MBSC

The
Mouse Brain
in Stereotaxic Coordinates
second edition
George Paxinos
The Prince of Wales Medical Research
Institute
Barker St, Randwick NSW 2031 Australia
(g.paxinos@unsw.edu.au)
(www.powmri.unsw.edu.au/paxinos)
And
School of Psychology
The University of New South Wales
Sydney 2052, Australia
Keith B. J. Franklin
Department of Psychology
McGill University
Montreal, Quebec
Canada H3A 1B1
Academic Press San Diego San Francisco New York Boston London Sydney Tokyo

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Dedicated to
Spyro
Heather

Contents
P R E F A C E
A C K N O W L E D G M E N T S
I N T R O D U C T I O N
G E N E R A L M E T H O D O L O G Y
M E T H O D S
H I S T O L O G Y
P R E P A R A T I O N O F I M A G E S
N O M E N C L A T U R E A N D A B B R E V I A T I O N S
D R A W I N G S
U S E I N S U R G E R Y
U S E O F T H E D A V I D K O P F S T E R E O T A X I C I N S T R U M E N T A N D B R A I N
B L O C K E R
T H E B A S I S O F D E L I N E A T I O N O F S T R U C T U R E S
F O R E B R A I N
H I N D B R A I N
R E F E R E N C E S
L I S T O F S T R U C T U R E S
I N D E X O F A B B R E V I A T I O N S
F I G U R E S
P L A T E S

An atlas is a record of how we see the world and represent
it to our contemporaries, and neuro-anatomical atlases are
no exception. This book is a window through which readers
may view the organization of the mouse brain as is now
understood.
The recent great advances in molecular biology provide
impetus to using the mouse. Because of its short generation
time and the availability of a large number of strains
(including knockout strains), it has been the key mammalian
species in research on genetics and development. Its rapid
growth and short life span are also advantageous for studies
on the biology of aging, while the characteristics of the
mouse immune system are favorable in transplantation
studies.
We decided to construct an atlas of the mouse brain
because of the allure of mapping the relatively uncharted
brain of this species, and the perception that this book
would be of use to the neuroscience community, which has a
growing interest in the mouse. Although there have been
several atlases of the mouse brain produced, until the first
edition of this atlas there had been no new atlas of the
whole mouse brain since the mid-1970s. During this time
there have been major advances in anatomical knowledge,
particularly as a result of neurochemical mapping.
In this atlas we have summarized the current knowledge of
brain anatomy and supplemented it with our observations of
the mouse. To facilitate comparison between the mouse and
the rat, we have retained the general methodology and
familiar format of The Rat Brain in Stereotaxic Coordinates,
4th ed. (Paxinos and Watson, 1998).
P R E F A C E
Features of the Fourth Edition:
1. It is based on the flat-skull position, with bregma,
lambda, and midpoint of the interaural line usable as
reference points.
2. The coronal set features 100 photographic plates and
100 matching diagrams delineating the entire brain.
3. The sagittal set features 32 photographic plates and 3 2
matching diagrams.
4. Photographs of Nissl- and acetylcholinesterase (AChE)
sections alternate.
5. Thoroughly revised cortical delineations as well as
improvements in subcortical areas in light of the
publication of Chemoarchitectonic Atlas of the Rat
Forebrain (Paxinos et al., 1999a) and Chemoarchitectonic
Atlas of the Rat Brainstem (Paxinos et al., 1999b).
6. Diagrams available on CD Rom constructed by Paul
Halasz.

