 VLTg ventrolateral tegmental area 52-53, 82-83, 91-93 VM ventromedial thalamic nucleus 26-35, 81-83, 98-102 VMH ventromedial hypothalamic nucleus 80-81, 90-92 VMHA ventromedial hypothalamic nucleus, anterior part 28 VMHC ventromedial hypothalamic nucleus, central part 29-34 VMHDM ventromedial hypothalamic nucleus, dorsomedial part 2933 VMHVL ventromedial hypothalamic nucleus, ventrolateral part 2934 VMPn ventromedial pontine nucleus 51 VMPO ventromedial preoptic nucleus 18-20, 80, 93 VN vomeronasal nerve layer 3 vn vomeronasal nerve 2 VO ventral orbital cortex 4-10, 81-86, 88, 102-114 VOLT vascular organ of the lamina terminalis 79, 95 VP ventral pallidum 10-22, 81-85, 91-99 VPL ventral posterolateral thalamic nucleus 28-37, 84-87, 100-108 VPM ventral posteromedial thalamic nucleus 29-38, 83-86, 101-108 VPPC ventral posterior thalamic nucleus, parvicellular part 34-37, 81-82, 101-102 VPPn ventral peduncular pontine nucleus 51 VRe ventral reuniens thalamic nucleus 24-33, 80, 98-101 vsc ventral spinocerebellar tract 53-77, 83-85, 96-103 VTA ventral tegmental area 40-47, 80-82, 95-98 VTg ventral tegmental nucleus 53-55, 80, 99-100 vtgx ventral tegmental decussation 40-45, 79-81, 96, 98 VTM ventral tuberomammillary nucleus 35-38, 82, 90 VTRZ visual tegmental relay zone 40-42, 80, 98 VTT ventral tenia tecta 6-8, 80-81, 98-101
X X nucleus X 64-71, 83, 85, 97, 99 Xi xiphoid thalamic nucleus 26-29, 97
xscp decussation of the superior cerebellar peduncle 46-52, 79-81, 97100
Y Y nucleus Y 63-65, 85, 101
Z Z nucleus Z 72 ZI zona incerta 25-31, 40, 81-83, 97-101 ZID zona incerta, dorsal part 32-39, 84-86, 99-103 ZIV zona incerta, ventral part 32-39, 84-86, 98-99 ZL zona limitans 15-18 Zo zonal layer of the superior colliculus 42-52, 79-85, 111-116
List of Structures Names of the structures are listed in alphabetical order. Each name is followed by abbreviation of the structure. 3rd ventricle 3V 4th ventricle 4V
A A1 noradrenaline cells A1 A2 noradrenaline cells A2 A4 noradrenaline cells A4 A5 noradrenaline cells A5 A7 noradrenaline cells A7 A8 dopamine cells A8 A11 dopamine cells A11 A13 dopamine cells A13 abducens nucleus 6 accessory abducens nucleus Acs6 accessory abducens/facial nucleus Acs6/7 accessory facial nucleus Acs7 accessory neurosecretory nuclei Acc accessory olfactory bulb AOB accessory olfactory tract aot accessory optic tract aopt accessory trigeminal nucleus Acs5 accumbens nucleus, core AcbC accumbens nucleus, shell AcbSh acoustic radiation ar acoustic stria as agranular insular cortex AI agranular insular cortex, dorsal part AID agranular insular cortex, posterior part AIP agranular insular cortex, ventral part AIV alar nucleus Al alveus of the hippocampus alv ambiguus nucleus Amb
amygdalohippocampal area, anterolateral part AHiAL amygdalohippocampal area, posteromedial part AHiPM amygdaloid fissure af amygdaloid intramedullary gray IMG amygdalopiriform transition area APir amygdalostriatal transition area AStr angular thalamic nucleus Ang ansa lenticularis al ansoparamedian fissure apmf anterior amygdaloid area AA anterior amygdaloid area, dorsal part AAD anterior amygdaloid area, ventral part AAV anterior commissure ac anterior commissure, anterior part aca anterior commissure, intrabulbar part aci anterior commissure, posterior part acp anterior cortical amygdaloid nucleus ACo anterior hypothalamic area AH anterior hypothalamic area AHi anterior hypothalamic area, anterior part AHA anterior hypothalamic area, central part AHC anterior hypothalamic area, posterior part AHP anterior lobe of pituitary APit anterior olfactory nucleus, dorsal part AOD anterior olfactory nucleus, external part AOE anterior olfactory nucleus, lateral part AOL anterior olfactory nucleus, medial part AOM anterior olfactory nucleus, ventral part AOV anterior perifornical nucleus APF anterior pretectal nucleus APT anterior pretectal nucleus, dorsal part APTD anterior pretectal nucleus, ventral part APTV anterior tegmental nucleus ATg anterodorsal preoptic nucleus ADP anterodorsal thalamic nucleus AD anteromedial thalamic nucleus AM
anteromedial thalamic nucleus, ventral part AMV anteroventral periventricular nucleus AVPe anteroventral thalamic nucleus AV anteroventral thalamic nucleus, dorsomedial part AVDM anteroventral thalamic nucleus, ventrolateral part AVVL aqueduct (Sylvius) Aq arcuate hypothalamic nucleus Arc arcuate hypothalamic nucleus, lateroposterior part ArcLP arcuate hypothalamic nucleus, medial posterior part ArcMP arcuate nucleus, dorsal part ArcD arcuate nucleus, lateral part ArcL arcuate nucleus, medial part ArcM area postrema AP artery a ascending fibers of the facial nerve asc7
B B4 serotonin cells B4 B9 serotonin cells B9 Barrington’s nucleus Bar basal nucleus (Meynert) B basilar artery bas basolateral amygdaloid nucleus BL basolateral amygdaloid nucleus, anterior part BLA basolateral amygdaloid nucleus, posterior part BLP basolateral amygdaloid nucleus, ventral part BLV basomedial amygdaloid nucleus BM basomedial amygdaloid nucleus, anterior part BMA basomedial amygdaloid nucleus, posterior part BMP
bed nucleus of stria terminalis, fusiform part Fu bed nucleus of stria terminalis, supracapsular part BSTS bed nucleus of the accessory olfactory tract BAOT bed nucleus of the anterior commissure BAC bed nucleus of the stria terminalis BST bed nucleus of the stria terminalis, intraamygdaloid division BSTIA bed nucleus of the stria terminalis, lateral division BSTL bed nucleus of the stria terminalis, lateral division, dorsal part BSTLD bed nucleus of the stria terminalis, lateral division, intermediate part BSTLI bed nucleus of the stria terminalis, lateral division, juxtacapsular part BSTLJ bed nucleus of the stria terminalis, lateral division, posterior part BSTLP bed nucleus of the stria terminalis, lateral division, ventral part BSTLV bed nucleus of the stria terminalis, medial division BSTM bed nucleus of the stria terminalis, medial division, anterior part BSTMA bed nucleus of the stria terminalis, medial division, posterior part BSTMP bed nucleus of the stria terminalis, medial division, posterointermediate part BSTMPI bed nucleus of the stria terminalis, medial division, posterolateral part BSTMPL bed nucleus of the stria terminalis, medial division, posteromedial part BSTMPM bed nucleus of the stria terminalis, medial division, ventral part BSTMV blood vessel bv Botzinger complex Bo brachium of the inferior colliculus bic brachium of the superior colliculus bsc
brachium pontis (stem of middle cerebellar peduncle) bp
C C1 adrenaline cells C1 C2 adrenaline cells C2 C3 adrenaline cells C3 caudal interstitial nucleus of the medial longitudinal fasciculus CI caudal linear nucleus of the raphe CLi caudal periolivary nucleus CPO caudate putamen (striatum) CPu caudoventral respiratory group CVRG caudoventrolateral reticular nucleus CVL cell bridges of the ventral striatum CB central amygdaloid nucleus, capsular part CeC central amygdaloid nucleus, lateral division CeL central amygdaloid nucleus, medial division CeM central canal CC central cervical nucleus CeCv central gray of the pons CGPn central gray, alpha part CGA central gray, beta part CGB central gray, gamma part CGG central medial thalamic nucleus CM central nucleus of the inferior colliculus CIC central tegmental tract ctg centrolateral thalamic nucleus CL cerebellar lobule 6a cerebellar lobule 6b cerebellar lobule 6c cerebellar lobules 2&3 cerebellar lobules 4&5 cerebellum Cb cerebral cortex Cx cerebral peduncle, basal part cp
choroid plexus chp cingulate cortex, area 1 Cg1 cingulate cortex, area 2 Cg2 cingulum cg circular nucleus Cir claustrum Cl cochlear root of the vestibulocochlear nerve 8cn commissural stria terminalis cst commissure of the inferior colliculus cic commissure of the lateral lemniscus cll commissure of the superior colliculus csc copula of the pyramis Cop corpus callosum cc cortex-amygdala transition zone CxA cortical or spinal cord layers, cerebellar folia or cranial nerve nuclei 1-10 crus 1 of the ansiform lobule Crus1 crus 2 of the ansiform lobule Crus2 cuneate fasciculus cu cuneate nucleus Cu cuneiform nucleus CnF
D decussation of the superior cerebellar peduncle xscp deep cerebral white matter dcw deep gray layer of the superior colliculus DpG deep mesencephalic nucleus DpMe deep white layer of the superior colliculus DpWh dentate gyrus DG dorsal 3rd ventricle D3V dorsal acoustic stria das dorsal cochlear nucleus DC dorsal cortex of the inferior colliculus DCIC dorsal endopiriform nucleus DEn dorsal fornix df
dorsal hippocampal commissure dhc dorsal hypothalamic area DA dorsal hypothalamic nucleus Do dorsal lateral geniculate nucleus DLG dorsal lateral olfactory tract dlo dorsal longitudinal fasciculus dlf dorsal motor nucleus of vagus 10 dorsal nucleus of the lateral lemniscus DLL dorsal paragigantocellular nucleus DPGi dorsal peduncular cortex DP dorsal peduncular pontine nucleus DPPn dorsal periolivary region DPO dorsal raphe nucleus DR dorsal raphe nucleus, caudal part DRC dorsal raphe nucleus, dorsal part DRD dorsal raphe nucleus, interfascicular part DRI dorsal raphe nucleus, ventral part DRV dorsal raphe nucleus, ventrolateral part DRVL dorsal spinocerebellar tract dsc dorsal tegmental bundle dtg dorsal tegmental decussation dtgx dorsal tegmental nucleus DTg dorsal tegmental nucleus, central part DTgC dorsal tegmental nucleus, pericentral part DTgP dorsal tenia tecta DTT dorsal terminal nucleus of the accessory optic tract DT dorsal transition zone DTr dorsal tuberomammillary nucleus DTM dorsolateral fasciculus d1 dorsolateral orbital cortex DLO dorsolateral periaqueductal gray DLPAG dorsolateral pontine nucleus DLPn dorsomedial hypothalamic nucleus DM dorsomedial hypothalamic nucleus, compact part DMC dorsomedial hypothalamic nucleus, dorsal part DMD
dorsomedial hypothalamic nucleus, ventral part DMV dorsomedial periaqueductal gray DMPAG dorsomedial pontine nucleus DMPn dorsomedial spinal trigeminal nucleus DMSp5 dorsomedial spinal trigeminal nucleus, dorsal part DMSp5D dorsomedial spinal trigeminal nucleus, ventral part DMSp5V dorsomedial tegmental area DMTg dysgranular insular cortex DI
E ectorhinal cortex Ect ectotrigeminal nucleus E5 Edinger-Westphal nucleus EW entorhinal cortex Ent ependyma and subependymal layer E epifascicular nucleus EF epilemniscal nucleus ELm epirubrospinal nucleus ERS ethmoid thalamic nucleus Eth external capsule ec external cortex of the inferior colliculus ECIC external cuneate nucleus ECu external medullary lamina eml external plexiform layer of the accessory olfactory bulb EPlA external plexiform layer of the olfactory bulb EPl extreme capsule exc
F F cell group of the vestibular complex FVe facial nerve or its root 7n facial nucleus 7
facial nucleus, dorsal intermediate subnucleus 7DI facial nucleus, dorsolateral subnucleus 7DL facial nucleus, dorsomedial subnucleus 7DM facial nucleus, lateral subnucleus 7L facial nucleus, ventral intermediate subnucleus 7VI facial nucleus, ventromedial subnucleus 7VM fasciculus retroflexus fr fasciola cinereum FC field CA1 of hippocampus CA1 field CA2 of hippocampus CA2 field CA3 of hippocampus CA3 fimbria of the hippocampus fi flocculus Fl forceps major of the corpus callosum fmj forceps minor of the corpus callosum fmi fornix f frontal association cortex FrA
G gelatinous layer of the caudal spinal trigeminal nucleus Ge5 gemini hypothalamic nucleus Gem genu of the corpus callosum gcc genu of the facial nerve g7 gigantocellular reticular nucleus Gi gigantocellular reticular nucleus, alpha part GiA gigantocellular reticular nucleus, ventral part GiV glomerular layer of the olfactory bulb Gl gracile fasciculus gr gracile nucleus Gr granular cell layer of the olfactory bulb GrO granular insular cortex GI granular layer of the cochlear nuclei GrC granular layer of the dentate gyrus GrDG
granule cell layer of the accessory olfactory bulb GrA
H habenular commissure hbc hilus of the dentate gyrus Hil hippocampal fissure hf hypoglossal nucleus 12
I indusium griseum IG inferior cerebellar peduncle (restiform body) icp inferior olive IO inferior olive, beta subnucleus IOBe inferior olive, cap of Kooy of the medial nucleus IOK inferior olive, dorsal nucleus IOD inferior olive, dorsomedial cell group IODM inferior olive, medial nucleus IOM inferior olive, principal nucleus IOPr inferior olive, subnucleus A of medial nucleus IOA inferior olive, subnucleus B of medial nucleus IOB inferior olive, subnucleus C of medial nucleus IOC inferior olive, ventrolateral protrusion IOVL inferior salivatory nucleus IS infracerebellar nucleus Inf infralimbic cortex IL infundibular reccess IRe infundibular stem InfS inner blade of the dentate gyrus IBl interanterodorsal thalamic nucleus IAD interanteromedial thalamic nucleus IAM intercalated amygdaloid nucleus, main part
IM intercalated nuclei of the amygdala I intercalated nucleus of the medulla In intercollicular nucleus InCo intercrural fissure icf interfascicular nucleus IF intergeniculate leaf IGL intermediate gray layer of the superior colliculus InG intermediate interstitial nucleus of the medial longitudinal fasciculus II intermediate lobe of pituitary IPit intermediate nucleus of the lateral lemniscus ILL intermediate reticular nucleus IRt intermediate white layer of the superior colliculus InWh intermediodorsal thalamic nucleus IMD intermediolateral cell column IML intermediomedial cell column IMM intermedioventral thalamic commissure imvc intermedius nucleus of the medulla InM internal arcuate fibers ia internal capsule ic internal medullary lamina iml internal plexiform layer of the olfactory bulb IPl interoculomotor nucleus I3 interpeduncular fossa IPF interpeduncular nucleus IP interpeduncular nucleus, apical subnucleus IPA interpeduncular nucleus, caudal subnucleus IPC interpeduncular nucleus, dorsolateral subnucleus IPDL interpeduncular nucleus, dorsomedial subnucleus IPDM interpeduncular nucleus, intermediate subnucleus IPI
interpeduncular nucleus, lateral subnucleus IPL interpeduncular nucleus, rostral subnucleus IPR interpeduncular nucleus, rostrolateral subnucleus IPRL interpedunculotegmental tract ipt interposed cerebellar nucleus, anterior part IntA interposed cerebellar nucleus, dorsolateral hump IntDL interposed cerebellar nucleus, dorsomedial crest IntDM interposed cerebellar nucleus, posterior part IntP interposed cerebellar nucleus, posterior parvicellular part IntPPC interstitial nucleus of medial longitudinal fasciculus, greater part IMLFG interstitial nucleus of the medial longitudinal fasciculus IMLF interstitial nucleus of the posterior limb of the anterior commissure IPAC interstitial nucleus of the posterior limb of the anterior commissure, lateral part IPACL interstitial nucleus of the posterior limb of the anterior commissure, medial part IPACM interstitial nucleus of the vestibulocochlear nerve I8 intertrigeminal nucleus I5 interventricular foramen IVF intramedullary thalamic area IMA islands of Calleja ICj islands of Calleja, major island ICjM
J juxtarestiform body jx juxtatrigeminal area Jx5
K Kˆlliker-Fuse nucleus KF
L lacunosum moleculare layer of the hippocampus LMol lambdoid septal zone Ld lamina dissecans of the entorhinal cortex Dsc lateral (dentate) cerebellar nucleus Lat lateral accumbens shell LAcbSh lateral amygdaloid nu La lateral amygdaloid nucleus, dorsolateral part LaDL lateral amygdaloid nucleus, ventrolateral part LaVL lateral amygdaloid nucleus, ventromedial part LaVM lateral cerebellar nucleus, parvicellular part LatPC lateral cervical nucleus LatC lateral entorhinal cortex LEnt lateral globus pallidus LGP lateral habenular nucleus LHb lateral habenular nucleus, lateral part LHbL lateral habenular nucleus, medial part LHbM lateral hypothalamic area LH lateral lemniscus ll lateral mammillary nucleus LM lateral olfactory tract lo lateral orbital cortex LO lateral parabrachial nucleus LPB lateral parabrachial nucleus, central part LPBC lateral parabrachial nucleus, crescent part LPBCr lateral parabrachial nucleus, dorsal part LPBD
lateral parabrachial nucleus, external part LPBE lateral parabrachial nucleus, internal part LPBI lateral parabrachial nucleus, superior part LPBS lateral parabrachial nucleus, ventral part LPBV lateral paragigantocellular nucleus LPGi lateral periaqueductal gray LPAG lateral pontine nucleus LPn lateral posterior thalamic nucleus LP lateral posterior thalamic nucleus, laterocaudal part LPLC lateral posterior thalamic nucleus, laterorostral part LPLR lateral posterior thalamic nucleus, mediocaudal part LPMC lateral posterior thalamic nucleus, mediorostral part LPMR lateral preoptic area LPO lateral recess of the 4th ventricle LR4V lateral reticular nucleus LRt lateral reticular nucleus, parvicellular part LRtPC lateral reticular nucleus, subtrigeminal part LRtS5 lateral septal nucleus, dorsal part LSD lateral septal nucleus, intermediate part LSI lateral septal nucleus, ventral part LSV lateral spinal nucleus LSp lateral stripe of the striatum LSS lateral superior olive LSO lateral tegmental tract ltg lateral terminal nucleus of the accessory optic tract LT lateral ventricle LV lateral vestibular nucleus LVe lateral vestibulospinal tract lvs lateroanterior hypothalamic nucleus LA laterodorsal tegmental nucleus LDTg
laterodorsal tegmental nucleus, ventral part LDTgV laterodorsal thalamic nucleus LD laterodorsal thalamic nucleus, dorsomedial part LDDM laterodorsal thalamic nucleus, ventrolateral part LDVL lateroventral periolivary nucleus LVPO layer of cortex 1a layer of cortex 1b lemina terminalis LTer linear nucleus of the medulla Li locus coeruleus LC longitudinal association bundle lab longitudinal fasciculus of the pons lfp
M magnocellular nucleus of the lateral hypothalamus MCLH magnocellular nucleus of the posterior commissure MCPC magnocellular preoptic nucleus MCPO mammillary peduncle mp mammillary recess of the 3rd ventricle MRe mammillotegmental tract mtg mammillothalamic tract mt marginal zone of the medial geniculate MZMG medial (fastigial) cerebellar nucleus Med medial accessory oculomotor nucleus MA3 medial amygdaloid nucleus Me medial amygdaloid nucleus, anterodorsal part MeAD medial amygdaloid nucleus, anteroventral part MeAV medial amygdaloid nucleus, posterodorsal part MePD medial amygdaloid nucleus, posteroventral part MePV
medial cerebellar nucleus, dorsolateral protuberance MedDL medial corticohypothalamic tract mch medial eminence, external layer MEE medial eminence, internal layer MEI medial entorhinal cortex MEnt medial entorhinal cortex, ventral part MEntV medial forebrain bundle mfb medial forebrain bundle, ‘a’ component mfba medial forebrain bundle, ‘b’ component mfbb medial geniculate nucleus MG medial geniculate nucleus, dorsal part MGD medial geniculate nucleus, medial part MGM medial geniculate nucleus, ventral part MGV medial globus pallidus MGP medial habenular nucleus MHb medial lemniscus ml medial longitudinal fasciculus mlf medial mammillary nucleus, lateral part ML medial mammillary nucleus, medial part MM medial mammillary nucleus, median part MMn medial orbital cortex MO medial parabrachial nucleus MPB medial parabrachial nucleus external part MPBE medial pontine nucleus MPn medial preoptic area MPA medial preoptic nucleus MPO medial preoptic nucleus, central part MPOC medial preoptic nucleus, lateral part MPOL medial preoptic nucleus, medial part MPOM medial pretectal nucleus MPT medial rostroventrolateral medulla MRVL medial septal nucleus MS medial superior olive MSO medial terminal nucleus of the accessory optic tract MT medial tuberal nucleus MTu