ACKNOWLEDGMENTS
We acknowledge our debt to the scientists and colleagues
who have assisted us in the construction of this atlas.
We owe our special thanks to Hong-Quin Wang for her
commitment and outstanding work in photographing the
sections.
We received invaluable advice from Jan Voogd (cerebellar
and vestibular nuclei) and from George Alheid and Jose de
Olmos (basal ganglia, bed nucleus of t he stria terminalis and
amygdala), Pascal Carrive (periaqueductal gray), Laura Kus
(cortex), Jurgen Mai (hypothalmus), Deborah McRitchie
(solitary nucleus), Laszlo Zaborszky (hypothalamus and basal
forebrain), Charles Watson (facial nucleus), Karl Zilles
(cortex), Luan Ling Zhang (solitary nucleus). We thank them
for the generous gift of their time and knowledge, and for the
pleasure of working with them. Any errors and
misinterpretations that remain are original.
Our drawings and lettering were converted into computer
files by Francis Hong, Mark Hawrychuk, David Morris (Editek
Communications), and Yuri Koutcherov. We thank them for
their painstaking attention to detail.
We thank Janet Raymond for assistance in histology. Our
thanks to Claudio Cuello for providing us with antibodies for
substance P and tyrosine hydroxylase for which we are very
grateful. We thank Glenda Halliday for the staining of the
parvalbumin slides and Gorm Danscher for his excellently
stained Timm’s preparations.
David Kopf Instruments of Tujunga, California, generously
provided us with a mouse stereotaxic head holder.
The completion of the delineations in the atlas was greatly
assisted by a grant from the Canadian Medical Research
Council to Keith Franklin. The preparation of the material on
which the atlas is based was also assisted by grants from the
Australian NHMRC and ARC to George Paxinos and from the
Canadian Natural Science and Engineering Research Council t o
Keith Franklin.
We thank Kevin McConkey and David Tracey (School of
Anatomy, UNSW) for making available departmental facilities
for our work.
We thank Hongmei Lieu and Paul Halasz for imaging the
color plates for the CD-Rom.
Our greatest debt is to Paul Halasz (The Istvan Törk
Confocal Microscope, School of Anatomy UNSW Sydney 2052
NSW Australia P.Halasz@unsw.edu.au) for designing and
constructing the CD Rom.
Finally, and most heartfelt, we thank our wives, Elly and
Fran, and our children Alexi, Yvette, Zoë, Rowena, and George
for their patience in tolerating our absences and
preoccupations, and for their generous hospitality, over many
years of a peripatetic collaboration.

INTRODUCTION
General Methodology
The brain depicted in the coronal atlas was the most
complete in a sample of brains from 26 adult C57BL/J6 mice
(weight range 26–30 g). The choice of mouse strain and
weight range presented some difficulties because mouse
strains vary much more in weight and brain anatomy than rat
strains (see Wahlsten et al., 1972). The C57BL/J6 strain was
chosen because it is one of the most widely used strains and
is of intermediate size. The weight range selected represents
the fully adult male mouse. Stereotaxic surgery on the mouse
is relatively difficult because of the great fragility of the
mouse skull. We therefore chose a weight range
representative of the fully adult mouse in which the skull is
calcified and presumably stronger.
Some adjustments for use of this atlas with other strains
can be calculated from Wahlsten et al. (1972) who show
stereotaxic grids in the sagittal plane for seven strains of 77-
to 78-day-old mice, with the same skull flat orientation as
this atlas.
The atlas represents the areas of the brain from the
olfactory bulb to the middle of the medulla oblongata. Plates
are usually 120 mm apart, except where no usable sections
were available, and the interplate distance is as small as 4 0
mm or as large as 160 mm. Alternate sections are stained
with cresyl violet or are reacted to reveal
acetylcholinesterase (AChE). Intermediate sections were
processed immunohistochemically to reveal parvalbumin.
These sections were used to aid delineation, but are not
reproduced in the atlas. Other histochemical markers used t o
assist delineation, but not shown in the atlas, include
immunohistochemical stains for substance P and tyrosine
hydroxylase, Timm’s reaction for zinc, the NADPH–
diaphorase stain for nitric oxide synthase, and the
iron–hematoxylin stain for myelin.
Structures were delineated using The Rat Brain in Stereotaxic
Coordinates, 4th ed. (Paxinos and Watson, 1998), The
Rat Nervous System, 2nd ed. (Paxinos, 1995), Chemoarchitectonic
Atlas of the Rat Forebrain (Paxinos et al., 1999)
and Chemoarchitectonic Atlas of the Rat Brainstem (Paxinos
et al., 1999) as the primary guides, supplemented by
consideration of the delineations in the Swanson (1992) atlas
and specific information on the mouse obtained from previous
atlases of the mouse brain, journal articles, and our own
observations.
Methods
SURGERY All procedures involving live animals were carried
out in accordance with accepted ethical principles for animal
research and were approved by the relevant Animal Ethics
committees of The University of New South Wales and McGill
University.
While under sodium pentobarbital anesthesia, the mice
were placed in a Kopf small animal stereotaxic instrument.
The head was positioned by means of a mouse nose clamp
adaptor (Kopf Model 922) supplemented by rat ear bars
(Kopf Model 957) placed lightly in the external auditory
meatus to locate the interaural line. [NOTE: because the skull
of the mouse is extremely fragile and easily compressed, the
Kopf mouse holder is designed to be used without ear bars
(Slotnick, 1972). If ear bars are used they must be inserted