medial vestibular nucleus MVe medial vestibular nucleus, magnocellular part MVeMC medial vestibular nucleus, parvicellular part MVePC median accessory nucleus of the medulla MnA median eminence ME median preoptic nucleus MnPO median raphe nucleus MnR mediodorsal thalamic nucleus MD mediodorsal thalamic nucleus, central part MDC mediodorsal thalamic nucleus, lateral part MDL mediodorsal thalamic nucleus, medial part MDM mediodorsal thalamic nucleus, paralaminar part MDPL medioventral periolivary nucleus MVPO medullary reticular nucleus, dorsal part MdD medullary reticular nucleus, ventral part MdV mesencephalic trigeminal nucleus Me5 mesencephalic trigeminal tract me5 microcellular tegmental nucleus MiTg middle cerebellar peduncle mcp middle cerebral artery mcer minimus nucleus Min mitral cell layer of the accessory olfactory bulb MiA mitral cell layer of the olfactory bulb Mi molecular layer of the dentate gyrus Mol motor root of the trigeminal nerve m5 motor trigeminal nucleus Mo5 motor trigeminal nucleus, dorsolateral part Mo5DL motor trigeminal nucleus, ventromedial part Mo5VM
N nigrostriatal bundle ns nucleus O O nucleus of Darkschewitsch Dk nucleus of origin of efferents of the vestibular nerve EVe nucleus of Roller Ro nucleus of the ansa lenticularis AL nucleus of the brachium of the inferior colliculus BIC nucleus of the commissural stria terminalis CST nucleus of the dorsal hippocampal commissure DHC nucleus of the fields of Forel F nucleus of the horizontal limb of the diagonal band HDB nucleus of the lateral olfactory tract LOT nucleus of the optic tract OT nucleus of the posterior commissure PCom nucleus of the solitary tract Sol nucleus of the solitary tract, central part SolCe nucleus of the solitary tract, commissural part SolC nucleus of the solitary tract, dorsomedial part SolDM nucleus of the solitary tract, gelatinous part SolG nucleus of the solitary tract, intermediate part SolIM nucleus of the solitary tract, interstitial part SolI nucleus of the solitary tract, medial part SolM nucleus of the solitary tract, rostrolateral part1-10 SolRL nucleus of the solitary tract, ventrolateral part SolVL
nucleus of the stria medullaris SM nucleus of the trapezoid body Tz nucleus of the vertical limb of the diagonal band VDB nucleus X X nucleus Y Y nucleus Z Z
O obex Obex oculomotor nerve or its root 3n oculomotor nucleus 3 oculomotor nucleus, parvicellular part 3PC olfactory bulb OB olfactory nerve layer ON olfactory tubercle Tu olfactory tubercle densocellular layer TuDC olfactory tubercle plexiform layer TuPl olfactory tubercle polymorph layer TuPo olfactory ventricle (olfactory part of lateral ventricle) OV olivary pretectal nucleus OPT olivocerebellar tract oc olivocochlear bundle ocb optic chiasm ox optic nerve 2n optic nerve layer of the superior colliculus Op optic tract opt oriens layer of the hippocampus Or outer blade of the dentate gyrus OBl oval paracentral thalamic nucleus OPC
P paraabducens nucleus Pa6 parabigeminal nucleus PBG parabrachial nucleus PB
parabrachial nucleus, waist part PBW parabrachial pigmented nucleus PBP paracentral thalamic nucleus PC paracochlear glial substance PCGS paracollicular tegmentum PCTg parafascicular thalamic nucleus PF parafloccular sulcus pfs paraflocculus PFl paralambdoid septal nucleus PLd paralemniscal nucleus PL paramedian lobule PM paramedian raphe nucleus PMnR paramedian reticular nucleus PMn paramedian sulcus pms paranigral nucleus PN parapyramidal nucleus PPy pararubral nucleus PaR parasolitary nucleus PSol parastrial nucleus PS parasubiculum PaS parasubthalamic nucleus PSTh paratenial thalamic nucleus PT paratrigeminal nucleus Pa5 paratrochlear nucleus Pa4 paraventricular hypoth nucleus Pa paraventricular hypothalamic nucleus, anterior magnocellular part PaAM paraventricular hypothalamic nucleus, anterior parvicellular part PaAP paraventricular hypothalamic nucleus, dorsal cap PaDC paraventricular hypothalamic nucleus, lateral magnocellular part PaLM paraventricular hypothalamic nucleus, medial parvicellular part PaMP paraventricular hypothalamic nucleus, posterior part PaPo paraventricular hypothalamic nucleus, ventral part PaV paraventricular thalamic nucleus PV paraventricular thalamic nucleus, anterior
part PVA paraventricular thalamic nucleus, posterior part PVP parietal association cortex PtA parvicellular motor trigeminal nucleus PC5 parvicellular reticular nucleus PCRt parvicellular reticular nucleus, alpha part PCRtA pedunculopontine tegmental nucleus PPTg periaqueductal gray PAG perifacial zone P7 perifornical nucleus PeF peripeduncular nucleus PP perirhinal cortex PRh peritrigeminal zone P5 periventricular fiber system pv periventricular hypothalamic nucleus Pe pineal gland Pi pineal recess PiRe piriform cortex Pir polymorph layer of the dentate gyrus PoDG pontine nuclei Pn pontine raphe nucleus PnR pontine reticular nucleus, caudal part PnC pontine reticular nucleus, oral part PnO pontine reticular nucleus, ventral part PnV posterior commissure pc posterior hypothalamic area PH posterior intralaminar thalamic nucleus PIL posterior limitans thalamic nucleus PLi posterior lobe of pituitary PPit posterior pretectal nucleus PPT posterior superior fissure psf posterior thalamic nuclear group Po posterior thalamic nuclear group, triangular part PoT posterodorsal preoptic nucleus PDP posterodorsal tegmental nucleus PDTg posterolateral cortical amygdaloid nucleus (C2) PLCo posterolateral fissure plf
posteromedial cortical amygdaloid nucleus (C3) PMCo posteromedian thalamic nucleus PoMn postsubiculum Post pre-Bˆtzinger complex PrBo precommissural fornix pcf precommissural nucleus PrC preculminate fissure pcuf predorsal bundle pd prelimbic cortex PrL premammillary nucleus, dorsal part PMD premammillary nucleus, ventral part PMV prepositus nucleus Pr prepyramidal fissure ppf prerubral field PR presubiculum PrS primary auditory cortex Au1 primary fissure prf primary motor cortex M1 primary somatosensory cortex S1 primary somatosensory cortex, barrel field S1BF primary somatosensory cortex, dysgranular region S1DZ primary somatosensory cortex, forelimb region S1FL primary somatosensory cortex, hindlimb region S1HL primary somatosensory cortex, jaw region S1J primary somatosensory cortex, jaw region, oral surface S1JO primary somatosensory cortex, trunk region S1Tr primary somatosensory cortex, upper lip region S1ULp primary visual cortex, binocular area V1B primary visual cortex, monocular area V1M principal mammillary tract pm principal sensory trigeminal nucleus Pr5 principal sensory trigeminal nucleus,
dorsomedial part Pr5DM principal sensory trigeminal nucleus, ventrolateral part Pr5VL Probst’s bundle prb prosubiculum ProS pyramidal cell layer of the hippocampus Py pyramidal decussation pyx pyramidal fissure pf pyramidal tract py
root of hypoglossal nerve 12n rostral interstitial nucleus of medial longitudinal fasciculus RI rostral linear nucleus of the raphe RLi rostral periolivary region RPO rostral ventral respiratory group RVRG rostroventrolateral reticular nucleus RVL rostrum of the corpus callosum rcc rubrospinal tract rs
R
S
raphe interpositus nucleus RIP raphe magnus nucleus RMg raphe obscurus nucleus ROb raphe pallidus nucleus RPa recess of the inferior colliculus ReIC red nucleus R red nucleus, lateral horn RLH red nucleus, magnocellular part RMC red nucleus, parvicellular part RPC reticular thalamic nucleus Rt reticulotegmental nucleus of the pons RtTg reticulotegmental nucleus of the pons, pericentral part RtTgP retroambiguus nucleus RAmb retrochiasmatic area RCh retroethmoid nucleus REth retrolemniscal nucleus RL retrorubral field RRF retrorubral nucleus RR retrosplenial agranular cortex RSA retrosplenial granular a cortex RSGa retrosplenial granular b cortex RSGb reuniens thalamic nucleus Re rhabdoid nucleus Rbd rhinal fissure rf rhinal incisura ri rhomboid thalamic nucleus Rh root of abducens nerve 6n
sagulum nucleus Sag scaphoid thalamic nucleus Sc secondary auditory cortex, dorsal area AuD secondary auditory cortex, ventral area AuV secondary fissure sf secondary motor cortex M2 secondary somatosensory cortex S2 secondary visual cortex, lateral area V2L secondary visual cortex, mediolateral area V2ML secondary visual cortex, mediomedial area V2MM semilunar nucleus SL sensory root of the trigeminal nerve s5 septofimbrial nucleus SFi septohippocampal nucleus SHi simple lobule Sim simple lobule A SimA simple lobule B SimB simplex fissure simf solitary tract sol sphenoid nucleus Sph spinal trigeminal nucleus, caudal part Sp5C spinal trigeminal nucleus, interpolar part Sp5I spinal trigeminal nucleus, oral part Sp5O spinal trigeminal tract sp5 spinal vestibular nucleus SpVe
spinocerebellar tract sc splenium of the corpus callosum scc stigmoid hypothalamic nucleus Stg stratum radiatum of the hippocampus Rad stria medullaris of the thalamus sm stria terminalis st strial part of the preoptic area StA striohypothalamic nucleus StHy subbrachial nucleus SubB subcoeruleus nucleus SubC subcoeruleus nucleus, alpha part SubCA subcoeruleus nucleus, dorsal part SubCD subcoeruleus nucleus, ventral part SubCV subcommissural nucleus SCom subcommissural organ SCO subfornical organ SFO subgeniculate nucleus SubG subiculum S subincertal nucleus SubI submammillothalamic nucleus SMT submedius thalamic nucleus Sub submedius thalamic nucleus, dorsal part SubD submedius thalamic nucleus, ventral part SubV subparafascicular thalamic nucleus SPF subparafascicular thalamic nucleus, parvicellular part SPFPC subparaventricular zone of the hypothalamus SPa subpedencular tegmental nucleus SPTg substantia innominata SI substantia innominata, basal part SIB substantia innominata, dorsal part SID substantia innominata, ventral part SIV substantia nigra, compact part SNC substantia nigra, compact part, dorsal tier SNCD substantia nigra, compacta part, ventral tier SNCV substantia nigra, lateral part SNL
substantia nigra, medial part SNM substantia nigra, reticular part SNR substantia nigra, reticular part, dorsomedial tier SNRDM substantia nigra, reticular part, ventrolateral tier SNRVL subthalamic nucleus STh sulcus limitans slim superficial glial zone of the cochlear nuclei SGl superficial gray layer of the superior colliculus SuG superior cerebellar peduncle (brachium conjunctivum) scp superior cerebellar peduncle, descending limb scpd superior colliculus SC superior medullary velum SMV superior paraolivary nucleus SPO superior salivatory nucleus SuS superior thalamic radiation str superior vestibular nucleus SuVe suprachiasmatic nucleus SCh suprageniculate thalamic nucleus SG supragenual nucleus SGe supramammillary decussation sumx supramammillary nucleus SuM supramammillary nucleus, lateral part SuML supramammillary nucleus, medial part SuMM supraoculomotor cap Su3C supraoculomotor periaqueductal gray Su3 supraoptic decussation sox supraoptic nucleus SO supraoptic nucleus, retrochiasmatic part SOR supratrigeminal nucleus Su5
T tectospinal tract ts
temporal association cortex TeA terete hypothalamic nucleus Te transverse fibers of the pons tfp trapezoid body tz triangular septal nucleus TS trigeminal ganglion 5Gn trigeminothalamic tract tth trochlear decussation 4x trochlear nerve or its root 4n trochlear nucleus 4 tuber cinereum area TC tuberomammillary nu TM
U uncinate fasciculus unc uvular fissure uf
V vagus nerve or its root 10n vascular organ of the lamina terminalis VOLT ventral amygdalofugal pathway vaf ventral anterior thalamic nucleus VA ventral cochlear nucleus VC ventral cochlear nucleus, anterior part VCA ventral cochlear nucleus, posterior part VCP ventral endopiriform nucleus VEn ventral hippocampal commissure vhc ventral lateral geniculate nucleus VLG ventral lateral geniculate nucleus, magnocellular part VLGMC ventral lateral geniculate nucleus, parvicellular part VLGPC ventral nucleus of the lateral lemniscus VLL ventral orbital cortex VO ventral pallidum VP ventral peduncular pontine nucleus VPPn
ventral posterior thalamic nucleus, parvicellular part VPPC ventral posterolateral thalamic nucleus VPL ventral posteromedial thalamic nucleus VPM ventral reuniens thalamic nucleus VRe ventral spinocerebellar tract vsc ventral tegmental area VTA ventral tegmental decussation vtgx ventral tegmental nucleus VTg ventral tenia tecta VTT ventral tuberomammillary nucleus VTM ventrolateral hypothalamic nucleus VLH ventrolateral periaqueductal gray VLPAG ventrolateral preoptic nucleus VLPO ventrolateral tegmental area VLTg ventrolateral thalamic nucleus VL ventromedial hypothalamic nucleus VMH ventromedial hypothalamic nucleus, anterior part VMHA ventromedial hypothalamic nucleus, central part VMHC ventromedial hypothalamic nucleus, dorsomedial part VMHDM ventromedial hypothalamic nucleus, ventrolateral part VMHVL ventromedial pontine nucleus VMPn ventromedial preoptic nucleus VMPO ventromedial thalamic nucleus VM vestibular root of the vestibulocochlear nerve 8vn vestibulocerebellar nucleus VeCb vestibulocochlear ganglion 8Gn vestibulocochlear nerve 8n vestibulomesencephalic tract veme visual tegmental relay zone VTRZ vomeronasal nerve vn vomeronasal nerve layer VN
X
xiphoid thalamic nucleus Xi
Z zona incerta ZI zona incerta, dorsal part ZID zona incerta, ventral part ZIV zona limitans ZL zonal layer of the superior colliculus Zo
The Rat Brain in Stereotaxic Coordinates, FOURTH EDITION CD-ROM George Paxinos School of Psychology The University of New South Wales Sydney 2052, Australia
Charles Watson Faculty of Health and Behavioural Sciences University of Wollongong New South Wales 2521, Australia
more extensive editing is required. These files can be opened with Adobe Illustrator 3.0 (or better) on appropriately configured Macintosh or MS-Windows computers. These files can be found in the folder entitled AI3FILES INSTALLATION Mac OS and MS Windows Start the computer and insert the CD-ROM.
The authors thank Paul Halasz for the design of the CD-Rom. FEATURES This CD-ROM is designed to allow you to print, copy, and search either labeled or unlabeled versions of the diagrams of coronal, sagittal and horizontal sections presented in The Rat Brain in Stereotaxic Coordinates, Fourth Edition. This CD-ROM can be used on a computer which runs either Macintosh System 7 (or better) or MSWindows (3.1, 95 or NT). It should also be possible to use this CDROM with LINUX, IBM AIX, Sun SPARC SunOS, Sun SPARC Solaris, SGIRIX, HP-UX, Digital Unix, and OS/2 Warp; for work with these operating systems obtain Adobe Acrobat Reader from Adobe, or from the Adobe web site (www.Adobe.Com). The diagrams are presented in Adobe Acrobat Portable Document Format (PDF) which can be read by the Adobe Acrobat Reader 3.0 (or better) software program. The installer for the Acrobat Reader software can be found on this CDROM. A special function of Acrobat allows diagrams or parts of diagrams to be copied to most drawing or word processing programs for annotation and custom labeling. In addition to the Acrobat files, there is a set of diagrams in Adobe Illustrator 3.0 format in order to allow more extensive editing with Adobe Illustrator and other graphics programs such as CorelDRAW that can edit Illustrator files. The CD-ROM also contains 69 color atlas plates and the full text of the atlas.
1. Double click on “Start.” (With windows 95 “Start” is usually automatic.) (For subsequent occasions you can click on RB4Atlas.pdf without clicking on “Start.”) 2. Click on Install Acrobat 3.0 if your computer does not have Acrobat 3.0 already installed; otherwise, click on “Open the Atlas.” THE START PAGE The START PAGE is the entry point into the (a) labeled and unlabeled diagrams (b)unlabeled diagrams with thick lines, (c) color plates, (d) introduction (e) list of structures, and (f) index of abbreviations. By clicking on different areas on the START PAGE you can open the following: TITLE - by clicking on this you can open the written introduction to The Rat Brain in Stereotaxic Coordinates, Fourth Edition. The stack of LABELED DIAGRAMS: Coronal, Sagittal, Horizontal, Spinal Cord - by clicking on this you can open the files containing the labeled diagrams of the brain and spinal cord. The stack of UNLABELED DIAGRAMS: Coronal, Sagittal, Horizontal, Spinal Cord - by clicking on this you can open the files containing the unlabeled diagrams of the brain and spinal cord that are suitable for printing at reduction/magnification from 50% to 200%.
USING ADOBE ILLUSTRATOR FILES FOR EDITING We have provided a set of labeled diagrams of coronal, sagittal and horizontal sections as vector mapped Adobe Illustrator files in case
The stack of THICK LINE DIAGRAMS - by clicking on this you can open the files containing the labeled diagrams of the brain and spinal cord that are suitable for printing at a great reduction without losing
definition of lines in the diagram. INDEX OF ABREVIATIONS - by clicking on this you can view the alphabetical list of abbreviations along with the full name of each structure. LIST OF STRUCTURES - by clicking on this you can view the alphabetical list of the full names of all structures, each followed by the abbreviation. HELP - by clicking on this, you are taken to the tabular summary of features of the START PAGE.
VIEWING, PRINTING, AND EDITING THE LABELED AND UNLABELED DIAGRAMS
To ANNOTATE OR EDIT a diagram or part of a diagram (for example, for the insertion of lesion or electrode placement marks), use the Select Graphics option in the TOOLS menu. All or part of the diagram can be selected and copied for subsequent pasting into a graphics program or an advanced word processor program. The images are copied as bitmapped images. For better results after the area has been selected, higher magnification should be selected (usually 400%) using the “Zoom to..” option in the VIEW menu. Files or parts of files can also be edited (as vector mapped files) by importing Adobe Illustrator Files (from AI3FILES folder) into Adobe Illustrator or a graphics program such as CorelDRAW that can open Adobe Illustrator files. To return to the sagittal or coronal plan diagrams, click the Window exit button.
Copyright © 1998 by George Paxinos and Charles Watson
Click on the relevant area on the START PAGE. A plan diagram of a sagittal section will appear. Click on the relevant area of brain to obtain the corresponding coronal, sagittal or horizontal section diagram. (It will appear on release of the mouse button.) Most, but not all, diagrams are linked to the sagittal and coronal plan diagrams, so the level selected may be the exact section required or one or two levels away from the desired coronal, sagittal or horizontal section. The desired section can quickly be reached by advancing from the section that is displayed. Once a coronal section is displayed, different views and magnifications can be selected from the pull down menus or icons - information on these menus and icons can be found in the Help section of Adobe Acrobat. (Click on the standard Help icon at the top of the window.)
All Rights Reserved.
To PRINT the diagram that has been selected, choose Page Setup from the File pull-down menu. Choose the desired magnification or reduction and the paper format to be used. Use the unlabeled diagrams with thick lines if the desired final size is to be less than 50% (The reason for this is that the reduction of the overall diagram also reduces the thickness of the lines, so substantial reductions should be carried out on the diagrams with double thickness lines.) Next, select the Print command from the File menu, and select the ‘Shrink to Fit Page’ option. This ensures that the full page is printed.
Academic Press, Ltd. 24-28 Oval Road, London NW1 7DX, UK http://www.hbuk.co.uk/ap/
No part of this publication may be reproduced or transmitted in any form or by any means, electronic or mechanical, including input into or storage in any information system, without permission of the publisher. All brand names and product names mentioned in this publication are trademarks or registered trademarks of their respective companies. Academic Press, Inc. 525 B Street, Suite 1900, San Diego, California 92101-4495, USA http://www.apnet.com
International Standard Book Number: 0-12-547617-5
Produced in the United States of America.
6
7
+5
10 9
0
-5
2
1
1
0
+10
6
5
4
5
7
WWW Link
PtA 2
Coronal Diagrams IG
cc
df
7
hf
alv
S1
dhc
bsc
6
CA3 LPMC
OPT
pc
SCO
str
4
Eth
opt 3
SubG
fr
ic
ml scp
rf
fr PH 3V
sox mtg
LV
SuM
BLP
ML
AcbSh
3
2
1
0
mfba VP Tu
Al
2
3
4
5
MPA
VM
ts scp
SPF
VM
PaPo
sf Med SMV/4x
xscp
1 CGPn
mlf
vtgx PnO RtTgP
3n mp IPF
4V
SolG
10
asc7
sol
11
10
9
8
cp
9
PnC
RtTg
Gi ml
lfp tfp
TM PMV
7
6
6n PnV
Pn
APit
5
8
IRt
4
3
2
1
10
MdV
LPGi
Tz
GiV
GiA
IO
IO
py
11
Figure 81
Interaural
12
Cu cu
DPGi
Lateral 0.90 mm 13
10 MVe SolM
DMTg
7
9
MVePC MVeMC
tz
14
plf
4V
ml
-1
7
6
9
LDTg
Pa4
LM
VMH
4
3
ECIC
SPTg
VTA SuM f
DM TC sox
ppf
g7
PMD
LA ox
Interaural
3
7
pcuf
dtg
RRF
R
RI
SMT LH
AHC
psf
CIC
mt
ZI
6
prf
4
5
IMLFG
AHP
AHA
SO
mcer
6
0
2
6
cic
VLPAG me5
PF
SubV
Rt
f
BSTMPM BSTMP
6
LPAG
PC SubD VPPC
StHy
HDB mfbb
ICj
PLCo 10
1
-15
8
MCPC
Bregma -4.52 mm 4
-14
2
PF fr
PS
SI
1
0
5
AOP
DCIC
DLPAG
pc
PF
IAD
CST ac BAC
VP
af
Interaural 4.48 mm
-13
PrC PCom
AM
VTT
Pir
ArcMP
-12
1
DpWh
PPT OPT
MDL MD
PT
PLd
ICjM BSTMA
2
APir PMCo
MRe 0
sm
LSV
E/OV
9
VTM
LSV
DTT
AHiPM LM
-11
5
SuG Op InG InWh DpG
bsc
LHbL
pcf SFi TS
8
DG
MM
Ld
LSI
DP
LEnt
DG
3V
LSD
gcc VO
AOV
DEn
MMn
f
-10
RSGa Zo
S
hf
CA3
IL
7
CA1
vhc
AOM
Gem
pm
1
-9
RSGb
IG
CA2
Cg2 PrL
3
ZIV
-8
V2MM
scc
4
SNR LH
mfb
cp
F
sumx
ns
-7
dhc
AOB
6
PRh
CA3
-6
RSA
cc
lo
Ect
CA2
ZID
PR
RI
-5
V1M
FrA
5
TeA
VPM
SPFPC
-4
Sagittal Diagrams
OB
AuV
VLGMC
-3
M2
6
VLGPC Po
PF pv
rf
Au1
IGL
LPLC LPLR
-2
Bregma
M2
5
APTV Sc
-1
Cg1
DLG
LPMR
MPT
PVP
ar
6
0
M1
3
CA2
IMA
APTD
PrC
ec
7
1
AuD
3V
alv
2
2
9
7
DG PiRe
hbc
4
3
10
8
CA1
PoDG
5
4
Bregma
1
V2ML
RSGb cg
-5
0
V2MM
RSA
10 +5
3
Figure 38
5
5
+15
2
-15 Bregma 0
0 Interaural 8
3
4
5
-10
0
-1
-2
-3
-4
-5
-6
Unlabeled Diagrams Introduction
Coronal Sagit Horiz IN STEREOTAXIC COORDINATES
List of Structures Index of Abbreviations
Thick Line Diagrams
Fourth Edition George Paxinos & Charles Watson Academic Press 1998
Coronal Sagit Horiz 5
10
+5
4
3
-5
0
2
-10
1
0
-1
-2
-3
-4
-5
-6
-9
-10
-11
Interaural +15 +10
10 +5
S 5
Cl PFl
DEn
CPu LGP
Pir
B
BSTMPL BSTL BSTMPI AOV
SubG VPL ZI
AcbSh
VTT
ICjM
0
Ld
VRe
ADP VDB MnPO
SL
SPF
scp
SubCA DTgP
VTg DTgC mlf
lo
MVe 0
1
LC
10
4V
9 1
MVe
me5
ml
SuVe LVe
scp LPB vsc
acp
icp
2
DC
Horizontal Diagrams ic
3
1
Bar
DRC
PaR IPAC
SpVe
scp
sm
aca
aci
2
2
ECu
LVe LC
LDTg Sph
Rbd
scp
fr mt
3
Cop
SuVe
MPB Me5
SPTg
RLi dtgx CLi xscp
DC
LPB
PL
R
RI 3V
Rh Re
f
ac
MiTg
PPTg
mch
1
LR4V VCA
ILL
RRF
Sub
Re
3V
SNL
F VM
SM
BSTMA
SNCD
ZID
Rt
BSTMPM
AcbC AOP
SNR
4
Fl
MGP
B
2
1
PoDG PrS DG PaS
CA3
B
3
7
LEnt
CA1 CA2
AIV
MEnt
PBG
ll
Cb
cp
3
mcp
sox
4
rf
st
5
4
opt
LV
5
hf
ec alv
6
6
7
7
Interaural 2.90 mm 14
Copyright (c) 1998 by George Paxinos and Charles Watson
-15
6
-5
0
4
How to Copy Figures Permission to Reproduce Figures
-14
Ect
LaDL
Color Plates
-13
AIP
5
Help
-12
Bregma -7.10 mm PRh
0
-8
5
5
6
-7
-15 Bregma 0
7
13
12
11
Figure 100 10
9
8
7
6
5
4
3
2
1
0
-1
-2
-3
-4
-5
-6
CD-Rom design by Paul Halasz
Copyright © 1998 by George Paxinos and Charles Watson All Rights Reserved. No part of this publication may be reproduced or transmitted in any form or by any means, electronic or mechanical, including input into or storage in any information system, without permission of the publisher. All brand names and product names mentioned in this publication are trademarks or registered trademarks of their respective companies. Academic Press, Inc. 525 B Street, Suite 1900, San Diego, California 92101-4495, USA http://www.apnet.com Academic Press, Ltd. 24-28 Oval Road, London NW1 7DX, UK http://www.hbuk.co.uk/ap/ International Standard Book Number: 0-12-547617-5
Produced in the United States of America.
Figure 1
E/OV
GrO aci
EPl
Mi
Gl
IPl
ON
Interaural 15.70 mm
Bregma 6.70 mm
Figure 2
GrA
vn
AOB
dlo
AOE
GrA
lo
aci
AOL
E/OV
GrO
Gl
EPl
Mi
IPl
ON
Interaural 15.20 mm
Bregma 6.20 mm
Figure 3
GlA
MiA
GrO
EPlA
VN
AOE
GrA
dlo
AOL
aci
E/OV
Gl
lo
EPl
Mi
GrO
IPl
ON
Interaural 14.70 mm
Bregma 5.70 mm
Figure 4
FrA
LO
MO
AOB
VO
rf
Mi
AOD
IPl
AOE
aci
AOM
AOL
EPl
GrO
E/OV
lo
Gl
AOV
Interaural 14.20 mm
Bregma 5.20 mm
Figure 5
FrA
PrL
LO
MO
DLO
VO
AOD
rf
E/OV AOL
aci
AOM
1a
1b
AOV
lo
Interaural 13.70 mm
Bregma 4.70 mm
Figure 6
M2
PrL
MO
LO
DLO
VO
AOD
ri
rf
AOL E/OV
aci
AOM
AOV
lo
VTT
Interaural 13.20 mm
Bregma 4.20 mm
Figure 7
M2
Cg1
M1
fmi
PrL
Cl
LO
AI
VO
MO
DTr
ri
rf
1 E/OV
3
2
3
DEn
2
aci
1 Pir
AOM
DTT
lo
AOV
3
2
VTT
1
Interaural 12.70 mm
Bregma 3.70 mm
Figure 8
M2
Cg1
M1
PrL fmi
Cl
AID
IL
VO
LO
AIV
DP
ri
E/OV rf
2
3
1
DTT
DEn
aca
Pir
lo
VTT
AOP
Tu
Interaural 12.20 mm
Bregma 3.20 mm
Figure 9
M2
M1
Cg1
S1J
PrL
fmi
GI
IL
Cl
E/OV
AID
DP
AIV
LO
VO
DTT
AcbSh
AcbC
rf
aca
DEn
Pir
AOP
lo
mfba
SL
ICj mfba
TuPo
TuDC
Interaural 11.70 mm
TuPl
Bregma 2.70 mm
Figure 10 M2
M1
Cg1
fmi
PrL
S1J
IL
E
GI
CPu
LV
DP Cl
AID
3
AIV
1
2
DTT
rcc
VO
DEn
SHi
rf AcbC
aca
SL
Pir AcbSh
lo
LSS
ICj
mfba
VP
Tu
Interaural 11.20 mm
Bregma 2.20 mm
Figure 11 M2
M1
Cg1
cg
Cg2
fmi
S1J
E
IG
ec
CPu
LV
DP
GI
LSI
DI
Cl
exc
SHi
AID
AIV
AcbC
DEn
AcbSh
LSS
aca
rf
SL
Pir
VP
LAcbSh
lo
mfba
mfba
VP
ICj
VP
Tu
Interaural 10.70 mm
Bregma 1.70 mm
Figure 12 M2
M1
Cg1
S1J
cg
fmi
Cg2
IG
E
S1JO
gcc
LSD
IG
LV CPu
ec
GI
LSV
Cl
DI
SHi
LSI
VDB
AID
AcbC
AIV
DEn
LSS
aca
rf
AcbSh
mfba
Pir
lo mfba
VP
LAcbSh
mfba
ICj
VP
Tu
Interaural 10.60 mm
Bregma 1.60 mm
Figure 13 M2
M1
S1FL
Cg1
S1J
cg
Cg2
S1JO
E
IG
S1DZ
gcc
S1ULp
LV
IG LSD
CPu
ec
GI
LSV
LSI
SHi
Cl
DI
MS
AID
AcbC
AIV
DEn
ICjM
rf
aca
VDB
AcbSh
Pir
LSS
VP
mfba
ICj
mfba
lo
LAcbSh
mfba
ICj
VP
2n
Tu
Interaural 10.20 mm
Bregma 1.20 mm
Figure 14 M2
M1
S1FL
Cg1
S1J
cg
Cg2
S1JO
IG
E
S1DZ
gcc
LV
S1ULp
LSD
SHi
ec
CPu
GI
LSV
LSI
Cl DI
MS
AID
AcbC
AIV
ICjM
DEn rf
aca
AcbSh
LSS
Pir
VDB
LAcbSh
lo
ICj
mfba
CB
VP
mfba
VP
VP
2n
ICj
Tu
Interaural 10.00 mm
Bregma 1.00 mm
Figure 15 M2
M1
S1FL
Cg1
S1J
cg
Cg2
S1JO
IG
S1DZ
E
gcc
LV
LSD
ec
S1ULp
SHi
LSI
CPu
GI
Ld
LSV
ZL
Cl
MS
DI
ICjM
AID
AcbSh
AIV
AcbC
VDB
rf
aca
DEn
LSS
Pir
LAcbSh
VP
HDB
mfbb
mfba
CB
lo
VP
mfba
VP
ICj
ICj
2n
Tu
Interaural 9.70 mm
Bregma 0.70 mm
Figure 16 M2
M1
S1FL
Cg1
S1DZ
S1J
cg
Cg2
S1DZ
IG
E
cc
LV
S1ULp
LSD
SHi
LSI
S2
ec
CPu
Ld
GI
PLd
ZL
LSV
DI
BSTMA
Cl
MS
AID
BSTL
AcbSh
AIV
DEn
aca
VDB
rf
IPAC
AcbC
LSS
SIB
Pir
VP
CB
HDB
mfba
mfbb
lo
VP
2n
ICj
Tu
Interaural 9.48 mm
Bregma 0.48 mm
Figure 17 M1
M2
S1FL
Cg1
S1DZ
cg
Cg2
S1ULp
IG
cc
LV
LSD
SHi
LSI
S2
Ld
CPu
PLd
ec
GI
ZL
MS
LSV
DI
BSTMA
Cl
BSTL
AIP
aca
VDB
DEn
rf
IPAC
SI
VP
LSS
Pir
CB
mfbb
HDB
mfba
SIB
lo
ICj
2n
Tu
Interaural 9.20 mm
Bregma 0.20 mm
Figure 18 M1
M2
S1HL
Cg1
S1FL
cg
S1DZ
Cg2
IG
cc
S1BF
LV
df
LSD
LSI
SFi
S2
CPu
LSV
ec
ic
f
GI
BSTLD
st
MS
ZL
DI
BSTMA
BSTLJ
Cl
ac MnPO
acp
AIP
LGP
BSTLP
BSTMV
acp
BSTLV
StA
rf
LSS
DEn
ADP
PS
Fu
IPACL
VP
VEn
Al
MPOL
IPACM
SIB LPO
Pe
Pir
CxA
MCPO
mfba
MPA
mfba AVPe
3V mfbb
HDB
VP
lo
ICj
VMPO
ox
Tu
Interaural 8.74 mm
Bregma -0.26 mm
Figure 19 1 M1
M2
2
S1HL
3
Cg1
4
S1FL
5
S1DZ
cg
Cg2
6a
6b
IG
S1BF
cc
LV
df
LSD
pcf
ec
LSI
SFi
S2
CPu
ic
LSV
GI
f
st
BSTMA
DI
LGP BSTLJ
BSTLD
MnPO
BSTLP
Cl
ac acp
AIP
BSTLV
BSTMV
acp
rf
ADP
LSS PS
3V
Fu
DEn
StA
IPACL
VP
Pe
IPACM
LPO
VEn
Pir
MPOL
SIB
mfba
MCPO
CxA MPA
mfba
AVPe
mfbb
HDB
VP
lo
ICj
VMPO
VLPO
ox
Tu
Interaural 8.70 mm
Bregma -0.30 mm
Figure 20 M1
M2
S1HL
Cg1
S1FL
S1DZ
cg
Cg2
IG
S1BF
cc
LV
LSD
df
ec
LSI
SFi
S2
CPu
LSV
st
GI
ic
f
BSTMA
BSTLJ
DI
CST
LGP
BSTLP
BSTLI
Cl
ac MnPO
AIP
BSTMV
IPACL
acp
BSTLV
rf
ADP
DEn
PS
IPACM
StA
Pe VEn
MPA
VP
LSS
LPO
MPOL
SIB
AVPe
CxA
mfba
MCPO
3V
mfba
Pir
HDB
mfbb
VP
lo
ICj
VMPO
VLPO
ox
Tu
Interaural 8.60 mm
Bregma -0.40 mm
Figure 21 M1
M2
S1HL
S1FL
Cg1
S1DZ
cg
Cg2
S1BF
IG
LSD
cc
LV
df
ec
pcf
SFi
TS
S2
st
SFO
vhc
CPu BSTS
ic
sm
3V
BSTMPM
GI
BSTMPI
LGP
BAC
f
DI
BSTMPL
BSTLI
Cl
AIP
B
BSTLP
APF
rf
acp
IPACL
PaAM
mch
DEn PDP
SID PaAP
Pe
IPACM
StHy
LSS
B
SIB
VP MPA
VEn
Pir
LPO
MPOC
MCPO
mfba
HDB
CxA
mfbb
MPOL
VLPO
AAV
MPOM
lo
ox
Tu
SO
Interaural 8.20 mm
Bregma -0.80 mm
Figure 22 M2
M1
S1HL
Cg1
S1FL
S1DZ
cg
Cg2
S1BF
IG
cc
LV LSD
df
TS
ec
SFi
vhc
IVF
S2
SFO
D3V
st
AV
CPu
ic
PT
sm
GI
PVA
BSTMPM
DI LGP
mch
BSTMPI
Cl
B
f Pe
3V AIP
PaAP
BSTMPL
rf
PaAM
SIV
IPACL
SID
acp
DEn
VP
B
Pe
StHy
IPACM
LSS
SIB
MPOC
MPOM
AAD
VEn
Pir
LPO
mfb
MCPO
MPA
HDB
ACo
MPOL
CxA
VLH
AAV
LOT
SCh LA
SO
lo
ox
Interaural 8.08 mm
Bregma -0.92 mm
Figure 23 M1
M2
S1HL
Cg1
S1FL
S1DZ
Cg2
cg
IG
S1BF
cc
df
LV
TS
vhc
ec
SFO
fi
AVDM
D3V
AD
st
sm
PVA
PT
S2
PC
AVVL
IAD
AM
CPu
ic
AMV
Rt
PVA
GI
LGP
Re
DI
B
rf
Pe
SM
sm Cl
LSS
f AIP
PaAP
B
IPACL
B
AStr
MPA
IPACM
3V
SIV
BSTMPL DEn
SID
SIB
Pir
LH MPO
mfb
AAD
AHA
VEn
MCPO
BMA
AAV
VLH
3
LA
ACo
2
LOT
SO
SCh
1 CxA
MeAD
ox
lo
Interaural 7.70 mm
Bregma -1.30 mm
Figure 24 M2 M1
S1HL
Cg1
S1FL
S1DZ
Cg2
cg
IG
S1BF
cc
df
TS LV
vhc
fi
SFO
AVDM
ec
AD
D3V
sm
st
S2
PVA
PT
PC
AVVL
CPu
CM
IAD
AM ic
Rt
GI
AMV
PVA
DI
LGP
B
Re
Cl
B rf
AIP
sm
VRe
3V
B
IPACL SM
f
PaAP
AStr
DEn
SI
BSTMPL
IPACM
LSS
Pe
LH
VEn AAD
AHA
mfb
Pir
Cir
MCPO MPO
AAV
BMA 3
VLH
LA
2
LOT
ACo
SO
CxA
SCh
1
MeAD
ox
lo
Interaural 7.60 mm
Bregma -1.40 mm
Figure 25 M2
M1
RSA
S1HL
S1FL
S1DZ
RSGb
cg
S1BF
IG
cc
df
TS
LV
CA3
S1
vhc
SFO
DG
ec AVDM
fi
D3V
sm
st
AD
MD
ic
PVA
S2
PC
AVVL
PT
Rt
CPu
VA
B
VA
AM
LGP
IAM
GI
mt
Rh
AMV
DI
B
Re
rf
VRe
AIP
ZI
IPAC
Cl
B
SI
AStr
PaAP
CeM
f
BLA
LH
DEn
CeC
I
mfb
AHA
AA
VEn
MCPO
Pe
3
BMA
AHC
SO
3V
LOT
ACo
1
RCh CxA
sox
MeAD
ox
Interaural 7.40 mm
Bregma -1.60 mm
Figure 26 M2
M1
S1HL
RSA
S1FL
S1DZ
RSGb cg
IG
S1BF
cc
df
TS
LV
S1
fi
DG
LDVL
D3V
sm
AD MHb
st
ec
MD
AVDM
PVA
PC
PC
S2
PT
ic
AVVL
CM
eml
AM
IAD
Rt
VA
CPu
IAM
GI
AMV
mt
Rh
DI
LGP
Re VM
rf
LaDL
Xi
Sub
Cl
IPAC
AIP
VRe
B
B
AStr
ns
ZI
PaDC
3V
al
PaLM
DEn
CeL PaMP CeC
CeM
SI
LH f
SPa
BLA
mfb
PaV
cst
AHP
I
VEn
Pe
AHC
BMA
MeAD
LOT
opt
ACo
SO
BAOT
RCh
sox
CxA
Interaural 7.20 mm
Bregma -1.80 mm
Figure 27 M2
RSA M1
S1HL
S1FL
S1DZ
RSGb
cg
S1BF
IG
cc
df
DHC
dhc
CA3
S1
LV
DG
LDVL
fi
D3V
AD sm MHb
st
S2
MD
PVA
AVVL
PC
PT
AVDM
ec
iml
CM
GI
CPu
IAD
VA
Rt
AM
IAM
AMV
DI
mt
ic
Rh
LGP
Sub
AIP
VM
Cl rf
Re
LaDL
Xi
IPAC
VRe
ZI
ns PaMP
DEn PaDC
CeC
CeM
PaLM
CeL
al
SI
f
SPa
LH
BLA
mfb
PaV
AHP
IM
cst
VEn
MeAD
Pir
AHC
BMA
3V
Pe
opt
SO ACo
BAOT
CxA
sox
RCh
Interaural 7.12 mm
Bregma -1.88 mm
Figure 28 M1
M2
S1HL
RSA
S1FL
S1DZ
RSGb
cg
IG
S1BF
cc
DHC
df alv
dhc
CA3
S1
LV
fi
ec
MHb
DG
LDDM
D3V AD
sm
st
LDVL
LHb
CL
PVA
MDL S2
AV
iml
MDM
VL
PC
CM
CPu
VPL
GI
eml
VA
AM
IAM
Rt
ic
DI
Rh
LGP
Sub
IPAC
mt
Re
rf
AIP
AStr
VM
B
Xi
VRe
CeC
MGP
ns
LaDL
ZI
CeL
al
DEn
PaPo vaf
CeM
SI
IMG cst
f
Stg
mfb
BLA LH
PaMP
SPa
AHP MeAD
IM
Acc
3V
VEn
Pe
AHC
MeAV
BMA
opt
VMHA
Pir ACo
sox
TC
CxA
aot
BAOT
ArcD
ArcM
ArcL
SOR
ME
Interaural 6.88 mm
Bregma -2.12 mm
Figure 29 M2
M1
RSA
S1Tr
S1DZ
cg
RSGb
IG