with only a few grams of pressure or else the bones of
external auditory meatus or the skull will be crushed. Ear bars
can be used successfully if they are inserted so as to merely
touch the meatus, but any further pressure may lead t o
breathing difficulties.]
The position of the head was adjusted so that the height of
the skull surface at bregma and lambda was the same.
Lambda was defined as the point of intersection of the bestfit
lines passing through the sagittal suture and the left and
right portions of the lambdoid suture (see skull diagram
below). The mean (± SD) position of bregma was 3.8 ( ±
0.25) mm rostral and 5.8 (± 0.48) mm dorsal to the
interaural line (IA). Lambda was located 0.41 (± 0.26 ) mm
caudal and 5.8 mm dorsal to the interaural line. These values
were used to define the scaling of distances on the
stereotaxic grid.
To establish the stereotaxic position of brain structures,
reference needle tracks were made perpendicular to the
horizontal and coronal planes and at predetermined distances
from bregma and the interaural line (vertical tracks: 2 mm
anterior to bregma and 1 mm anterior to the IA; horizontal
track: 3 mm above the IA; all tracks were 1.5 mm lateral t o
the midline).
The coronal set of the first edition reached only the level of
the area postrema. For the second edition we inserted
another 7 levels obtained from a different mouse of the same
strain and weight.
The sagittal set was obtained in a similar manner as the
coronal set and with insertion of fiducial marks in a fashion
similar to that for the sagittal set for The Rat Brain in
Stereotaxic Coordinates, 4th ed. (Paxinos and Watson,
1998).
Histology
After surgery, while still under anesthesia, mice were killed by
transcardial perfusion of 20 ml ice-cold phosphate buffered
saline (0.1 M PBS, pH 7.3), followed by 20 ml of 4%
paraformaldehyde in PBS. The brain was immediately
dissected free from the skull and placed dorsal surface down
in a small aluminum foil boat containing 1.5% gelatin
dissolved in 0.9% saline solution. The aluminum foil boats
were made by folding aluminum foil around an appropriately
sized rectangular block (20 _ 12 _ 12 mm). The brain was
oriented in the boat so that its anterior–posterior axis was
parallel to the long axis of the boat. When suspended in the
gelatin solution, the brain floats so that its dorsal surface is
almost exactly parallel to the flat skull horizontal plane. When
the brain was correctly positioned, the boat was placed in a
refrigerator for 20 min for the gelatin to jell. The sides of the
aluminum boat were then folded down to expose t he gelatin
block. The foil now formed a tray that was used to lower the
gelatin block into dry ice-cooled isopentane. The block was
lowered slowly so that freezing proceeded rostrally through
the brain, from brainstem to olfactory bulb, and no more than
1–2 mm of unfrozen tissue was below the surface of the
isopentane at any time. The frozen block was then stripped
of the remaining aluminum foil and attached to the chuck of
the microtome with mounting medium. The planar sides of
the rectangular block were used to orient the block on the
chuck, with the anterior–posterior axis of the brain
perpendicular to the surface of the chuck. Only minor
adjustment of the orientation of the chuck in the microtome