alv
cc df
S1BF
CA1
CA2
dhc
DHC
CA3
LV
ec
MHb
fi
DG
sm
LDVL
LDDM D3V
LHb
st
PV
MDC
MDL
CL
iml
S2
IMD
MDM
VPM
PC
VL
CM
eml
GI Rt
ic
CPu
VPL
IAM
LGP
DI
Rh
Sub
VM
IPAC
rf
mt
Re
AIP
B
AStr
VRe
LaDL
CeL
I
MGP
Xi
cst
ZI
A13
ns DA
DEn
CeC
IMG
SI
Stg
PaPo
CeM
al
AHP
f
Pe
LH BLA
3V
mfb
MeAD BLP
I VMHDM
VEn
Pir
TC
MeAV
BMA
BLV
opt
VMHC
VMHVL
sox ACo
CxA
ArcM BAOT
PLCo
ArcD
ArcL
SOR
MEI
Interaural 6.70 mm
MEE
Bregma -2.30 mm
Figure 30 M2
M1
RSA
S1Tr
S1DZ
RSGb
cg
IG
cc
alv
df
DHC
S1BF
CA1
CA2
dhc
CA3
LV
PoDG
MHb
fi
DG
LDDM
sm
D3V
LDVL
LHb
st ec
PV
MDC
CL
S2
Ang
iml
MDL
Rt
Po
MDM
IMD
MDPL
PC
CPu
VPM GI
CM
eml
VL
ic
VPL
LGP
DI
SubD
Rh
B
rf
IPAC
lab
scp
VM
SubV
AIP
LaVM
B
LaDL
AStr
Re
mt
CeL
VRe
MGP
ZI CeC
cst
LaVL
A13
ns
CeM
SubI
DEn
DA
al
MePD BSTIA
BLA
opt
DMD
LH
mfb
I f
BLP
TC
3V Pe
MeAD VEn
VMHDM
BMA
BMP
BLV
VMHC
sox
MePV
ACo
VMHVL
aot
Pir
PLCo
ArcD
ArcM
ArcL
SOR
Interaural 6.44 mm
MEI
MEE
Bregma -2.56 mm
Figure 31 M1
M2
RSA
S1Tr
S1DZ
RSGb
cg
IG
alv
S1BF
CA1
df
cc
CA2
dhc
CA3
PoDG
LV
DG
fi
LDVL sm
D3V
LDDM
LHb
st
MHb
PV
S2
iml
ec MDC CL
Ang
MDL
Po
Rt
GI
IMD
MDM
PC
VPM
DI
CM
CPu
eml
VPL
VL
ic
Ect
LGP
Rh
SubD
lab
VM
scp
rf
IPAC
SubV
cst
B
Re
PRh
LaDL
AStr
VRe
CeL
mt
MGP
ZI
LaVM
LEnt
CeC A13 CeM
ns
3V
DEn
SubI
LaVL
DA
MCLH
BSTIA al
BLA
BLP
opt
I
MePD
DMD
PeF
LH
mfb
f
VEn
VMHDM
MeAD
BMA
BLV
Pe TC
sox
VMHC
ArcD
MePV
Pir
BMP
ACo
SOR
PLCo
VMHVL
ArcL
Interaural 6.20 mm
ArcM
MEE
MEI
Bregma -2.80 mm
Figure 32 M2
M1
RSA
S1Tr
S1DZ
cg RSGb
alv
IG
CA1
S1BF
df
cc
hf
CA2
dhc
CA3
S2
PoDG
LHbM
LV
LHbL
D3V
sm
fi
LDVL
LDDM
MHb
AuD
LPMR
ec
st
PVP
iml
MDL
MDM
Po
CL
Rt
MDC
IMD
AuV VPM
PC
eml
CPu
CM
VL
VPL
B
Rh
ic Ect
LGP
scp
rf
Sub
VM
AStr ml
st eml
Re
PRh
VRe
CeC
LaDL ZID
mt
CeL A11
LEnt
Do
ZIV
MGP
LaVM
DA
SubI
opt
3V LaVL
ns
DEn
BSTIA
Pe
BLA
mfb
LH
MePD
PeF
DMD
DMC
BLP
f I
sox
MCLH
BMP
I
MePV
VEn
BL
V
VMHC
TC
Pir
PMCo
MTu
BMA
VMHDM
SOR
ArcD
VMHVL
PLCo
ArcM
ArcL
MEE MEI
Interaural 5.86 mm
Bregma -3.14 mm
Figure 33 M2
RSA
M1
S1Tr
S1DZ
RSGb
cg
alv
S1BF
IG
CA1 df
cc
hf
dhc
CA2
FC
S2
CA3
DG
PoDG
LV
MHb
LHbM
AuD
LHbL
LDVL
D3V
sm
LPMR
CPu fi
LDDM
Au1
PVP
st
CL
Rt
IMD
MDC
MDL
Po
iml
AuV
MDM
VPM
ec
VPL
PC
eml
CM
imvc
OPC
LGP
Ect
CPu
ic
ml
VM
scp
st
Re
rf
PRh
ZIV
CeL
VRe
eml ZID LaDL
AStr
LEnt A11
mt
opt
LaVM
CeC
3V
SubI
MGP
LaVL
PH
DEn
BSTIA
ns
MCLH
mfb DMD
LH
BLA
Pe
BLP
PeF
I
MePD
sox
f
VEn
DMV
I DMC
BMP
MePV
Te
BLV
TC
VMHC
Pir
MTu
VMHDM
PMCo
PLCo
ArcD
VMHVL
ArcM
Interaural 5.70 mm
ArcL
MEE
MEI
Bregma -3.30 mm
Figure 34 M2
M1
RSA
S1Tr
RSGb
cg
S1BF
IG
CA1
cc
df
dhc
hf
alv
S2
CA2
PoDG
CA3
DG
AuD
D3V
LHbM
MHb DLG
sm LV
LPMR
LDVL
VLG
ec
LHbL fi
Au1
fr
PVP
Po
iml
CL
st
MDL
ic
Rt
MDM
eml
IMD ic CPu
AuV
VPM
PC
VPL
CM
OPC
rf
Ect
VPPC
ml
A11
AStr
PRh
ZID VM
opt
LaDL
scp
LV
LEnt
ZIV
LaVM
mt
STh
PH
SubI
ns sox
st
LaVL
DEn
Pe
3V
BSTIA
MePD
BLP
LH
mfb PeF
Pir
DMD
BMP
VEn
AHiAL
f
PMCo
BLV
DMV
Te
ArcD
VMHC
PLCo
VMHVL
ArcM
ArcL
Interaural 5.40 mm
InfS
Bregma -3.60 mm
Figure 35 RSA
PtA
RSGb
Or
cg
Py
Rad
LMol
Mol
S1BF
GrDG
IG CA1
alv
df
cc
hf
dhc
CA2
PoDG
AuD
Hil
LHbM
CA3
LHbL
DG
D3V
sm
LPLR
DLG
LPMR
Au1
fi
MHb
VLG
ec
PVP
fr Po
iml
CL
eml
PF
AuV
VPL
st Rt
PoMn
MD
CPu
OPC
ic
TeA
VPM
PF
CM
Ect
VPPC
opt
ml
SPF
rf
PRh VM
ZID
scp
fi
LaDL
ZIV
LEnt
sox
STh
mt
PH
LaVM
LV
LH
ns
mfb
DEn
3V
MePD
BSTIA
Gem
BLP
AHiAL
PSTh
DTM
f BMP
Pir
PMCo
PMV
Te
ArcMP
VTM
ArcLP
PLCo
InfS
af
Interaural 5.20 mm
Bregma -3.80 mm
Figure 36 RSA
PtA
RSGb
cg
IG
S1BF
hf
CA1 df
cc
IBl
dhc
alv
PoDG
CA3
CA2
OBl
AuD
bsc
hbc
DG
IMA
D3V
sm
LPMR LPLR
DLG
LHbL
APTD
Au1
MHb
IGL
VLGPC LHbM
VLGMC
Po
str
fi
AuV
Rt
PVP
PF
fr
VPL
VPM
LV
TeA SubG
ec
opt
pv
Ect
VPPC
ic
ml
SPF
rf
ZID
PR
PRh
scp
F
ZIV
3V
CA3
LEnt
LaDL
PH
ns
LaVM
Gem
STh
DEn
mfb
SMT
PSTh
cp
BLP
SuM
LH
AHiPM
Pir
DG f
AHiAL BMP
PMD DTM
PMCo
MRe
APir
PMV
VTM
ArcMP
ArcLP
PLCo
af
Interaural 4.84 mm
InfS
Bregma -4.16 mm
Figure 37 RSA
V2MM
PtA
RSGb
cg
S1
IG
CA1
cc
df
hf
IBl
dhc
AuD
PoDG
CA2
OBl
DG
hbc
IMA
LPLR
bsc
CA3 D3V
Au1
LPMR
DLG
MHb
VLGPC
APTD
VLGMC
str fi
IGL
ec
PrC
alv
Po
AuV
ar
VPL
PF
VPM
TeA
fr
PVP
SubG
pv
VPPC
opt
SPFPC
Ect
rf
RI
ml
ic
3V
PR
ZID
scp
F
PRh
sox
PH
ZIV
mtg
LV CA3
LEnt
Gem
ns STh
SMT
sumx
mfb
LH
SuM
DEn
cp
pm
BLP
ML
Pir
DG
AHiPM
MMn
f
AHiAL
MM
APir
PMCo
VTM
MRe
PMD
PLCo
af
ArcMP
Interaural 4.70 mm
Bregma -4.30 mm
Figure 38 V2MM
RSA
V2ML
RSGb
PtA
cg
IG
cc
df
CA1
S1
hf
alv
dhc
AuD
PoDG
bsc
DG CA3
CA2
PiRe
LPMC
IMA
hbc
Au1
APTD
OPT
DLG
pc SCO
LPMR
MPT
3V
alv
IGL
str
LPLC
PrC
AuV
APTV
VLGMC
LPLR
Sc
VLGPC
PVP
ar
Po
TeA
VPM
PF
ec
Eth
SPFPC
pv
Ect
SubG
CA2
fr
opt
ic
ml
fr
ZID
PRh
CA3 scp PR
RI
rf
PH
sox
3V
F
ZIV
LEnt
mtg
LV
SNR
sumx
ns
DEn
LH
Gem
SuM
mfb
cp
BLP
pm
Pir
DG
MMn
f
AHiPM
MM
LM
VTM
ML APir
PMCo
MRe
PLCo
ArcMP
af
Interaural 4.48 mm
Bregma -4.52 mm
Figure 39 V2MM
RSA
V2ML
V2L
RSGb
cg
alv
PtA
df
scc
CA1
AuD hf
dhc
PoDG
DG
Au1
bsc
OT
LPMC
OPT
IMA
MPT
APTD
hbc
LPLC
PLi
DLG
PCom
PLi
pc
AuV
CA2
SG
MGD
str
SCO
APTV IGL dlf
MGM
SCom
alv TeA
MCPC
MGV VLGPC
PAG
VLGMC PoT
PIL ctg
opt
Eth
CA3
LT
Dk
Ect
IMLF
SPFPC
3V
PRh
PR
scp
rf
ml
CA1
fr
ZIV
ZID
mtg
RI
sumx
SNR
PBP
ns
LH
DEn
SNCD
LEnt
SuMM
SuML
mp
mfb BLP
mt cp
f
DG
APir
AHiPM
MM
LM ML
PMCo
af
Interaural 4.20 mm
Bregma -4.80 mm
Figure 40 RSA
V2MM
V2ML
V2L
RSGb
cg
alv
scc
PtA
CA1
FC
dhc
AuD
hf
PoDG
DG
PiRe
Au1
bsc
OT
PPT
LPMC
MPT
OPT
IMA
csc
LPLC
APTD
DLG
PAG
pc
PCom
MGD
AuV
CA2
PLi
SG
CA3
dlf
opt
MCPC
alv
PAG
Aq
MGV
MZMG TeA
PoT ctg
APTV
dtg
IMLFG
MGM
PIL Dk
PP CA1
SPFPC EW
Ect
DpMe
REth
IMLF MA3
PRh
rf
LT
SNL
scp PR
ZI
ml
PBP
RLi
mtg
SNRVL
VTRZ
vtgx
fr
PBP
SNCD
LEnt
IF
SNM
VTA
SNRDM
PN
DEn
IPF MT
mp
cp
APir
MM
AHiPM
af
PMCo
Interaural 3.80 mm
Bregma -5.20 mm
Figure 41 RSA
V2MM
V2ML
RSGb
cg
V2L
CA1
scc
PtA
dhc
FC
hf
AuD
S
PiRe
alv
PoDG
DG
SC bsc
LPLC
MPT OT
PPT
Au1
LPMC
SC
OPT
csc
DLG IMA
DMPAG
pc
APTD
PCom
SG MGD
opt
AuV dlf
PLi
CA3
alv
LPAG
Aq
MGV
ctg
MCPC
MZMG
CA2
dtg
MGM
APTV TeA
PoT
Dk
IMLFG
IMLF
PIL
EW
DpMe
Ect
PP
REth
LT
SPFPC
MA3
PRh
CA1
rf
SNL
scp
ml
PBP
RPC
RLi
mtg
vtgx
SNCD
VTRZ
PBP
fr
IF SNR
VTA
DEn
PN
MT
IPF mp
aopt LEnt
DG
cp
APir
MM
AHiPM
af
PMCo
Interaural 3.70 mm
Bregma -5.30 mm
Figure 42 V2MM
RSA
V2ML
V1M
V1B
cg
RSGb
V2L
fmj
Post
RSGa
PtA
CA1
hf
S
Zo
alv
AuD
SuG
Op
PoDG
InG
DG
bsc
Au1
OT
InWh csc
PPT
LPMC
DMPAG
DpG
DpWh
PLi
DLPAG
AuV MGD
dlf
LPAG
SG
Aq
CA2
MZMG
MGV
alv
APT
TeA EW
CA3
dtg ctg
Dk
IMLFG
MGM
MA3
DpMe
PoT
IMLF
mlf
PP PIL
PaR
Ect
mtg
LT
SNL
Min
rf
scp RPC
ELm
PRh
VTRZ
RMC
RLi
ml
CA1
SNR
vtgx
DEn
PBP
SNCD
hf
IPDM
VTA
IF
3n
LEnt
PN
SNM
AHiPM
IPR APir
mp
fr
cp
IPC
IPRL
PMCo
3n
MM
af
Interaural 3.40 mm*
Bregma -5.60 mm
Figure 43 V2MM
V2ML
RSA
V1M
V1B
cg
RSGb
fmj
V2L
RSGa
S
Zo
Post
PtA
hf
SuG
AuD
Op
DG
PoDG
alv
InG
CA1
csc
InWh
OT
Au1
bsc
DMPAG
DLPAG
PPT
DpG
LPMC
PLi
alv
DpWh
MGD
dlf
SG
CA3
Aq
LPAG
AuV
MGV
CA2
MZMG
IMLF
Dk
EW
APT
dtg
MGM
ctg
TeA
IMLFG
PoT
DpMe
MA3
PIL
PP
mlf
Ect
PaR
SNL
Min
R
rf
PRh
scp
RLi
ELm
CA1
vtgx
SNR
mtg
PBP hf
DEn
ml
IPDM
VTA
SNCD
IF
PN
LEnt
S
APir SNM
3n
IPR
4n
AHiPM
mp
cp
IPC
IPRL 3n PMCo
af
Interaural 3.20 mm*
Bregma -5.80 mm
Figure 44 V2MM
RSA
V2ML
V1M
V1B
RSGb fmj
V2L
RSGa
Zo
Post
S
SuG
Op
AuD
DG
InG
PoDG
csc InWh
OT
DT bsc
alv
Au1
DpG
DMPAG
dlf
DpWh
DLPAG
MGD
CA2
LPAG
SG
Aq
Su3C CA3
bic
AuV MZMG
EW
MGM
dtg
MGV
IMLFG
hf Su3
3PC
DpMe
IMLF
TeA
PIL
3 ctg
PP mlf RLi
SNL Ect
dtgx
scp
PaR
RPC
SNCD
vtgx
rf
PRh
RMC
CA1
DG
SNR
PBP
3n
mtg
CLi
DEn
SNCV
VTA
LEnt
IPDM
ml
IPDL
SNM
IPR
AHiPM
APir
cp
IPL
IPI
PMCo
IPC
af
Interaural 2.96 mm*
Bregma -6.04 mm
Figure 45
V2ML
V2MM
RSA
V1M
V1B
RSGb
fmj
V2L
RSGa
Zo
Post
SuG
S
Op
InG
AuD
csc
DpG
DpWh
DMPAG
InWh
Au1
CA1
bsc
dlf
DT
PoDG
DLPAG MGD
AuV
hf
DG
Hil
Aq
LPAG
SG
TeA Su3C
MGV
bic EW
IMLF
ctg
Su3
3PC
MGM
ltg
dtg DpMe
IMLFG
Ect
3
mlf
SubB
PaR
PRh
S
dtgx
RPC
scp
rf
PrS
RMC
vtgx
mtg
RRF
PaS
rs
MEntV
CLi
SNR
IPDM
VTA
SNCD
ml
IPDL
IPR
LEnt
IPL
cp
s5
IPC
IPI
tfp
bas
Interaural 2.70 mm
Bregma -6.30 mm
Figure 46 V2MM
V2ML
RSA
V1M
V1B
RSGb
fmj
RSGa
Zo
V2L
SuG
Post
Op
S
InG
InWh
DpG
hf
DMPAG
DG
dlf
DpWh bsc
DLPAG
TeA
Me5
bic me5
CA1
Aq
LPAG
Su3C
BIC
ts
EW
Su3 ltg
3PC
ctg
MG
DpMe
dtg
3
SubB Ect
PrS mlf
dtgx
PRh
S
PaS
rf
mtg
RRF
A8
CLi
scp PPTg
MEnt
xscp IPDM
rs
VTA
LEnt
B9
IPA
cp
ml
IPL
s5
m5
bp
IPI
IPC
Pn
tfp
Interaural 2.28 mm
bas
Bregma -6.72 mm
Figure 47 V2ML
V2MM
V1M
RSA
V1B
RSGb
fmj
RSGa
Zo
SuG
Post
V2L
Op
InG
InWh
DpG
CA1
bsc
DpWh
DMPAG
dlf
GrDG
DLPAG
hf
S
TeA DG
bic
Aq
me5
LPAG
Me5
Su3C
BIC MG
EW
ts
Su3
ctg ltg
Ect
3PC
dtg
DpMe
3
PrS
SubB
mlf
PRh
mtg PaS
dtgx
rf
RRF
A8
CLi
xscp
Dsc
PPTg
MEnt
IPDM Rbd
cp
rs
VTA LEnt
B9
IPA
tth
IPL
ml
s5
IPC
m5
IPI
bp
Pn
tfp
Interaural 2.20 mm
bas
Bregma -6.80 mm
Figure 48 V2MM
V1M
RSA
V1B
RSGb
RSGa
fmj
Zo
SuG
V2L
Op
Post
InG
InWh
DpG
bsc
DpWh DMPAG
dlf
hf
DLPAG
TeA
Me5
S me5
Aq
LPAG
bic
Su3C
BIC DR
ltg
ts
PrS
Su3
3PC
ctg
Ect
DpMe
dtg
I3
3
SubB
PaS
PRh mlf
MiTg
A8
RRF
ts
CLi
PBG
mtg
Dsc
PPTg
rf
xscp
MEnt
RR
LEnt
Rbd
ipt
rs
IPA
IPL
B9
cp
tth
bp
s5
ml
IPI
IPC
m5
Pn
tfp
Interaural 1.96 mm
bas
Bregma -7.04 mm
Figure 49 V2MM
V1M
RSA
V1B
RSGb
RSGa
Zo
fmj
SuG
V2L
Op
InG
InWh
Post
DpG
DMPAG
TeA dlf
DpWh
DLPAG
PrS
Aq
BIC
S
LPAG InCo
bic
me5
Me5
DRD
Su3C
Ect ltg
ts
Su3
SubB
PaS
3PC
DpMe
ctg
DRV
dtg
PBG PRh
4
MiTg
Pa4
mlf
rf
CLi
Dsc
PL
RR
PPTg
xscp
MEnt
LEnt
ipt
Rbd
PnO
rs
ll
MnR
RtTg
mcp
s5
B9
tth
ml
lfp
Pn
m5
Pn
bp
tfp
Interaural 1.70 mm
bas
Bregma -7.30 mm
Figure 50 V2MM
RSA
V1M
V1B
RSGb
RSGa
Zo
V2L
SuG
fmj
Op
InG
InWh
Post
DpG
TeA
DMPAG
DpWh
PrS
dlf
DLPAG
BIC
InCo
Aq
LPAG
ECIC
bic
Ect
me5
PaS
Me5 VLPAG
DRD
ll
DpMe
PRh DRVL
ctg
dtg
MiTg
DRV
Pa4
mlf PBG
CLi
PPTg
Dsc
rf
RR
xscp
SPTg
MEnt
Rbd
LEnt
ATg
PL
ERS
ts
rs
PnO
VLL
s5
mcp
PMnR
ll
RtTgP
MnR
tth
m5
RtTg
B9
ml
bp lfp
Pn
Interaural 1.36 mm
tfp
bas
Bregma -7.64 mm
Figure 51 V2MM
V1M
RSA
V1B
RSGb
RSGa
Zo
V2L
SuG
Post
fmj
Op
InG
InWh
DpG
TeA
PrS
ECIC
DpWh
DMPAG 1
1
2
DLPAG
InCo
BIC
PaS
Ect
Aq
LPAG
bic
me5
Me5
PRh
VLPAG
ll
DRD
DpMe
DRVL
MiTg
dtg
Dsc
DRV
PBG
MEnt
mlf
PPTg
xscp
LEnt
Rbd
SPTg
ILL
PL
ts
ATg
mcp
PMnR
rs
VLL PnO
MnR
s5
RtTg
RtTgP
m5 B9
DMPn
tth
ll
DLPn
ml
m5
DPPn
lfp
VPPn
LPn
MPn
Interaural 1.20 mm
VMPn
bp
tfp
bas
Bregma -7.80 mm
Figure 52 V1M
V2MM
V1B
RSA
RSGa
fmj
V2L
Zo
SuG
Op
Post
InG
InWh
TeA
DpG
DpWh
ECIC
DMPAG
2
InCo
DLPAG
PaS
Ect
Aq
LPAG
BIC
me5
Me5
bic
VLPAG
Dsc
CnF
ll DRD
4n
DRVL
MiTg
PRh
DpMe
DRV dtg
rf
PBG
MEnt
mlf
LEnt
scp
cll
xscp
PPTg
Rbd
SPTg
ILL
ATg
PL
MnR
ts
PnO
PMnR
rs
mcp
VLL
s5
RtTgP
VLTg
RtTg
m5
ll
tth
ml
RPO
lfp
bp
Pn
tfp
Interaural 1.00 mm
bas
Bregma -8.00 mm
Figure 53 V1M
V2MM
V1B
Pi
RSA
RSGa
V2L
TeA
Post
cic
PaS
1
ECIC
Ect
DMPAG
2
Dsc
3
DLPAG
Aq
LPAG PRh
me5
Me5
MEnt VLPAG
DRVL
CnF
4n
ll
LEnt
DRD PPTg
DLL
dtg
DRV
Rbd
cll
scp
mlf
DRI
PL
ILL
SPTg
VLL
VTg
mcp
PMnR
ll
PnO