was then necessary to cut sections perpendicular to the
horizontal and vertical stereotaxic planes.
The brain was cut at 40-µm thickness sections. Unattached
gelatin was brushed away, and the section was taken up into
a drop of PBS on the surface of an acid-cleaned and
gelatinized slide. Out of every three successive sections, two
were taken onto a slide designated for staining of Nissl or
AChE. If the first two sections were deemed satisfactory, the
third was set aside in ice-cold PBS for parvalbumin
immunohistochemistry. The following three sections were
designated for staining of AChE or Nissl, respectively, as per
the protocol of Paxinos and Watson (1986). A detailed Nissl
and AChE staining protocol can be found at the web site
www.psy.unsw.edu.au/users/gpaxinos.
This technique was developed to reliably obtain precisely
oriented sections of relatively undistorted mouse brain in
which Nissl- and AChE-stained sections alternated. Fresh or
lightly fixed mouse brain tissue is so soft that it distorts
under its own weight, but it assumes its normal shape when
supported in a viscous fluid. Jelled gelatin solution adequately
supports the brain during freezing, but the gelatin causes the
sections to curl when they are cut in a freezing microtome.
The addition of sodium chloride to the gelatin solution
promotes the formation of fine crystals in the gelatin block
so that the embedding material shatters when sectioned, and
can be gently brushed away from the frozen sections.
Freezing must proceed steadily through the long axis of the
block. If the whole block is placed directly into the cooling
medium, the outside of the block freezes and forms a rigid
shell so that when the brain expands during freezing, it
distorts. Sections were taken up into a drop of PBS t o
eliminate minute bubbles which become trapped under the
section if sections are thawed directly onto a slide. With
partially fixed mouse brain, the minute bubbles perforate the
section when it dries.
Preparation of Images
Photographs of selected sections were made onto 4 __5
inch Kodak Plus X or AGFA negatives using a Nikon Multifid
photomicroscope, and 20 x 22 inch black and white prints
were made of these negatives on AGFA multigrade
photographic paper. The delineations and fiducial marks were
hand drawn onto acetate tracing paper placed over the
photographs. The tracings were scanned, and the resulting
images were used as a template for tracing using CorelDraw
5.0 for Windows (coronal set) or Adobe Illustrator 8.0 for
Mac OS (sagittal set).
Nomenclature and Abbreviations
The nomenclature and abbreviations used are those that
have been employed in The Rat Brain in Stereotaxic
Coordinates, 4th ed. (Paxinos & Watson, 1998), The Mouse
Brain in Stereotaxic Coordinates (Franklin & Paxinos, 1997),
Atlas of the Developing Rat Nervous System (Paxinos et al.,
1994), Chemoarchitectonic Atlas of the Rat Forebrain
(Paxinos et al., 1996b), Chemoarchitectonic Atlas of the Rat
Brainstem (Paxinos et al., 1999a, b), The Rhesus Monkey
Brain in Stereotaxic Coordinates (Paxinos et al., 2000), Atlas
of the Human Brainstem (Paxinos & Huang, 1995), and Atlas
of the Human Brain (Mai, Asscheuer, & Paxinos, 1997). We
have made a conscious effort to use identical abbreviations
for homologous structures in various species so that readers
do not have to be burdened with a meaningless task of

learning different abbreviations for the same structures.
Bowden and Martin (1995) in their atlas of the monkey brain
used the same principles for construction of abbreviations as
we have used here.
There are more than 20 ways to abbreviate “accumbens
nucleus”: Acb, ACB, acb, NAS, nas, A, a, Ac, ac, NA, na, AN,
an, NAC, nac, ACN, acn, ACU, acu, ACC, and Acc. The user of
this atlas is welcome to use our abbreviation Acb, the same
abbreviation we used in all our other atlases.
The principles used in the construction of abbreviations are
the same as those used to derive the abbreviations for the -
elements of the Periodic Table and for the word
acetylcholinesterase (AChE).
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.
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).
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, i t
is usually given the same abbreviation (e.g., Rt = reticular
thalamus 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.
Abbreviations representing nuclei and cortical regions are
shown in uppercase characters on the left side of the figures,
except where structures were only visible on the other side of
the section. Fiber tracts and fissures are abbreviated in
lowercase characters and are shown on the right side of the
figures.
Drawings
It was thought that the drawings would be more
informative if they were not stylized, and for this reason, with
the exception of small adjustments to distorted midlines and
cortex, the drawings depict the asymmetries present in the
sections. When part of a section was missing or severely
distorted, it was drawn in after consideration of sections
obtained from other brains.
Coronal Plane
The large number at the bottom left of each figure shows
the anteroposterior distance of the corresponding plate from
the vertical plane passing through the interaural line. The
large number at the bottom right shows the anteroposterior
distance of the plate from bregma. 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 top and bottom
margins show the distance of structures from the midline.
Sagittal Plane
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 passing through the interaural line. The
numbers on the top margin show the anteroposterior
distance from the coronal plane passing through bregma.
Use in Surgery
If it is necessary to insert an electrode into the
ventromedial hypothalamic nucleus, Fig. 44 reveals the
coordinates with reference to the interaural line to be 2.22
mm anterior to the interaural line, 0.25 mm dorsal to it, and
0.9 mm lateral to the midline. The coordinates of the same
structure obtained with reference to bregma are 1.58 mm
anterior to bregma, 5.5 mm ventral to it, and 0.9 mm lateral
to the midline. The location of bregma and lambda on the
mouse skull is shown in the skull diagram.
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.
The Basis of Delineation of
Structures
The principal references for our work on the mouse atlas
have been The Rat Brain in Stereotaxic Coordinates, 4th ed.
(Paxinos and Watson, 1998) and The Rat Nervous System,