ts
MnR
rs
ll
m5
s5
VLTg
vsc
tz
RtTg
VLL
ll
RtTgP
tth
ll
Tz
ml
RPO
py
Interaural 0.70 mm
bas
Bregma -8.30 mm
Figure 54
V1M
V1B
V2L
DCIC
RSA
TeA
cic
Ect
PaS
DMPAG
PRh
ECIC
ReIC
Dsc
CIC
1
2
3
LPAG
MEnt
LEnt
2
Sag
Me5
me5
ll
VLPAG
CnF
4n
cll
LDTg
LPBS
LPBC
dtg
DLL
DRC
scp
DTgP
LPBE
vsc
mcp
MPB
LDTgV
mlf
DMTg
VTg
KF
DRI
SubCD
PnR
A7
ts
P5
s5
PnO PC5
m5
SubCV
Pr5
rs
MSO RtTg
vsc
tz
A5
RPO
tth
SPO
ml
Tz
LVPO
tz
py
MVPO
bas
Interaural 0.28 mm
Bregma -8.72 mm
Figure 55 V1M
V1B
V2L
RSA
DCIC
cic
Ect
DMPAG
PaS
PRh
CIC
ECIC
ReIC
1
3
2
MEnt
LPAG
4n
2
MEnt
Sag
Cb
Me5
me5
ll
CnF
4n
LPBS
LPBC
LDTg
DRC
dtg
DLL
DTgP
scp
LPBE
vsc
VTg
MPB
mcp
LDTgV
mlf
KF
SubCD
DRI
DMTg
Su5
DMTg
A7
VCA
PC5
Mo5
ts
P5
PnR
PnO
s5
Pr5VL
m5
RtTg
SubCV
rs
DPO
tz
A5
LSO
SPO
tth
ml
MSO
Tz
vsc
tz
LVPO
MVPO
py
bas
Interaural 0.20 mm
Bregma -8.80 mm
Figure 56 V1M
V1B
Cb
1
V2L
2
DCIC
RSA
3
cic
Ect
PaS
ReIC
PRh
ECIC
MEnt
1
CIC
2
3
3
4
2
Sag
LPBV
LPBI
4n
LPBD
SMV
RL
4V
2&3
LC
LPBCr
LPBC
LDTg
vsc
scp
Me5
Bar
mcp
LPBE
me5
MPB
DTgP
MPBE
DRC
DTgC
Su5 KF
SubCA
mlf
PnR
SubCD
VCA
Mo5DL
DMTg
P5
I5
ts
m5 Mo5VM s5
Pr5VL
RtTg
SubCV
PnC
A5
DPO
rs
PnV
tth
RMg
LSO
6n
tz
SPO
MSO
ml
Tz
tz
LVPO
vsc
MVPO
py
bas
Interaural -0.16 mm
Bregma -9.16 mm
Figure 57 V1M
Cb
V1B
V2L RSA
DCIC
PaS
Ect
PRh
MEnt
ReIC
CIC
ECIC
3
2
1
3
Sim
4
2
PCTg
LPBI
LPBD
LPBV
4n
4V
LPBC
SMV
DRC
LPBE
2&3
vsc
LPBCr
LC
LDTg
Me5
scp
DTgC
Bar
me5
MPB
mcp
CGB DTgP
MPBE Pr5DM
LR4V
SubCA
scpd
Su5
chp
CGA
mlf
Mo5DL
DMTg
SubCD
P5
VCA
Mo5VM
PFl
I5
ts
PnR
Pr5VL
RtTg
m5
s5
SubCV
PnC
RIP
A5
DPO
PnV
rs
RMg
tth
LSO
SPO
ml
vsc
MSO
Tz
tz
py
LVPO
MVPO
bas
Interaural -0.30 mm
Bregma -9.30 mm
Figure 58 5
Cx
4
DCIC
CIC
3
Sim
prf
Crus1
ECIC
PCTg
3
4&5
2
LPBV LPBV
LPBC LPBC
PFl LPBE
LPBE
LC
plf
vsc
4V
1
PCGS SMV
mcp
scp
CGPn
MPB
Bar
Fl
Sph
me5 Me5
LR4V
PDTg
CGB
Su5
SubCA
I5
Pr5DM
CGA
O
SGl
scpd
II
mlf
SubCD
P5
DMTg
m5
Mo5
VCA
Acs5 s5
ts
ocb
pd
Pr5VL
SubCV
Jx5
PnC
RIP
8vn
7n
DPO
A5
PnV tz
LSO RMg
rs
tth
SPO
tz
Tz
ml
MSO
LVPO
py vsc MVPO
bas
Interaural -0.68 mm
Bregma -9.68 mm
Figure 59 5
Cx
4
DCIC
ECIC
3
psf
prf
Crus1
Sim
2
LPBV
PBW
vsc
plf
LC
1
PFl
4V
mcp
SMV
scp
Sph
PCGS
LR4V
Bar
Fl
MPB
Me5
me5
PDTg
CGB
Pr5DM SubCA
O
CGA
P5
II
SubCD
mlf
DMTg
Mo5
VCA
m5
sp5
Acs5
ts
pd
ocb
SubCV
Pr5VL
PnC
8vn
RIP
Acs6
7n
A5
DPO
rs
PnV
RMg
tth tz
tz
LSO
SPO
RPa
ml
Tz
vsc
MSO
LVPO py
MVPO
bas
Interaural -0.80 mm
Bregma -9.80 mm
Figure 60 5
SimA
SimB
4
pcuf
prf
Sim
psf
3
Crus1
pfs
2
mcp
plf
PFl
MPB
icp
1
unc
vsc
LPBV
scp
LC
SMV
SuVe
4V
LR4V Bar
me5 PDTg
Me5
MVeMC
Fl
CGG
PCGS
prb
8vn
SGl
CGA
veme
plf
CGB
Pr5DM
VCA
6
P5
mlf
ocb
Pa6
PCRtA
I8
sp5
8cn
ts
IS
7n
Pr5VL
IRt
pd
PnC
Acs6
A5
rs
RMg
PnV
tz
MSO
LSO
tth
tz
SPO
RPa
vsc
ml
Tz
py
LVPO
bas
MVPO
Interaural -1.04 mm
Bregma -10.04 mm
Figure 61
6
prf
simf
5
4
Sim
pcuf
Crus1
psf
3
pfs
2
unc
PFl
scp
plf
LC
1
SGl
Fl
icp
LR4V
SuVe
SMV
DC
MVePC
8vn
4V
plf
SGe
LVe
MVeMC
VCA
CGPn
g7
ocb
EVe
prb
DMSp5
PCRtA
mlf
6
7n
sp5
Sp5O
I8
Pa6
IS
pd
8cn
PnC
ts
8Gn
IRt
Pr5VL
Acs7
SuS
Gi
A5
P7
rs
tz
7
GiA
LPGi
RMg
7
tth
ml
RPa
CPO
vsc
py
bas
Interaural -1.30 mm
Bregma -10.30 mm
Figure 62
6
simf
prf
5
Sim
4
psf
pcuf
Crus1
3
2
pfs
Lat
unc
PFl
scp
1
A4
SuVe
LC
Fl
SMV
plf
MVePC
DC
icp
LR4V
LVe
MVeMC
4V
8vn
VCA
GrC
SGe
g7
mlf
6
prb
VCP
PCRtA
Pa6
DMSp5
IS
sp5
Sp5O
pd
IRt
SuS
ts
Acs7
Gi
6n
P7
A5
GiA
LPGi rs 7
RMg
tz
tth
ml
PPy
vsc
RPa
py
bas
Interaural -1.52 mm
Bregma -10.52 mm
Figure 63
6
prf
simf
Sim
5
psf
4
pcuf
Crus1
2&3
pfs
Lat
IntA
scp
jx
Y
1
VeCb
LR4V
SuVe
A4
PFl
icp
MVePC
SMV
LVe
DC
4V
Pr
MVeMC
8vn
g7
CI
mlf
GrC
6
Sol
lvs
8n
VCP
sp5
IS
DPGi
DMSp5
PCRtA
IRt
pd
Acs7
Sp5O
ts
SuS
Gi
P7
rs
A5
LPGi
7
RMg
GiA
tz
ml
PPy
vsc
RPa
py
bas
Interaural -1.80 mm
Bregma -10.80 mm
Figure 64
6
prf
5
Sim
psf
4
Crus1
pcuf
5
pfs
2&3
IntA
Lat
Lat
scp
Inf
Y
VeCb
Y
SuVe
LR4V
1
A4
PFl
LR4V
LVe
das
icp MVePC
DC
icp
SMV
4V
SpVe
X
Pr
MVeMC
GrC
CI
SolRL
g7
8n
VCP
mlf
IS
DPGi
sp5
IRt
DMSp5D
Acs7
pd
Sp5O
DMSp5V
PCRtA
ts
Gi
tz
rs
7
LPGi
GiA
A5
RMg
P7
vsc
ml
PPy
RPa
py
bas
Interaural -2.00 mm
Bregma -11.00 mm
Figure 65 6
prf
psf
Sim
4&5
Crus1
pcuf IntDL
IntDM
IntA
Lat
IntA
2&3
Inf
LatPC
VeCb
Y
A4
4V
LVe
DC
LR4V
jx
das
PFl
1
SMV
MVePC
icp
X
SpVe
4V
MVeMC
Pr
sol
8n
mlf
VCP
asc7
GrC
CI
DMSp5D
SolIM
sp5
SolRL
pd
PCRtA
DMSp5V
DPGi
IRt IS
ts
Sp5O
Acs7
Gi
P7
7DL
7DM
ROb
7DI
rs
7
7L
LPGi
7VI
RMg
GiA
7VM
PPy
ml
vsc
C1
R
VL
py
RPa
bas
Interaural -2.30 mm
Bregma -11.30 mm
Figure 66 simf
6
psf
Sim
prf
Crus1
4&5
icf
MedDL
Crus2
IntDM
IntA
2&3
IntP
Lat
Med
IntPPC
LatPC
IntPPC
DC
PFl
1
ECu
LR4V
SpVe
MVePC
icp
X
8n
4V
MVeMC
SolIM
Pr
SolM
C3
SolRL
sol
B4
CI
IS DMSp5D
sp5
mlf
SolVL
IRt
PCRt
DPGi
pd
DMSp5V
Sp5O
ts
Amb
Gi
ROb
P7
rs
7
LPGi
GiA
RMg
7
PPy
RVL
ml
C1
vsc
RPa
py
bas
Interaural -2.60 mm
Bregma -11.60 mm
Figure 67 6
prf
Crus1
icf
Med
Crus2
IntP
plf
Cop
PFl
10
ECu
SpVe
MVePC
4V
X
LR4V
icp
SolIM
Pr
SolM
MVeMC
C3
sol
PFl
B4
sp5
mlf
DMSp5D
EF
SolVL
DMSp5V
CI
DPGi
pd
PCRt
IRt
Sp5I ts
ROb
Amb
Gi
rs
Bo
10n
R
VL
ml C1
IOD
GiV
LPGi
MRVL
vsc
RPa
py
IOM
Interaural -2.80 mm
IOPr
Bregma -11.80 mm
Figure 68 6
prf
Crus1
icf
Crus2
plf
Cop
10
PFl
LR4V
ECu
SpVe
icp
MVePC
4V
X
C3
Pr sol
MVeMC
SolM
B4
DMSp5
EF
SolVL
mlf
SolIM
sp5
CI
DPGi
PCRt
pd
Sp5I
IRt
Gi
ts
Amb
ROb
Bo
rs
RVL
C1
ml
GiV
IOD
vsc
LPGi
MRVL
IOPr
RPa
py
IOM
Interaural -2.96 mm
Bregma -11.96 mm
Figure 69 6
Crus1
7
icf
8
Crus2
9
PM
plf
Cop
10
LR4V
ECu
SpVe
icp
MVe
X
4V
FVe
SolM
sp5
sol Pr
DMSp5
C3
SolIM
B4
C2
mlf
EF
SolVL CI
DPGi
PCRt
IRt
Li
Sp5I
pd
Amb
ts Gi
rs
PrBo
GiV RVL
C1
ml
ROb
IOD
LPGi
vsc
IOM
RPa
py IOPr
Interaural -3.30 mm
Bregma -12.30 mm
Figure 70
6
Crus1
7
icf
ppf
Crus2
8
sf
9
plf
PM
Cop
10
pms
ECu
Pa5 FVe
MVe
icp
Cu
SolIM
X
sol
SolM
In
C2
E5 DMSp5
SolVL
12
C3
10
Ro
B4
sp5
mlf
PCRt
Sp5I
CI DPGi
IRt
PMn
ts
Li
Amb
Gi
rs
RVRG
dsc/oc
RVL
ml
ROb
GiV
C1
LPGi
IOD
vsc
IOM
IODM
IOPr RPa
py
Interaural -3.72 mm
Bregma -12.72 mm
Figure 71
6
pms
Crus1
icf
7
ppf
Crus2
8
sf
9
plf
Cop
PM
pms
10
ECu
icp
MVe
Cu
sol
SolM Pa5
Pa5
X
SolIM
C2
In
SolVL
DMSp5
E5
C3
10 12
Ro
sp5
mlf
DPGi
PCRt
IRt
Sp5I
PMn
Gi
ts
12n
rs
RVRG
Amb
RVL/CVL
C1/A1
ml
ROb
dsc/oc GiV
IODM
LPGi
vsc
IOD
IOM
RPa
py
IOPr
Interaural -3.80 mm
Bregma -12.80 mm
Figure 72
pms
7
ppf
Crus2
8
sf
apmf
9
PM
uf
Cop
9
plf pms
10
ECu
SolDM
cu
SolG
Z
PSol
Cu
C2
chp
icp
SolM
Pa5
sol
4V
SolIM
SolI
10
sp5
SolVL
SolCe
12
Sp5I
Ro
mlf
PCRt
ROb
IRt
PMn
RVRG
ts
Amb
Gi
12n rs
LRtS5 ml
IOBe
IOVL
dsc/oc
C1/A1
R
VL/CVL
IOD
LRt
vsc
LRtPC
IOPr
IOB
IOC
RPa
py
IOA
Interaural -4.24 mm
Bregma -13.24 mm
Figure 73
pms
7
ppf
Crus2
8
sf
apmf
9
PM
pms
Cop
plf
10
ECu
SolG
SolDM
SolIM
Pa5
cu
PSol
sol
Cu
C2
sp5
SolCe
SolM
SolI
10
SolVL
12
Sp5I
PCRt
Ro
ROb
IRt
mlf
PMn
Gi Amb
RVRG
rs
RVL/CVL
ts
dsc/oc
LRtS5
C1/A1
ml
12n
IOBe
IOVL
LRt
IOD
vsc
IOC
LRtPC
RPa
IOB IOPr
py
IOA
Interaural -4.30 mm
Bregma -13.30 mm
Figure 74
7
pms
ppf
8
Crus2
sf
9
apmf
PM
Cop
9
pms
10
ECu
SolDM
cu
Gr
Cu
SolIM
AP
PSol
sol A2
Sp5C
SolC
sp5
SolI
10 SolVL
SolCe
SolM
CC
12
MdD
InM
Ro
IRt
mlf
PMn
Amb Sp5I
RVRG
ROb
MdV
ts
rs
IOK
dsc/oc
C1/A1
LRtS5
12n
RVL/CVL
ml
IOD
IOBe
LRt IOA
IOC
RPa LRtPC
vsc
py
Interaural -4.68 mm
IOB
Bregma -13.68 mm
Figure 75
7
ppf
8
pms
pf
Crus2
8
sf
apmf
PM
9
Cop
pms
ECu
cu
Gr
gr
Cu
SolDM
SolI
AP
sp5
A2 SolC
sol
10
SolVL Sp5C
ia
SolM
SolIM CC
12 MdD
IRt
Ge5
Ro
RVRG
PMn
Amb ROb
CVRG
mlf
Sp5I
MdV
IOK ts
rs
12n
IOBe
ml
A1
RVL/CVL
LRtS5
dsc
IOD
LRt
IOC
RPa
IOB
LRtPC
py
vsc
IOA
Interaural -4.80 mm
Bregma -13.80 mm
Figure 76
ppf
8
sf
9
PM
pms
Cop
9
cu
Gr
gr Cu
SolDM
SolM
AP
sp5
SolI
A2
SolC
sol
10 SolVL
CC
Sp5C
SolIM
12
MdD
ia
RAmb
mlf
PMn
ROb
MdV
ts
IOK
CVRG
CVL
12n rs
A1
dsc
LRt
IOBe
RPa
IOC
IOA
LRtPC
vsc
IOB
py
Interaural -5.08 mm
Bregma -14.08 mm
Figure 77
8
sf
9
PM
Cop
9
Obex
cu
Gr
Cu
gr
SolC
Sol
10 A2
sol
sp5
CC
Sp5C
MdD
12
IRt
CVRG
mlf
ROb
MdV
CVL
A1
RAmb
rs
ts
12n
dsc
LRt
ml
LRtPC
pyx
vsc
RPa
IOM
Interaural -5.30 mm
Bregma -14.30 mm
Figure 78
9
9
cu
Gr
MnA
Cu
gr
SolC
sol Sol
sp5
A2
10
MdD Sp5C
12
CC IRt
RAmb
mlf
MdV
CVRG
rs
A1
ts
CVL
sc
pyx
LRt
IOM
LRtPC
Interaural -5.60 mm
Bregma -14.60 mm
Lateral -0.10 mm
Figure 79
Lateral 0.40 mm
Figure 80
IO
Lateral 0.90 mm
IO
Figure 81
Lateral 1.40 mm
Figure 82
Lateral 1.90 mm
Figure 83
Lateral 2.40 mm
Figure 84
Lateral 2.90 mm
Figure 85
Lateral 3.40 mm
Figure 86
Lateral 3.90 mm
Figure 87
Lateral 4.20 mm
Figure 88
Lateral 4.60 mm
Figure 89
Bregma -9.60 mm
Interaural 0.40 mm
Figure 90
Bregma -9.22 mm
Interaural 0.78 mm
Figure 91
Bregma -9.10 mm
Interaural 0.90 mm
Figure 92
Bregma -8.82 mm
Interaural 1.18 mm
Figure 93
Bregma -8.60 mm
Interaural 1.40 mm
Figure 94
Bregma -8.42 mm
Interaural 1.58 mm
Figure 95
Bregma -8.10 mm
Interaural 1.90 mm
Figure 96
Bregma -7.80 mm
Interaural 2.20 mm
Figure 97
Bregma -7.60 mm
Interaural 2.40 mm
Figure 98
Bregma -7.34 mm
Interaural 2.66 mm
Figure 99
Bregma -7.10 mm
Interaural 2.90 mm
Figure 100
Bregma -6.82 mm
Interaural 3.18 mm
Figure 101
Bregma -6.60 mm
Interaural 3.40 mm
Figure 102
Bregma -6.38 mm
Interaural 3.62 mm
Figure 103
Bregma -6.10 mm
Interaural 3.90 mm
Figure 104
Bregma -5.82 mm
Interaural 4.18 mm
Figure 105
Bregma -5.60 mm
Interaural 4.40 mm
Figure 106
Bregma -5.32 mm
Interaural 4.68 mm
Figure 107
Bregma -5.10 mm
Interaural 4.90 mm
Figure 108
Bregma -4.74 mm
Interaural 5.26 mm
Figure 109
Bregma -4.60 mm
Interaural 5.40 mm
Figure 110
Bregma -4.28 mm
Interaural 5.72 mm
Figure 111
Bregma -4.10 mm
Interaural 5.90 mm
Figure 112
Bregma -3.86 mm
Interaural 6.14 mm
Figure 113
Bregma -3.60 mm
Interaural 6.40 mm
Figure 114
Bregma -3.38 mm
Interaural 6.62 mm
Figure 115
Bregma -3.10 mm
Interaural 6.90 mm
Figure 116
1
Figure 117a*
2
1
dl
dl
1
2
3
3
2
4
3
4
C4 C7
C1 LSp
4
LSp
py
5
py
5
py
5
6
CeCv
10 10
6
IMM
10
7
7
LSp
IMM IMM
7
9
LatC
9
8
9
8 9
8
9
9
9
9 9
9
1
dl
dl 1
2
2
3
3
dl
4
4
C5
1 LSp
C2
C8
2
5
4
3
py
LSp
5
6
LSp py
LatC
5
10
10
py
7
CeCv
IMM
6
7
9
IMM
9
7
IMM
9
9 8
10
9
8
9 9
9
8
9
9
9
9
9
1
dl
2
dl
C6
C3
1
3
T1
2
4
3
1
dl
2
4
LSp
3
py 5
LatC LSp
4
5
py
5
6
IML
LSp
py
10
6
CeCv
7
IMM
9
IMM
7
7 IMM
10
10
9
8
8
8
9 9
9
9
9
9
9
Figure 117b*
1
dl
1
dl
dl
1
1 2 2
L4
3 2
L1
4 3
2
dl T3
S1
3
3 4
py
4
LSp py
4
5
LSp LSp
5
5
5
D
py LSp py
IML
6 IML
6
10
D 7
7
10
10
IMM IMM
9
7
8
10
IMM
IMM 7
9
9
9
8
9
8
9
9
8
9
9
9
9
9
1
2
3
py
4
S2
dl 1 dl
L5 1
L2
2
5
T5
2
LSp
3
4
dl
py
3
1
4
10
LSp
2
5 7
3 5
py
LSp
4
IMM
D
LSp
6
5
IML
10 10
8
IML
py
7
9
IMM
7
IMM
9
7
D
9
IMM
8
8
10
8
9
9
9
9
9
9
1
2
S3
py
dl
3
4
LSp
5
10
7
IMM
8
1 dl
1
9
3
L6
L3 dl
2
3 4
2
T10
4
py
LSp
1
dl
5
5
2
py
4
3
LSp
6
6
IML
LSp
1
5 S4
2
10
py
3
7
IMM
10 4
7
IML
IMM D 9
10
9
7
LSp
5
IMM
8
9
8 8
10
9
7
9
9
9
9
9
IMM
8
9
Go to START PAGE 5
4
3
2
1
0
-1
-2
-3
-4
-5
-6
-7
Bregma
-8
-9
-10
-11
-12
-15
Pineal 6
5
6 6
Corpus Callosum
4
Inferior Superior Colliculus Colliculus
Hippocampus
7 3
3V Fornix
Posterior Commissure
8 Cerebellum
4V
2
Thalamus
Septum
9
Midbrain
1
Anterior Commissure Olfactory Tubercle
-14
Lambda
Cerebral Cortex
Olfactory Bulb
-13
Preoptic Area
Hypothalamus
4V
Pons
9
10
Medulla Oblongata
Optic Chiasm Spinal Cord
Pituitary
Lateral 0.40 mm 14
13
12
11
Interaural 10
9
8
7
6
5
4
3
2
1
0
-1
-2
-3
-4
Click on sagittal diagram to go the corresponding coronal diagram
-5
-6
Go to START PAGE 7
6
5
4
3
2
1
0
1
2
3
6
5
4
7
Corpus Callosum Somatosesnory Cortex Barrel Field
Hippocampus Lateral Ventrical
S2
Auditory Cortex
Mediodorsal Nu
Internal Capsule
VPM
Caudate Putamen (Striatum)
VPL
Thalamus
Hypothalamus
Amygdala Optic Tract
Amygdala
Fornix Piriform Cortex
Lateral Hypothalamus 3rd Ventricle 7
6
5
4
3
2
1
Ventromedial Hy Nu 0
1
2
3
4
5
6
7
Click on Coronal diagram to go the corresponding sagittal diagram
Go to START PAGE
Bregma
10
9
1
Pineal
Cerebral Cortex
Hippocampus
6
Posterior Commissure
4V
Thalamus
Septum
Olfactory Tubercle
1
Preoptic Area
Cerebellum
5
2
9 1
Anterior Commissure
2
4
8
6
Midbrain
3
3
7 3
Fornix Olfactory Bulb
2
4
Inferior Superior Colliculus Colliculus
3V
5
6 6
Corpus Callosum
4
6
5
8
7
0
4V
10
9 7
8
Hypothalamus
Pons
Medulla Oblongata
9
Optic Chiasm 0
Interaural Pituitary
-1
Spinal Cord
10
11
Lateral 0.40 mm
Click on sagittal diagram to go the corresponding horizontal diagram
Figure 1
E/OV
GrO aci
EPl
Mi
Gl
IPl
ON
Interaural 15.70 mm
Bregma 6.70 mm
Figure 2
GrA
vn
AOB
dlo
AOE
GrA
lo
aci
AOL
E/OV
GrO
Gl
EPl
Mi
IPl
ON
Interaural 15.20 mm
Bregma 6.20 mm
Figure 3
GlA
MiA
GrO
EPlA
VN
AOE
GrA
dlo
AOL
aci
E/OV
Gl
lo
EPl
Mi
GrO
IPl
ON
Interaural 14.70 mm
Bregma 5.70 mm
Figure 4
FrA
LO
MO
AOB
VO
rf
Mi
AOD
IPl
AOE
aci
AOM
AOL
EPl
GrO
E/OV
lo
Gl
AOV
Interaural 14.20 mm
Bregma 5.20 mm
Figure 5
FrA
PrL
LO
MO
DLO
VO
AOD
rf
E/OV AOL
aci
AOM
1a
1b
AOV
lo
Interaural 13.70 mm
Bregma 4.70 mm
Figure 6
M2
PrL
MO
LO
DLO
VO
AOD
ri
rf
AOL E/OV
aci
AOM
AOV
lo
VTT
Interaural 13.20 mm
Bregma 4.20 mm
Figure 7
M2
Cg1
M1
fmi
PrL
Cl
LO
AI
VO
MO
DTr
ri
rf
1 E/OV
3
2
3
DEn
2
aci
1 Pir
AOM
DTT
lo
AOV
3
2
VTT
1
Interaural 12.70 mm
Bregma 3.70 mm
Figure 8
M2
Cg1
M1
PrL fmi
Cl
AID
IL
VO
LO
AIV
DP
ri
E/OV rf
2
3
1
DTT
DEn
aca
Pir
lo
VTT
AOP
Tu
Interaural 12.20 mm
Bregma 3.20 mm
Figure 9
M2
M1
Cg1
S1J
PrL
fmi
GI
IL
Cl
E/OV
AID
DP
AIV
LO
VO
DTT
AcbSh
AcbC
rf
aca
DEn
Pir
AOP
lo
mfba
SL
ICj mfba
TuPo
TuDC
Interaural 11.70 mm
TuPl
Bregma 2.70 mm
Figure 10 M2
M1
Cg1
fmi
PrL
S1J
IL
E
GI
CPu
LV
DP Cl
AID
3
AIV
1
2
DTT
rcc
VO
DEn
SHi
rf AcbC
aca
SL
Pir AcbSh
lo
LSS
ICj
mfba
VP
Tu
Interaural 11.20 mm
Bregma 2.20 mm
Figure 11 M2
M1
Cg1
cg
Cg2
fmi
S1J
E
IG
ec
CPu
LV
DP
GI
LSI
DI
Cl
exc
SHi
AID
AIV
AcbC
DEn
AcbSh
LSS
aca
rf
SL
Pir
VP
LAcbSh
lo
mfba
mfba
VP
ICj
VP
Tu
Interaural 10.70 mm
Bregma 1.70 mm
Figure 12 M2
M1
Cg1
S1J
cg
fmi
Cg2
IG
E
S1JO
gcc
LSD
IG
LV CPu
ec
GI
LSV
Cl
DI
SHi
LSI
VDB
AID
AcbC
AIV
DEn
LSS
aca
rf
AcbSh
mfba
Pir
lo mfba
VP
LAcbSh
mfba
ICj
VP
Tu
Interaural 10.60 mm
Bregma 1.60 mm
Figure 13 M2
M1
S1FL
Cg1
S1J
cg
Cg2
S1JO
E
IG
S1DZ
gcc
S1ULp
LV
IG LSD
CPu
ec
GI
LSV
LSI
SHi
Cl
DI
MS
AID
AcbC
AIV
DEn
ICjM
rf
aca
VDB
AcbSh
Pir
LSS
VP
mfba
ICj
mfba
lo
LAcbSh
mfba
ICj
VP
2n
Tu
Interaural 10.20 mm
Bregma 1.20 mm
Figure 14 M2
M1
S1FL
Cg1
S1J
cg
Cg2
S1JO
IG
E
S1DZ
gcc
LV
S1ULp
LSD
SHi
ec
CPu
GI
LSV
LSI
Cl DI
MS
AID
AcbC
AIV
ICjM
DEn rf
aca
AcbSh
LSS
Pir
VDB
LAcbSh
lo
ICj
mfba
CB
VP
mfba
VP
VP
2n
ICj
Tu
Interaural 10.00 mm
Bregma 1.00 mm
Figure 15 M2
M1
S1FL
Cg1
S1J
cg
Cg2
S1JO
IG
S1DZ
E
gcc
LV
LSD
ec
S1ULp
SHi
LSI
CPu
GI
Ld
LSV
ZL
Cl
MS
DI
ICjM
AID
AcbSh
AIV
AcbC
VDB
rf
aca
DEn
LSS
Pir
LAcbSh
VP
HDB
mfbb
mfba
CB
lo
VP
mfba
VP
ICj
ICj
2n
Tu
Interaural 9.70 mm
Bregma 0.70 mm
Figure 16 M2
M1
S1FL
Cg1
S1DZ
S1J
cg
Cg2
S1DZ
IG
E
cc
LV
S1ULp
LSD
SHi
LSI
S2
ec
CPu
Ld
GI
PLd
ZL
LSV
DI
BSTMA
Cl
MS
AID
BSTL
AcbSh
AIV
DEn
aca
VDB
rf
IPAC
AcbC
LSS
SIB
Pir
VP
CB
HDB
mfba
mfbb
lo
VP
2n
ICj
Tu
Interaural 9.48 mm
Bregma 0.48 mm
Figure 17 M1
M2
S1FL
Cg1
S1DZ
cg
Cg2
S1ULp
IG
cc
LV
LSD
SHi
LSI
S2
Ld
CPu
PLd
ec
GI
ZL
MS
LSV
DI
BSTMA
Cl
BSTL
AIP
aca
VDB
DEn
rf
IPAC
SI
VP
LSS
Pir
CB
mfbb
HDB
mfba
SIB
lo
ICj
2n
Tu
Interaural 9.20 mm
Bregma 0.20 mm
Figure 18 M1
M2
S1HL
Cg1
S1FL
cg
S1DZ
Cg2
IG
cc
S1BF
LV
df
LSD
LSI
SFi
S2
CPu
LSV
ec
ic
f
GI
BSTLD
st
MS
ZL
DI
BSTMA
BSTLJ
Cl
ac MnPO
acp
AIP
LGP
BSTLP
BSTMV
acp
BSTLV
StA
rf
LSS
DEn
ADP
PS
Fu
IPACL
VP
VEn
Al
MPOL
IPACM
SIB LPO
Pe
Pir
CxA
MCPO
mfba
MPA
mfba AVPe
3V mfbb
HDB
VP
lo
ICj
VMPO
ox
Tu
Interaural 8.74 mm
Bregma -0.26 mm
Figure 19 1 M1
M2
2
S1HL
3
4
Cg1
S1FL
5
S1DZ
cg
Cg2
6a
6b
IG
S1BF
cc
LV
df
LSD
pcf
ec
LSI
SFi
S2
CPu
ic
LSV
GI
f
st
BSTMA
DI
LGP BSTLJ
BSTLD
MnPO
BSTLP
Cl
ac acp
AIP
BSTLV
BSTMV
acp
rf
ADP
LSS PS
3V
Fu
DEn
StA
IPACL
VP
Pe
IPACM
LPO
VEn
Pir
MPOL
SIB
mfba
MCPO
CxA MPA
mfba
AVPe
mfbb
HDB
VP
lo
ICj
VMPO
VLPO
ox
Tu
Interaural 8.70 mm
Bregma -0.30 mm
Figure 20 M1
M2
S1HL
Cg1
S1FL
S1DZ
cg
Cg2
IG
S1BF
cc
LV
LSD
df
ec
LSI
SFi
S2
CPu
LSV
st
GI
ic
f
BSTMA
BSTLJ
DI
CST
LGP
BSTLP
BSTLI
Cl
ac MnPO
AIP
BSTMV
IPACL
acp
BSTLV
rf
ADP
DEn
PS
IPACM
StA
Pe VEn
MPA
VP
LSS
LPO
MPOL
SIB
AVPe
CxA
mfba
MCPO
3V
mfba
Pir
HDB
mfbb
VP
lo
ICj
VMPO
VLPO
ox
Tu
Interaural 8.60 mm
Bregma -0.40 mm
Figure 21 M1
M2
S1HL
S1FL
Cg1
S1DZ
cg
Cg2
S1BF
IG
LSD
cc
LV
df
ec
pcf
SFi
TS
S2
st
SFO
vhc
CPu BSTS
ic
sm
3V
BSTMPM
GI
BSTMPI
LGP
BAC
f
DI
BSTMPL
BSTLI
Cl
AIP
B
BSTLP
APF
rf
acp
IPACL
PaAM
mch
DEn PDP
SID PaAP
Pe
IPACM
StHy
LSS
B
SIB
VP MPA
VEn
Pir
LPO
MPOC
MCPO
mfba
HDB
CxA
mfbb
MPOL
VLPO
AAV
MPOM
lo
ox
Tu
SO
Interaural 8.20 mm
Bregma -0.80 mm
Figure 22 M2
M1
S1HL
Cg1
S1FL
S1DZ
cg
Cg2
S1BF
IG
cc
LV LSD
df
TS
ec
SFi
vhc
IVF
S2
SFO
D3V
st
AV
CPu
ic
PT
sm
GI
PVA
BSTMPM
DI LGP
mch
BSTMPI
Cl
B
f Pe
3V AIP
PaAP
BSTMPL
rf
PaAM
SIV
IPACL
SID
acp
DEn
VP
B
Pe
StHy
IPACM
LSS
SIB
MPOC
MPOM
AAD
VEn
Pir
LPO
mfb
MCPO
MPA
HDB
ACo
MPOL
CxA
VLH
AAV
LOT
SCh LA
SO
lo
ox
Interaural 8.08 mm
Bregma -0.92 mm
Figure 23 M1
M2
S1HL
Cg1
S1FL
S1DZ
Cg2
cg
IG
S1BF
cc
df
LV
TS
vhc
ec
SFO
fi
AVDM
D3V
AD
st
sm
PVA
PT
S2
PC
AVVL
IAD
AM
CPu
ic
AMV
Rt
PVA
GI
LGP
Re
DI
B
rf
Pe
SM
sm Cl
LSS
f AIP
PaAP
B
IPACL
B
AStr
MPA
IPACM
3V
SIV
BSTMPL DEn
SID
SIB
Pir
LH MPO
mfb
AAD
AHA
VEn
MCPO
BMA
AAV
VLH
3
LA
ACo
2
LOT
SO
SCh
1 CxA
MeAD
ox
lo
Interaural 7.70 mm
Bregma -1.30 mm
Figure 24 M2 M1
S1HL
Cg1
S1FL
S1DZ
Cg2
cg
IG
S1BF
cc
df
TS LV
vhc
fi
SFO
AVDM
ec
AD
D3V
sm
st
S2
PVA
PT
PC
AVVL
CPu
CM
IAD
AM ic
Rt
GI
AMV
PVA
DI
LGP
B
Re
Cl
B rf
AIP
sm
VRe
3V
B
IPACL SM
f
PaAP
AStr
DEn
SI
BSTMPL
IPACM
LSS
Pe
LH
VEn AAD
AHA
mfb
Pir
Cir
MCPO MPO
AAV
BMA 3
VLH
LA
2
LOT
ACo
SO
CxA
SCh
1
MeAD
ox
lo
Interaural 7.60 mm
Bregma -1.40 mm
Figure 25 M2
M1
RSA
S1HL
S1FL
S1DZ
RSGb
cg
S1BF
IG
cc
df
TS
LV
CA3
S1
vhc
SFO
DG
ec AVDM
fi
D3V
sm
st
AD
MD
ic
PVA
S2
PC
AVVL
PT
Rt
CPu
VA
B
VA
AM
LGP
IAM
GI
mt
Rh
AMV
DI
B
Re
rf
VRe
AIP
ZI
IPAC
Cl
B
SI
AStr
PaAP
CeM
f
BLA
LH
DEn
CeC
I
mfb
AHA
AA
VEn
MCPO
Pe
3
BMA
AHC
SO
3V
LOT
ACo
1
RCh CxA
sox
MeAD
ox
Interaural 7.40 mm
Bregma -1.60 mm
Figure 26 M2
M1
S1HL
RSA
S1FL
S1DZ
RSGb cg
IG
S1BF
cc
df
TS
LV
S1
fi
DG
LDVL
D3V
sm
AD MHb
st
ec
MD
AVDM
PVA
PC
PC
S2
PT
ic
AVVL
CM
eml
AM
IAD
Rt
VA
CPu
IAM
GI
AMV
mt
Rh
DI
LGP
Re VM
rf
LaDL
Xi
Sub
Cl
IPAC
AIP
VRe
B
B
AStr
ns
ZI
PaDC
3V
al
PaLM
DEn
CeL PaMP CeC
CeM
SI
LH f
SPa
BLA
mfb
PaV
cst
AHP
I
VEn
Pe
AHC
BMA
MeAD
LOT
opt
ACo
SO
BAOT
RCh
sox
CxA
Interaural 7.20 mm
Bregma -1.80 mm
Figure 27 M2
RSA M1
S1HL
S1FL
S1DZ
RSGb
cg
S1BF
IG
cc
df
DHC
dhc
CA3
S1
LV
DG
LDVL
fi
D3V
AD sm MHb
st
S2
MD
PVA
AVVL
PC
PT
AVDM
ec
iml
CM
GI
CPu
IAD
VA
Rt
AM
IAM
AMV
DI
mt
ic
Rh
LGP
Sub
AIP
VM
Cl rf
Re
LaDL
Xi
IPAC
VRe
ZI
ns PaMP
DEn PaDC
CeC
CeM
PaLM
CeL
al
SI
f
SPa
LH
BLA
mfb
PaV
AHP
IM
cst
VEn
MeAD
Pir
AHC
BMA
3V
Pe
opt
SO ACo
BAOT
CxA
sox
RCh
Interaural 7.12 mm
Bregma -1.88 mm
Figure 28 M1
M2
S1HL
RSA
S1FL
S1DZ
RSGb
cg
IG
S1BF
cc
DHC
df alv
dhc
CA3
S1
LV
fi
ec
MHb
DG
LDDM
D3V AD
sm
st
LDVL
LHb
CL
PVA
MDL S2
AV
iml
MDM
VL
PC
CM
CPu
VPL
GI
eml
VA
AM
IAM
Rt
ic
DI
Rh
LGP
Sub
IPAC
mt
Re
rf
AIP
AStr
VM
B
Xi
VRe
CeC
MGP
ns
LaDL
ZI
CeL
al
DEn
PaPo vaf
CeM
SI
IMG cst
f
Stg
mfb
BLA LH
PaMP
SPa
AHP MeAD
IM
Acc
3V
VEn
Pe
AHC
MeAV
BMA
opt
VMHA
Pir ACo
sox
TC
CxA
aot
BAOT
ArcD
ArcM
ArcL
SOR
ME
Interaural 6.88 mm
Bregma -2.12 mm
Figure 29 M2
M1
RSA
S1Tr
S1DZ
cg
RSGb
IG
alv
cc df
S1BF
CA1
CA2
dhc
DHC
CA3
LV
ec
MHb
fi
DG
sm
LDVL
LDDM D3V
LHb
st
PV
MDC
MDL
CL
iml
S2
IMD
MDM
VPM
PC
VL
CM
eml
GI Rt
ic
CPu
VPL
IAM
LGP
DI
Rh
Sub
VM
IPAC
rf
mt
Re
AIP
B
AStr
VRe
LaDL
CeL
I
MGP
Xi
cst
ZI
A13
ns DA
DEn
CeC
IMG
SI
Stg
PaPo
CeM
al
AHP
f
Pe
LH BLA
3V
mfb
MeAD BLP
I VMHDM
VEn
Pir
TC
MeAV
BMA
BLV
opt
VMHC
VMHVL
sox ACo
CxA
ArcM BAOT
PLCo
ArcD
ArcL
SOR
MEI
Interaural 6.70 mm
MEE
Bregma -2.30 mm
Figure 30 M2
M1
RSA
S1Tr
S1DZ
RSGb
cg
IG
cc
alv
df
DHC
S1BF
CA1
CA2
dhc
CA3
LV
PoDG
MHb
fi
DG
LDDM
sm
D3V
LDVL
LHb
st ec
PV
MDC
CL
S2
Ang
iml
MDL
Rt
Po
MDM
IMD
MDPL
PC
CPu
VPM GI
CM
eml
VL
ic
VPL
LGP
DI
SubD
Rh
B
rf
IPAC
lab
scp
VM
SubV
AIP
LaVM
B
LaDL
AStr
Re
mt
CeL
VRe
MGP
ZI CeC
cst
LaVL
A13
ns
CeM
SubI
DEn
DA
al
MePD BSTIA
BLA
opt
DMD
LH
mfb
I f
BLP
TC
3V Pe
MeAD VEn
VMHDM
BMA
BMP
BLV
VMHC
sox
MePV
ACo
VMHVL
aot
Pir
PLCo
ArcD
ArcM
ArcL
SOR
Interaural 6.44 mm
MEE MEI
Bregma -2.56 mm
Figure 31 M1
M2
RSA
S1Tr
S1DZ
RSGb
cg
IG
alv
S1BF
CA1
df
cc
CA2
dhc
CA3
PoDG
LV
DG
fi
LDVL sm
D3V
LDDM
LHb
st
MHb
PV
S2
iml
ec MDC CL
Ang
MDL
Po
Rt
GI
IMD
MDM
PC
VPM
DI
CM
CPu
eml
VPL
VL
ic
Ect
LGP
Rh
SubD
lab
VM
scp
rf
IPAC
SubV
cst
B
Re
PRh
LaDL
AStr
VRe
CeL
mt
MGP
ZI
LaVM
LEnt
CeC A13 CeM
ns
3V
DEn
SubI
LaVL
DA
MCLH
BSTIA al
BLA
BLP
opt
I
MePD
DMD
PeF
mfb
LH
f
VEn
VMHDM
MeAD
BMA
BLV
Pe TC
sox
VMHC
ArcD
MePV
Pir
BMP
ACo
SOR
PLCo
VMHVL
ArcL
Interaural 6.20 mm
ArcM
MEE
MEI
Bregma -2.80 mm
Figure 32 M2
M1
RSA
S1Tr
S1DZ
cg RSGb
alv
IG
CA1
S1BF
df
cc
hf
CA2
dhc
CA3
S2
PoDG
LHbM
LV
LHbL
D3V
sm
fi
LDVL
LDDM
MHb
AuD
LPMR
ec
st
PVP
iml
MDL
MDM
Po
CL
Rt
MDC
IMD
AuV VPM
PC
eml
CPu
CM
VL
VPL
B
Rh
ic Ect
LGP
scp
rf
Sub
VM
AStr ml
st eml
Re
PRh
VRe
CeC
LaDL ZID
mt
CeL A11
LEnt
Do
ZIV
MGP
LaVM
DA
SubI
opt
3V LaVL
ns
DEn
BSTIA
Pe
BLA
mfb
LH
MePD
PeF
DMD
DMC
BLP
f I
sox
MCLH
BMP
I
MePV
VEn
BL
V
VMHC
TC
Pir
PMCo
MTu
BMA
VMHDM
SOR
ArcD
VMHVL
PLCo
ArcM
ArcL
MEE MEI
Interaural 5.86 mm
Bregma -3.14 mm
Figure 33 M2
RSA
M1
S1Tr
S1DZ
RSGb
cg
alv
S1BF
IG
CA1 df
cc
hf
dhc
CA2
FC
S2
CA3
DG
PoDG
LV
MHb
LHbM
AuD
LHbL
LDVL
D3V
sm
LPMR
CPu fi
LDDM
Au1
PVP
st
CL
Rt
IMD
MDC
MDL
Po
iml
AuV
MDM
VPM
ec
VPL
PC
eml
CM
imvc
OPC
LGP
Ect
CPu
ic
ml
VM
scp
st
Re
rf
PRh
ZIV
CeL
VRe
eml ZID LaDL
AStr
LEnt A11
mt
opt
LaVM
CeC
3V
SubI
MGP
LaVL
PH
DEn
BSTIA
ns
MCLH
mfb DMD
LH
BLA
Pe
BLP
PeF
I
MePD
sox
f
VEn
DMV
I DMC
BMP
MePV
Te
BLV
TC
VMHC
Pir
MTu
VMHDM
PMCo
PLCo
ArcD
VMHVL
ArcM
Interaural 5.70 mm
ArcL
MEE
MEI
Bregma -3.30 mm
Figure 34 M2
M1
RSA
S1Tr
RSGb
cg
S1BF
IG
CA1
cc
df
dhc
hf
alv
S2
CA2
PoDG
CA3
DG
AuD
D3V
LHbM
MHb DLG
sm LV
LPMR
LDVL
VLG
ec
LHbL fi
Au1
fr
PVP
Po
iml
CL
st
MDL
ic
Rt
MDM
eml
IMD ic CPu
AuV
VPM
PC
VPL
CM
OPC
rf
Ect
VPPC
ml
A11
AStr
PRh
ZID VM
opt
LaDL
scp
LV
LEnt
ZIV
LaVM
mt
STh
PH
SubI
ns sox
st
LaVL
DEn
Pe
3V
BSTIA
MePD
BLP
LH
mfb PeF
Pir
DMD
BMP
VEn
AHiAL
f
PMCo
BLV
DMV
Te
ArcD
VMHC
PLCo
VMHVL
ArcM
ArcL
Interaural 5.40 mm
InfS
Bregma -3.60 mm
Figure 35 RSA
PtA
RSGb
Or
cg
Py
Rad
LMol
Mol
S1BF
GrDG
IG CA1
alv
df
cc
hf
dhc
CA2
PoDG
AuD
Hil
LHbM
CA3
LHbL
DG
D3V
sm
LPLR
DLG
LPMR
Au1
fi
MHb
VLG
ec
PVP
fr Po
iml
CL
eml
PF
AuV
VPL
st Rt
PoMn
MD
CPu
OPC
ic
TeA
VPM
PF
CM
Ect
VPPC
opt
ml
SPF
rf
PRh VM
ZID
scp
fi
LaDL
ZIV
LEnt
sox
STh
mt
PH
LaVM
LV
LH
ns
mfb
DEn
3V
MePD
BSTIA
Gem
BLP
AHiAL
PSTh
DTM
f BMP
Pir
PMCo
PMV
Te
ArcMP
VTM
ArcLP
PLCo
InfS
af
Interaural 5.20 mm
Bregma -3.80 mm
Figure 36 RSA
PtA
RSGb
cg
IG
S1BF
hf
CA1 df
cc
IBl
dhc
alv
PoDG
CA3
CA2
OBl
AuD
bsc
hbc
DG
IMA
D3V
sm
LPMR LPLR
DLG
LHbL
APTD
Au1
MHb
IGL
VLGPC LHbM
VLGMC
Po
str
fi
AuV
Rt
PVP
PF
fr
VPL
VPM
LV
TeA SubG
ec
opt
pv
Ect
VPPC
ic
ml
SPF
rf
ZID
PR
PRh
scp
F
ZIV
3V
CA3
LEnt
LaDL
PH
ns
LaVM
Gem
STh
DEn
mfb
SMT
PSTh
cp
BLP
SuM
LH
AHiPM
Pir
DG f
AHiAL BMP
PMD DTM
PMCo
MRe
APir
PMV
VTM
ArcMP
ArcLP
PLCo
af
Interaural 4.84 mm
InfS
Bregma -4.16 mm
Figure 37 RSA
V2MM
PtA
RSGb
cg
S1
IG
CA1
cc
df
hf
IBl
dhc
AuD
PoDG
CA2
OBl
DG
hbc
IMA
LPLR
bsc
CA3 D3V
Au1
LPMR
DLG
MHb
VLGPC
APTD
VLGMC
str fi
IGL
ec
PrC
alv
Po
AuV
ar
VPL
PF
VPM
TeA
fr
PVP
SubG
pv
VPPC
opt
SPFPC
Ect
rf
RI
ml
ic
3V
PR
ZID
scp
F
PRh
sox
PH
ZIV
mtg
LV CA3
LEnt
Gem
ns STh
SMT
sumx
mfb
LH
SuM
DEn
cp
pm
BLP
ML
Pir
DG
AHiPM
MMn
f
AHiAL
MM
APir
PMCo
VTM
MRe
PMD
PLCo
af
ArcMP
Interaural 4.70 mm
Bregma -4.30 mm
Figure 38 V2MM
RSA
V2ML
RSGb
PtA
cg
IG
cc
df
CA1
S1
hf
alv
dhc
AuD
PoDG
bsc
DG CA3
CA2
PiRe
LPMC
IMA
hbc
Au1
APTD
OPT
DLG
pc SCO
LPMR
MPT
3V
alv
IGL
str
LPLC
PrC
AuV
APTV
VLGMC
LPLR
Sc
VLGPC
PVP
ar
Po
TeA
VPM
PF
ec
Eth
SPFPC
pv
Ect
SubG
CA2
fr
opt
ic
ml
fr
ZID
PRh
CA3 scp PR
RI
rf
PH
sox
3V
F
ZIV
LEnt
mtg
LV
SNR
sumx
ns
DEn
LH
Gem
SuM
mfb
cp
BLP
pm
Pir
DG
MMn
f
AHiPM
MM
LM
VTM
ML APir
PMCo
MRe
PLCo
ArcMP
af
Interaural 4.48 mm
Bregma -4.52 mm
Figure 39 V2MM
RSA
V2ML
V2L
RSGb
cg
alv
PtA
df
scc
CA1
AuD hf
dhc
PoDG
DG
Au1
bsc
PiRe
OT
LPMC
OPT
IMA
MPT
APTD
hbc
LPLC
PLi
DLG
PCom
PLi
pc
AuV
CA2
SG
MGD
str
SCO
APTV IGL dlf
MGM
SCom
alv TeA
MCPC
MGV VLGPC
PAG
VLGMC PoT
PIL ctg
opt
Eth
CA3
LT
Dk
Ect
IMLF
SPFPC
3V
PRh
PR
scp
rf
ml
CA1
fr
ZIV
ZID
mtg
RI
sumx
SNR
PBP
ns
LH
DEn
SNCD
LEnt
SuMM
SuML
mp
mfb BLP
mt cp
f
DG
APir
AHiPM
MM
LM ML
PMCo
af
Interaural 4.20 mm
Bregma -4.80 mm
Figure 40 RSA
V2MM
V2ML
V2L
RSGb
cg
alv
scc
PtA
CA1
FC
dhc
AuD
hf
PoDG
DG
PiRe
Au1
bsc
OT
PPT
LPMC
MPT
OPT
IMA
csc
LPLC
APTD
DLG
PAG
pc
PCom
MGD
AuV
CA2
PLi
SG
CA3
dlf
opt
MCPC
alv
PAG
Aq
MGV
MZMG TeA
PoT ctg
APTV
dtg
IMLFG
MGM
PIL Dk
PP CA1
SPFPC EW
Ect
DpMe
REth
IMLF MA3
PRh
rf
LT
SNL
scp PR
ZI
ml
PBP
RLi
mtg
SNRVL
VTRZ
vtgx
fr
PBP
SNCD
LEnt
IF
SNM
VTA
SNRDM
PN
DEn
IPF MT
mp
cp
APir
MM
AHiPM
af
PMCo
Interaural 3.80 mm
Bregma -5.20 mm
Figure 41 RSA
V2MM
V2ML
RSGb
cg
V2L
CA1
scc
PtA
dhc
FC
hf
AuD
S
PiRe
alv
PoDG
DG
SC bsc
LPLC
MPT OT
PPT
Au1
LPMC
SC
OPT
csc
DLG IMA
DMPAG
pc
APTD
PCom
SG MGD
opt
AuV dlf
PLi
CA3
alv
LPAG
Aq
MGV
ctg
MCPC
MZMG
CA2
dtg
MGM
APTV TeA
PoT
Dk
IMLFG
IMLF
PIL
EW
DpMe
Ect
PP
REth
LT
SPFPC
MA3
PRh
CA1
rf
SNL
scp
PBP
ml
RPC
RLi
mtg
vtgx
SNCD
VTRZ
PBP
fr
IF SNR
VTA
DEn
PN
MT
IPF mp
aopt LEnt
DG
cp
APir
MM
AHiPM
af
PMCo
Interaural 3.70 mm
Bregma -5.30 mm
Figure 42 V2MM
RSA
V2ML
V1M
V1B
cg
RSGb
V2L
fmj
Post
RSGa
PtA
CA1
hf
S
Zo
alv
AuD
SuG
Op
PoDG
InG
DG
bsc
Au1
OT
InWh csc
PPT
LPMC
DMPAG
DpG
DpWh
PLi
DLPAG
AuV MGD
dlf
LPAG
SG
Aq
CA2
MZMG
MGV
alv
APT
TeA EW
CA3
dtg ctg
Dk
IMLFG
MGM
MA3
DpMe
PoT
IMLF
mlf
PP PIL
PaR
Ect
mtg
LT
SNL
Min
rf
scp RPC
ELm
PRh
VTRZ
RMC
RLi
ml
CA1
SNR
vtgx
DEn
PBP
SNCD
hf
IPDM
VTA
IF
3n
LEnt
PN
SNM
AHiPM
IPR APir
mp
fr
cp
IPC
IPRL
PMCo
3n
MM
af
Interaural 3.40 mm*
Bregma -5.60 mm
Figure 43 V2MM
V2ML
RSA
V1M
V1B
cg
RSGb
fmj
V2L
RSGa
S
Zo
Post
PtA
hf
SuG
AuD
Op
DG
PoDG
alv
InG
CA1
csc
InWh
OT
Au1
bsc
DMPAG
DLPAG
PPT
DpG
LPMC
PLi
alv
DpWh
MGD
dlf
SG
CA3
Aq
LPAG
AuV
MGV
CA2
MZMG
IMLF
Dk
EW
APT
dtg
MGM
ctg
TeA
IMLFG
PoT
DpMe
MA3
PIL
PP
mlf
Ect
PaR
SNL
Min
R
rf
PRh
scp
RLi
ELm
CA1
vtgx
SNR
mtg
PBP hf
DEn
ml
IPDM
VTA
SNCD
IF
PN
LEnt
S
APir SNM
3n
IPR
4n
AHiPM
mp
cp
IPC
IPRL 3n PMCo
af
Interaural 3.20 mm*
Bregma -5.80 mm
Figure 44 V2MM
RSA
V2ML
V1M
V1B
RSGb fmj
V2L
RSGa
Zo
Post
S
SuG
Op
AuD
DG
InG
PoDG
csc InWh
OT
DT bsc
alv
Au1
DpG
DMPAG
dlf
DpWh
DLPAG
MGD
CA2
LPAG
SG
Aq
Su3C CA3
bic
AuV MZMG
EW
MGM
dtg
MGV
IMLFG
hf Su3
3PC
DpMe
IMLF
TeA
PIL
3 ctg
PP mlf RLi
SNL Ect
dtgx
scp
PaR
RPC
SNCD
vtgx
rf
PRh
RMC
CA1
DG
SNR
PBP
3n
mtg
CLi
DEn
SNCV
VTA
LEnt
IPDM
ml
IPDL
SNM
IPR
AHiPM
APir
cp
IPL
IPI
PMCo
IPC
af
Interaural 2.96 mm*
Bregma -6.04 mm
Figure 45
V2ML
V2MM
RSA
V1M
V1B
RSGb
fmj
V2L
RSGa
Zo
Post
SuG
S
Op
InG
AuD
csc
DpG
DpWh
DMPAG
InWh
Au1
CA1
bsc
dlf
DT
PoDG
DLPAG MGD
AuV
hf
DG
Hil
Aq
LPAG
SG
TeA Su3C
MGV
bic EW
IMLF
ctg
Su3
3PC
MGM
ltg
dtg DpMe
IMLFG
Ect
3
mlf
SubB
PaR
PRh
S
dtgx
RPC
scp
rf
PrS
RMC
vtgx
mtg
RRF
PaS
rs
MEntV
CLi
SNR
IPDM
VTA
SNCD
ml
IPDL
IPR
LEnt
IPL
cp
s5
IPC
IPI
tfp
bas
Interaural 2.70 mm
Bregma -6.30 mm
Figure 46 V2MM
V2ML
RSA
V1M
V1B
RSGb
fmj
RSGa
Zo
V2L
SuG
Post
Op
S
InG
InWh
DpG
hf
DMPAG
DG
dlf
DpWh bsc
DLPAG
TeA
Me5
bic me5
CA1
Aq
LPAG
Su3C
BIC
ts
EW
Su3 ltg
3PC
ctg
MG
DpMe
dtg
3
SubB Ect
PrS mlf
dtgx
PRh
S
PaS
rf
mtg
RRF
A8
CLi
scp PPTg
MEnt
xscp IPDM
rs
VTA
LEnt
B9
IPA
cp
ml
IPL
s5
m5
bp
IPI
IPC
Pn
tfp
Interaural 2.28 mm
bas
Bregma -6.72 mm
Figure 47 V2ML
V2MM
V1M
RSA
V1B
RSGb
fmj
RSGa
Zo
SuG
Post
V2L
Op
InG
InWh
DpG
CA1
bsc
DpWh
DMPAG
dlf
GrDG
DLPAG
hf
S
TeA DG
bic
Aq
me5
LPAG
Me5
Su3C
BIC MG
EW
ts
Su3
ctg ltg
Ect
3PC
dtg
DpMe
3
PrS
SubB
mlf
PRh
mtg PaS
dtgx
rf
RRF
A8
CLi
xscp
Dsc
PPTg
MEnt
IPDM Rbd
cp
rs
VTA LEnt
B9
IPA
tth
IPL
ml
s5
IPC
m5
IPI
bp
Pn
tfp
Interaural 2.20 mm
bas
Bregma -6.80 mm
Figure 48 V2MM
V1M
RSA
V1B
RSGb
RSGa
fmj
Zo
SuG
V2L
Op
Post
InG
InWh
DpG
bsc
DpWh DMPAG
dlf
hf
DLPAG
TeA
Me5
S me5
Aq
LPAG
bic
Su3C
BIC DR
ltg
ts
PrS
Su3
3PC
ctg
Ect
DpMe
dtg
I3
3
SubB
PaS
PRh mlf
MiTg
A8
RRF
ts
CLi
PBG
mtg
Dsc
PPTg
rf
xscp
MEnt
RR
LEnt
Rbd
ipt
rs
IPA
IPL
B9
cp
tth
bp
s5
ml
IPI
IPC
m5
Pn
tfp
Interaural 1.96 mm
bas
Bregma -7.04 mm
Figure 49 V2MM
V1M
RSA
V1B
RSGb
RSGa
Zo
fmj
SuG
V2L
Op
InG
InWh
Post
DpG
DMPAG
TeA dlf
DpWh
DLPAG
PrS
Aq
BIC
S
LPAG InCo
bic
me5
Me5
DRD
Su3C
Ect ltg
ts
Su3
SubB
PaS
3PC
DpMe
ctg
DRV
dtg
PBG PRh
4
MiTg
Pa4
mlf
rf
CLi
Dsc
PL
RR
PPTg
xscp
MEnt
LEnt
ipt
Rbd
PnO
rs
ll
MnR
RtTg
mcp
s5
B9
tth
ml
lfp
Pn
m5
Pn
bp
tfp
Interaural 1.70 mm
bas
Bregma -7.30 mm
Figure 50 V2MM
RSA
V1M
V1B
RSGb
RSGa
Zo
V2L
SuG
fmj
Op
InG
InWh
Post
DpG
TeA
DMPAG
DpWh
PrS
dlf
DLPAG
BIC
InCo
Aq
LPAG
ECIC
bic
Ect
me5
PaS
Me5 VLPAG
DRD
ll
DpMe
PRh DRVL
ctg
dtg
MiTg
DRV
Pa4
mlf PBG
CLi
PPTg
Dsc
rf
RR
xscp
SPTg
MEnt
Rbd
LEnt
ATg
PL
ERS
ts
rs
PnO
VLL
s5
mcp
PMnR
ll
RtTgP
MnR
tth
m5
RtTg
B9
ml
bp lfp
Pn
Interaural 1.36 mm
tfp
bas
Bregma -7.64 mm
Figure 51 V2MM
V1M
RSA
V1B
RSGb
RSGa
Zo
V2L
SuG
Post
fmj
Op
InG
InWh
DpG
TeA
PrS
ECIC
DpWh
DMPAG 1
1
2
DLPAG
InCo
BIC
PaS
Ect
Aq
LPAG
bic
me5
Me5
PRh
VLPAG
ll
DRD
DpMe
DRVL
MiTg
dtg
Dsc
DRV
PBG
MEnt
mlf
PPTg
xscp
LEnt
Rbd
SPTg
ILL
PL
ts
ATg
PMnR
mcp
rs
VLL PnO
MnR
s5
RtTg
RtTgP
m5 B9
DMPn
tth
ll
DLPn
ml
m5
DPPn
lfp
VPPn
LPn
MPn
Interaural 1.20 mm
VMPn
bp
tfp
bas
Bregma -7.80 mm
Figure 52 V1M
V2MM
V1B
RSA
RSGa
fmj
V2L
Zo
SuG
Op
Post
InG
InWh
TeA
DpG
DpWh
ECIC
DMPAG
2
InCo
DLPAG
PaS
Ect
Aq
LPAG
BIC
me5
Me5
bic
VLPAG
Dsc
CnF
ll DRD
4n
DRVL
MiTg
PRh
DpMe
DRV dtg
rf
PBG
MEnt
mlf
LEnt
scp
cll
xscp
PPTg
Rbd
SPTg
ILL
ATg
PL
MnR
ts
PnO
PMnR
rs
mcp
VLL
s5
RtTgP
VLTg
RtTg
m5
ll
tth
RPO
ml
lfp
bp
Pn
tfp
Interaural 1.00 mm
bas
Bregma -8.00 mm
Figure 53 V1M
V2MM
V1B
Pi
RSA
RSGa
V2L
TeA
Post
cic
PaS
1
ECIC
Ect
DMPAG
2
Dsc
3
DLPAG
Aq
LPAG PRh
me5
Me5
MEnt VLPAG
DRVL
CnF
4n
ll
LEnt
DRD PPTg
DLL
dtg
DRV
Rbd
cll
scp
mlf
DRI
PL
ILL
SPTg
VLL
VTg
mcp
PMnR
ll
PnO
ts
MnR
rs
ll
m5
s5
VLTg
vsc
tz
RtTg
VLL
ll
RtTgP
tth
ll
Tz
ml
RPO
py
Interaural 0.70 mm
bas
Bregma -8.30 mm
Figure 54
V1M
V1B
V2L
DCIC
RSA
TeA
cic
Ect
PaS
DMPAG
PRh
ECIC
ReIC
Dsc
CIC
1
2
3
LPAG
MEnt
LEnt
2
Sag
Me5
me5
ll
VLPAG
CnF
4n
cll
LDTg
LPBS
LPBC
dtg
DLL
DRC
scp
DTgP
LPBE
vsc
mcp
MPB
LDTgV
mlf
DMTg
VTg
KF
DRI
SubCD
PnR
A7
ts
P5
s5
PnO PC5
m5
SubCV
Pr5
rs
MSO RtTg
vsc
tz
A5
RPO
tth
SPO
ml
Tz
LVPO
tz
py
MVPO
bas
Interaural 0.28 mm
Bregma -8.72 mm
Figure 55 V1M
V1B
V2L
RSA
DCIC
cic
Ect
DMPAG
PaS
PRh
CIC
ECIC
ReIC
1
3
2
MEnt
LPAG
4n
2
MEnt
Sag
Cb
Me5
me5
ll
CnF
4n
LPBS
LPBC
LDTg
DRC
dtg
DLL
DTgP
scp
LPBE
vsc
VTg
MPB
mcp
LDTgV
mlf
KF
SubCD
DRI
DMTg
Su5
DMTg
A7
VCA
PC5
Mo5
ts
P5
PnR
PnO
s5
Pr5VL
m5
RtTg
SubCV
rs
DPO
tz
A5
LSO
SPO
tth
ml
MSO
Tz
vsc
tz
LVPO
MVPO
py
bas
Interaural 0.20 mm
Bregma -8.80 mm
Figure 56 V1M
V1B
Cb
1
V2L
2
DCIC
RSA
3
cic
Ect
PaS
ReIC
PRh
ECIC
MEnt
1
CIC
2
3
3
4
2
Sag
LPBV
LPBI
4n
LPBD
SMV
RL
4V
2&3
LC
LPBCr
LPBC
LDTg
vsc
scp
Me5
Bar
mcp
LPBE
me5
MPB
DTgP
MPBE
DRC
DTgC
Su5 KF
SubCA
mlf
PnR
SubCD
VCA
Mo5DL
DMTg
P5
I5
ts
m5 Mo5VM s5
Pr5VL
RtTg
SubCV
PnC
A5
DPO
rs
PnV
tth
RMg
LSO
6n
tz
SPO
MSO
ml
Tz
tz
LVPO
vsc
MVPO
py
bas
Interaural -0.16 mm
Bregma -9.16 mm
Figure 57 V1M
Cb
V1B
V2L RSA
DCIC
PaS
Ect
PRh
MEnt
ReIC
CIC
ECIC
3
2
1
3
Sim
4
2
PCTg
LPBI
LPBD
LPBV
4n
4V
LPBC
SMV
DRC
LPBE
2&3
vsc
LPBCr
LC
LDTg
Me5
scp
DTgC
Bar
me5
MPB
mcp
CGB DTgP
MPBE Pr5DM
LR4V
SubCA
scpd
Su5
chp
CGA
mlf
Mo5DL
DMTg
SubCD
P5
VCA
Mo5VM
PFl
I5
ts
PnR
Pr5VL
RtTg
m5
s5
SubCV
PnC
RIP
A5
DPO
PnV
rs
RMg
tth
LSO
SPO
ml
vsc
MSO
Tz
tz
py
LVPO
MVPO
bas
Interaural -0.30 mm
Bregma -9.30 mm
Figure 58 5
Cx
4
DCIC
CIC
3
Sim
prf
Crus1
ECIC
PCTg
3
4&5
2
LPBV LPBV
LPBC LPBC
PFl LPBE
LPBE
LC
plf
vsc
4V
1
PCGS SMV
mcp
scp
CGPn
MPB
Bar
Fl
Sph
me5 Me5
LR4V
PDTg
CGB
Su5
SubCA
I5
Pr5DM
CGA
O
SGl
scpd
II
mlf
SubCD
P5
DMTg
m5
Mo5
VCA
Acs5 s5
ts
ocb
pd
Pr5VL
SubCV
Jx5
PnC
RIP
8vn
7n
DPO
A5
PnV tz
LSO RMg
rs
tth
SPO
tz
Tz
ml
MSO
LVPO
py vsc MVPO
bas
Interaural -0.68 mm
Bregma -9.68 mm
Figure 59 5
Cx
4
DCIC
ECIC
3
psf
prf
Crus1
Sim
2
LPBV
PBW
vsc
plf
LC
1
PFl
4V
mcp
SMV
scp
Sph
PCGS
LR4V
Bar
Fl
MPB
Me5
me5
PDTg
CGB
Pr5DM SubCA
O
CGA
P5
II
SubCD
mlf
DMTg
Mo5
VCA
m5
sp5
Acs5
ts
pd
ocb
SubCV
Pr5VL
PnC
8vn
RIP
Acs6
7n
A5
DPO
rs
PnV
RMg
tth tz
tz
LSO
SPO
RPa
ml
Tz
vsc
MSO
LVPO py
MVPO
bas
Interaural -0.80 mm
Bregma -9.80 mm
Figure 60 5
SimA
SimB
4
pcuf
prf
Sim
psf
3
Crus1
pfs
2
mcp
plf
PFl
MPB
icp
1
unc
vsc
LPBV
scp
LC
SMV
SuVe
4V
LR4V Bar
me5 PDTg
Me5
MVeMC
Fl
CGG
PCGS
prb
8vn
SGl
CGA
veme
plf
CGB
Pr5DM
VCA
6
P5
mlf
ocb
Pa6
PCRtA
I8
sp5
8cn
ts
IS
7n
Pr5VL
IRt
pd
PnC
Acs6
A5
rs
RMg
PnV
tz
MSO
LSO
tth
tz
SPO
RPa
vsc
ml
Tz
py
LVPO
bas
MVPO
Interaural -1.04 mm
Bregma -10.04 mm
Figure 61
6
prf
simf
5
4
Sim
pcuf
Crus1
psf
3
pfs
2
unc
PFl
scp
plf
LC
1
SGl
icp
Fl
LR4V
SuVe
SMV
DC
MVePC
8vn
4V
plf
SGe
LVe
MVeMC
VCA
CGPn
g7
ocb
EVe
prb
DMSp5
PCRtA
mlf
6
7n
sp5
Sp5O
I8
Pa6
IS
pd
8cn
PnC
ts
8Gn
IRt
Pr5VL
Acs7
SuS
Gi
A5
P7
rs
tz
7
GiA
LPGi
RMg
7
tth
ml
RPa
CPO
vsc
py
bas
Interaural -1.30 mm
Bregma -10.30 mm
Figure 62
6
simf
prf
5
Sim
4
psf
pcuf
Crus1
3
2
pfs
Lat
unc
PFl
scp
1
A4
SuVe
LC
Fl
SMV
plf
MVePC
DC
icp
LR4V
LVe
4V
MVeMC
8vn
VCA
GrC
SGe
g7
mlf
6
prb
VCP
PCRtA
Pa6
DMSp5
IS
sp5
Sp5O
pd
IRt
SuS
ts
Acs7
Gi
6n
P7
A5
GiA
LPGi rs 7
RMg
tz
tth
ml
PPy
vsc
RPa
py
bas
Interaural -1.52 mm
Bregma -10.52 mm
Figure 63
6
prf
simf
Sim
5
psf
4
pcuf
Crus1
2&3
pfs
Lat
IntA
scp
jx
Y
1
VeCb
LR4V
SuVe
A4
PFl
icp
MVePC
SMV
LVe
DC
4V
Pr
MVeMC
8vn
g7
CI
mlf
GrC
6
Sol
lvs
8n
VCP
sp5
IS
DPGi
DMSp5
PCRtA
IRt
pd
Acs7
Sp5O
ts
SuS
Gi
P7
rs
A5
LPGi
7
RMg
GiA
tz
ml
PPy
vsc
RPa
py
bas
Interaural -1.80 mm
Bregma -10.80 mm
Figure 64
6
prf
5
Sim
psf
4
Crus1
pcuf
5
pfs
2&3
IntA
Lat
Lat
scp
Inf
Y
VeCb
Y
SuVe
LR4V
1
A4
PFl
LR4V
LVe
das
icp MVePC
DC
icp
SMV
4V
SpVe
X
Pr
MVeMC
GrC
CI
SolRL
g7
8n
VCP
mlf
IS
DPGi
sp5
IRt
DMSp5D
Acs7
pd
Sp5O
DMSp5V
PCRtA
ts
Gi
tz
rs
7
LPGi
GiA
A5
RMg
P7
vsc
ml
PPy
RPa
py
bas
Interaural -2.00 mm
Bregma -11.00 mm
Figure 65 6
prf
psf
Sim
4&5
Crus1
pcuf IntDL
IntDM
IntA
Lat
IntA
2&3
Inf
LatPC
VeCb
Y
A4
4V
LVe
DC
LR4V
jx
das
PFl
1
SMV
MVePC
icp
X
SpVe
4V
MVeMC
Pr
sol
8n
mlf
VCP
asc7
GrC
CI
DMSp5D
SolIM
sp5
SolRL
pd
PCRtA
DMSp5V
DPGi
IRt IS
ts
Sp5O
Acs7
Gi
P7
7DL
7DM
ROb
7DI
rs
7
7L
LPGi
7VI
RMg
GiA
7VM
PPy
ml
vsc
C1
R
VL
py
RPa
bas
Interaural -2.30 mm
Bregma -11.30 mm
Figure 66 simf
6
psf
Sim
prf
Crus1
4&5
icf
MedDL
Crus2
IntDM
IntA
2&3
IntP
Lat
Med
IntPPC
LatPC
IntPPC
DC
PFl
1
ECu
LR4V
SpVe
MVePC
icp
X
8n
4V
MVeMC
SolIM
Pr
SolM
C3
SolRL
sol
B4
CI
IS DMSp5D
sp5
mlf
SolVL
IRt
PCRt
DPGi
pd
DMSp5V
Sp5O
ts
Amb
Gi
ROb
P7
rs
7
LPGi
GiA
RMg
7
PPy
RVL
ml
C1
vsc
RPa
py
bas
Interaural -2.60 mm
Bregma -11.60 mm
Figure 67 6
prf
Crus1
icf
Med
Crus2
IntP
plf
Cop
PFl
10
ECu
SpVe
MVePC
4V
X
LR4V
icp
SolIM
Pr
SolM
MVeMC
C3
sol
PFl
B4
sp5
mlf
DMSp5D
EF
SolVL
DMSp5V
CI
DPGi
pd
PCRt
IRt
Sp5I ts
ROb
Amb
Gi
rs
Bo
10n
R
VL
ml C1
IOD
GiV
LPGi
MRVL
vsc
RPa
py
IOM
Interaural -2.80 mm
IOPr
Bregma -11.80 mm
Figure 68 6
prf
Crus1
icf
Crus2
plf
Cop
10
PFl
LR4V
ECu
SpVe
icp
MVePC
4V
X
C3
Pr sol
MVeMC
SolM
B4
DMSp5
EF
SolVL
mlf
SolIM
sp5
CI
DPGi
PCRt
pd
Sp5I
IRt
Gi
ts
Amb
ROb
Bo
rs
RVL
C1
ml
GiV
IOD
vsc
LPGi
MRVL
IOPr
RPa
py
IOM
Interaural -2.96 mm
Bregma -11.96 mm
Figure 69 6
Crus1
7
icf
8
Crus2
9
PM
plf
Cop
10
LR4V
ECu
SpVe
icp
MVe
X
4V
FVe
SolM
sp5
sol Pr
DMSp5
C3
SolIM
B4
C2
mlf
EF
SolVL CI
DPGi
PCRt
IRt
Li
Sp5I
pd
Amb
ts Gi
rs
PrBo
GiV RVL
C1
ml
ROb
IOD
LPGi
vsc
IOM
RPa
py IOPr
Interaural -3.30 mm
Bregma -12.30 mm
Figure 70
6
Crus1
7
icf
ppf
Crus2
8
sf
9
plf
PM
Cop
10
pms
ECu
Pa5 FVe
MVe
icp
Cu
SolIM
X
sol
SolM
In
C2
E5 DMSp5
SolVL
12
C3
10
Ro
B4
sp5
mlf
PCRt
Sp5I
CI DPGi
IRt
PMn
ts
Li
Amb
Gi
rs
RVRG
dsc/oc
RVL
ml
ROb
GiV
C1
LPGi
IOD
vsc
IOM
IODM
IOPr RPa
py
Interaural -3.72 mm
Bregma -12.72 mm
Figure 71
6
pms
Crus1
icf
7
ppf
Crus2
8
sf
9
plf
Cop
PM
pms
10
ECu
icp
MVe
Cu
sol
SolM Pa5
Pa5
X
SolIM
C2
In
SolVL
DMSp5
E5
C3
10 12
Ro
sp5
mlf
DPGi
PCRt
IRt
Sp5I
PMn
Gi
ts
12n
rs
RVRG
Amb
RVL/CVL
C1/A1
ml
ROb
dsc/oc GiV
IODM
LPGi
vsc
IOD
IOM
RPa
py
IOPr
Interaural -3.80 mm
Bregma -12.80 mm
Figure 72
pms
7
ppf
Crus2
8
sf
apmf
9
PM
uf
Cop
9
plf pms
10
ECu
SolDM
cu
SolG
Z
PSol
Cu
C2
chp
icp
SolM
Pa5
sol
4V
SolIM
SolI
10
sp5
SolVL
SolCe
12
Sp5I
Ro
mlf
PCRt
ROb
IRt
PMn
RVRG
ts
Amb
Gi
12n rs
LRtS5 ml
IOBe
IOVL
dsc/oc
C1/A1
R
VL/CVL
IOD
LRt
vsc
LRtPC
IOPr
IOB
IOC
RPa
py
IOA
Interaural -4.24 mm
Bregma -13.24 mm
Figure 73
pms
7
ppf
Crus2
8
sf
apmf
9
PM
pms
Cop
plf
10
ECu
SolG
SolDM
SolIM
Pa5
cu
PSol
sol
Cu
C2
sp5
SolCe
SolM
SolI
10
SolVL
12
Sp5I
PCRt
Ro
ROb
IRt
mlf
PMn
Gi Amb
RVRG
rs
RVL/CVL
ts
dsc/oc
LRtS5
C1/A1
ml
12n
IOBe
IOVL
LRt
IOD
vsc
IOC
LRtPC
RPa
IOB IOPr
py
IOA
Interaural -4.30 mm
Bregma -13.30 mm
Figure 74
7
pms
ppf
8
Crus2
sf
9
apmf
PM
Cop
9
pms
10
ECu
SolDM
cu
Gr
Cu
SolIM
AP
PSol
sol A2
Sp5C
SolC
sp5
SolI
10 SolVL
SolCe
SolM
CC
12
MdD
InM
Ro
IRt
mlf
PMn
Amb Sp5I
RVRG
ROb
MdV
ts
rs
IOK
dsc/oc
C1/A1
LRtS5
12n
RVL/CVL
ml
IOD
IOBe
LRt IOA
IOC
RPa LRtPC
vsc
py
Interaural -4.68 mm
IOB
Bregma -13.68 mm
Figure 75
7
ppf
8
pms
pf
Crus2
8
sf
apmf
PM
9
Cop
pms
ECu
cu
Gr
gr
Cu
SolDM
SolI
AP
sp5
A2 SolC
sol
10
SolVL Sp5C
ia
SolM
SolIM CC
12 MdD
IRt
Ge5
Ro
RVRG
PMn
Amb ROb
CVRG
mlf
Sp5I
MdV
IOK ts
rs
12n
IOBe
ml
A1
RVL/CVL
LRtS5
dsc
IOD
LRt
IOC
RPa
IOB
LRtPC
py
vsc
IOA
Interaural -4.80 mm
Bregma -13.80 mm
Figure 76
ppf
8
sf
9
PM
pms
Cop
9
cu
Gr
gr Cu
SolDM
SolM
AP
sp5
SolI
A2
SolC
sol
10 SolVL
CC
Sp5C
SolIM
12
MdD
ia
RAmb
mlf
PMn
ROb
MdV
ts
IOK
CVRG
CVL
12n rs
A1
dsc
LRt
IOBe
RPa
IOC
IOA
LRtPC
vsc
IOB
py
Interaural -5.08 mm
Bregma -14.08 mm
Figure 77
8
sf
9
PM
Cop
9
Obex
cu
Gr
Cu
gr
SolC
Sol
10 A2
sol
sp5
CC
Sp5C
MdD
12
IRt
CVRG
mlf
ROb
MdV
CVL
A1
RAmb
rs
ts
12n
dsc
LRt
ml
LRtPC
pyx
vsc
RPa
IOM
Interaural -5.30 mm
Bregma -14.30 mm
Figure 78
9
9
cu
Gr
MnA
Cu
gr
SolC
sol Sol
sp5
A2
10
MdD Sp5C
12
CC IRt
RAmb
mlf
MdV
CVRG
rs
A1
ts
CVL
sc
pyx
LRt
IOM
LRtPC
Interaural -5.60 mm
Bregma -14.60 mm
Lateral -0.10 mm
Figure 79
Lateral 0.40 mm
Figure 80
IO
Lateral 0.90 mm
IO
Figure 81
Bregma -9.10 mm
Interaural 0.90 mm
Figure 92
Lateral 1.90 mm
Figure 83
Lateral 2.40 mm
Figure 84
Lateral 2.90 mm
Figure 85
Lateral 3.40 mm
Figure 86
Lateral 3.90 mm
Figure 87
Lateral 4.20 mm
Figure 88
Lateral 4.60 mm
Figure 89
Bregma -9.60 mm
Interaural 0.40 mm
Figure 90
Bregma -9.22 mm
Interaural 0.78 mm
Figure 91
Bregma -9.10 mm
Interaural 0.90 mm
Figure 92
Bregma -8.82 mm
Interaural 1.18 mm
Figure 93
Bregma -8.60 mm
Interaural 1.40 mm
Figure 94
Bregma -8.42 mm
Interaural 1.58 mm
Figure 95
Bregma -8.10 mm
Interaural 1.90 mm
Figure 96
Bregma -7.80 mm
Interaural 2.20 mm
Figure 97
Bregma -7.60 mm
Interaural 2.40 mm
Figure 98
Bregma -7.34 mm
Interaural 2.66 mm
Figure 99
Bregma -7.10 mm
Interaural 2.90 mm
Figure 100
Bregma -6.82 mm
Interaural 3.18 mm
Figure 101
Bregma -6.60 mm
Interaural 3.40 mm
Figure 102
Bregma -6.38 mm
Interaural 3.62 mm
Figure 103
Bregma -6.10 mm
Interaural 3.90 mm
Figure 104
Bregma -5.82 mm
Interaural 4.18 mm
Figure 105
Bregma -5.60 mm
Interaural 4.40 mm
Figure 106
Bregma -5.32 mm
Interaural 4.68 mm
Figure 107
Bregma -5.10 mm
Interaural 4.90 mm
Figure 108
Bregma -4.74 mm
Interaural 5.26 mm
Figure 109
Bregma -4.60 mm
Interaural 5.40 mm
Figure 110
Bregma -4.28 mm
Interaural 5.72 mm
Figure 111
Bregma -4.10 mm
Interaural 5.90 mm
Figure 112
Bregma -3.86 mm
Interaural 6.14 mm
Figure 113
Bregma -3.60 mm
Interaural 6.40 mm
Figure 114
Bregma -3.38 mm
Interaural 6.62 mm
Figure 115
Bregma -3.10 mm
Interaural 6.90 mm
Figure 116
1
Figure 117a*
2
1
dl
dl
1
2
3
3
2
4
3
4
C4 C7
C1 LSp
4
LSp
py
5
py
5
py
5
6
CeCv
10 10
6
IMM
10
7
7
LSp
IMM IMM
7
9
LatC
9
8
9
8 9
8
9
9
9
9 9
9
1
dl
dl 1
2
2
3
3
dl
4
4
C5
1 LSp
C2
C8
2
5
4
3
py
LSp
5
6
LSp py
LatC
5
10
10
py
7
CeCv
IMM
6
7
9
IMM
9
7
IMM
9
9 8
10
9
8
9 9
9
8
9
9
9
9
9
1
dl
2
dl
C6
C3
1
3
T1
2
4
3
1
dl
2
4
LSp
3
py 5
LatC LSp
4
5
py
5
6
IML
LSp
py
10
6
CeCv
7
IMM
9
IMM
7
7 IMM
10
10
9
8
8
8
9 9
9
9
9
9
9
Figure 117b*
1
dl
1
dl
dl
1
1 2 2
L4
3 2
L1
4 3
2
dl T3
S1
3
3 4
py
4
LSp py
4
5
LSp LSp
5
5
5
D
py LSp py
IML
6 IML
6
10
D 7
7
10
10
IMM IMM
9
7
8
10
IMM
IMM 7
9
9
9
8
9
8
9
9
8
9
9
9
9
9
1
2
3
py
4
S2
dl 1 dl
L5 1
L2
2
5
T5
2
LSp
3
4
dl
py
3
1
4
10
LSp
2
5 7
3 5
py
LSp
4
IMM
D
LSp
6
5
IML
10 10
8
IML
py
7
9
IMM
7
IMM
9
7
D
9
IMM
8
8
10
8
9
9
9
9
9
9
1
2
S3
py
dl
3
4
LSp
5
10
7
IMM
8
1 dl
1
9
3
L6
L3 dl
2
3 4
2
T10
4
py
LSp
1
dl
5
5
2
py
4
3
LSp
6
6
IML
LSp
1
5 S4
2
10
py
3
7
IMM
10 4
7
IML
IMM D 9
10
9
7
LSp
5
IMM
8
9
8 8
10
9
7
9
9
9
9
9
IMM
8
9
Go to START PAGE 5
4
3
2
1
0
-1
-2
-3
-4
-5
-6
-7
Bregma
-8
-9
-10
-11
-12
-15
Pineal 6
5
6 6
Corpus Callosum
4
Inferior Superior Colliculus Colliculus
Hippocampus
7 3
3V Fornix
Posterior Commissure
8 Cerebellum
4V
2
Thalamus
Septum
9
Midbrain
1
Anterior Commissure Olfactory Tubercle
-14
Lambda
Cerebral Cortex
Olfactory Bulb
-13
Preoptic Area
Hypothalamus
4V
Pons
9
10
Medulla Oblongata
Optic Chiasm Spinal Cord
Pituitary
Lateral 0.40 mm 14
13
12
11
Interaural 10
9
8
7
6
5
4
3
2
1
0
-1
-2
-3
-4
Click on sagittal diagram to go the corresponding coronal diagram
-5
-6
Go to START PAGE 7
6
5
4
3
2
1
0
1
2
3
6
5
4
7
Corpus Callosum Somatosesnory Cortex Barrel Field
Hippocampus Lateral Ventrical
S2
Auditory Cortex
Mediodorsal Nu
Internal Capsule
VPM
Caudate Putamen (Striatum)
VPL
Thalamus
Hypothalamus
Amygdala Optic Tract
Amygdala
Fornix Piriform Cortex
Lateral Hypothalamus 3rd Ventricle 7
6
5
4
3
2
1
Ventromedial Hy Nu 0
1
2
3
4
5
6
7
Click on Coronal diagram to go the corresponding sagittal diagram
Go to START PAGE
Bregma
10
9
1
Pineal
Cerebral Cortex
Hippocampus
6
Posterior Commissure
4V
Thalamus
Septum
Olfactory Tubercle
1
Preoptic Area
Cerebellum
5
2
9 1
Anterior Commissure
2
4
8
6
Midbrain
3
3
7 3
Fornix Olfactory Bulb
2
4
Inferior Superior Colliculus Colliculus
3V
5
6 6
Corpus Callosum
4
6
5
8
7
0
4V
10
9 7
8
Hypothalamus
Pons
Medulla Oblongata
9
Optic Chiasm 0
Interaural Pituitary
-1
Spinal Cord
10
11
Lateral 0.40 mm
Click on sagittal diagram to go the corresponding horizontal diagram
Plate 1
Plate 2
Plate 3
Plate 4
Plate 5
Plate 6
Plate 7
Plate 8
Plate 9
Plate 10
Plate 11
Plate 13
Plate 15
Plate 17
Plate 19
Plate 21
Plate 23
Plate 26
Plate 29
Plate 31
Plate 33
Plate 35
Plate 37
Plate 39
Plate 41
Plate 43
Plate 45
Plate 47
Plate 49
Plate 51
Plate 53
Plate 55
Plate 57
Plate 59
Plate 61
Plate 63
Plate 65
Plate 67
Plate 69
Plate 71
Plate 73
Plate 75
Plate 77
Plate 79
Plate 80
Plate 81
Plate 82
Plate 83
Plate 84
Plate 85
Plate 86
Plate 87
Plate 92
Plate 94
Plate 96
Plate 98
Plate 100
Plate 102
Plate 104
Plate 106
Plate 108
Plate 110
Plate 112
Plate 114
Plate 116
Plate 117a
Plate 117b
Plate 117c
Plate 117d