2nd ed. (Paxinos, 1995). This was supplemented by
reference to anatomical studies on specific regions in the
mouse and consideration of the atlas of Swanson (1992), as
well as material on the chemoarchitecture of the rat brain in
which each section of the rat brain is depicted after being
stained for parvalbumin, calbindin, calretinin, Nissl, SMI32,
tyrosine hydroxylase, and NADPH–diaphorase (Paxinos et al.,
1999a, b).
To resolve ambiguities in delineations based on the Nissl
and AChE distribution, we examined mouse brains stained t o
reveal other neurochemical markers, including substance P,
parvalbumin, NADPH–diaphorase, tyrosine hydroxylase, and
zinc (Timm’s). In many cases, assistance with the
construction of boundaries was provided by a number of
colleagues who have special knowledge of the anatomy of
particular brain regions (see Acknowledgments). We also
benefited from our examination of the delineation of
structures in a number of rat, mouse, cat, and human brain
atlases (Berman and Jones, 1982; Jacobowitz and Palkovits,
1974; König and Klippel, 1981; Olszelwski and Baxter, 1954;
Palkovits and Jacobowitz, 1974; Pellegrino et al., 1979;
Slotnick and Hersch, 1980; Slotnick and Leonard, 1975;
Zilles, 1985; Paxinos et al., 1994; Huang and Paxinos, 1995)
and maps of the distribution of neurochemical markers
(Arimatsu et al., 1981; Vincent and Kimura, 1992; Rodrigo et
al., 1994; Loren et al., 1979; Bartsch, 1991).
Some brief notes on the neuroanatomical literature on the
mouse brain and on delineations that differ significantly from
the delineations of the rat brain in Paxinos and Watson
(1986) are provided below. For a more extensive rationale of
the delineations of structures see Paxinos and Watson (1986;
1997).
Forebrain
Olfactory System
Olfactory structures were delineated according to the
description of Shipley et al. (1995), and detailed delineations
of the mouse olfactory bulb and its connections are found in
Bucherelli et al. (1993), Caviness and Sidman (1972), and
Shipley and Adamec (1984).
Cortex
Our delineation is based primarily on recent delineations of
the cortex of the rat (Zilles and Wree, 1995) and has to be
considered as tentative, given that the mouse cortex is
different. We supplemented the observations of Zilles and
Wree (1995) by examination of the intervening sections from
the atlas brain that were immunoreacted for parvalbumin.
For a description of the cytoarchitectonic fields of the
mouse cortex, see Caviness (1975). The distribution of
choline acetyltransferase and acetylcholinesterase in mouse
cortex and other structures is described in Kitt et al. (1994)
and Arimatsu et al. (1981). The SMI immunoreactivity of the
rat cortex (Paxinos et al., 1999a, b) was critical in suggesting
a possible plan for the mouse cortex. Consideration of the
delineation of the posterior parietal region in Swanson (1992)
was very helpful. That atlas was also assisted by the
delineation of the rostral panhandles of the lateral entorhinal
cortex and the entorhinal cortex (Swanson, 1992).
Hippocampus and entorhinal cortex delineations were based
on Amaral and Witter (1995). The work of Slomianka and
Geneser (1991a,b) was helpful because they describe the
distribution of AChE in the hippocampal region of the mouse.

Basal Ganglia and Basal Forebrain
The basal ganglia and basal forebrain were delineated by
comparison with the rat, guided by the densities of Nissl,
AChE staining, and substance P immunoreactivity. Refer t o
Heimer et al. (1995) for a discussion of the organization
description of the basal ganglia in the rat. The cholinergic
innervation of the basal forebrain in the mouse has been
described by Kitt et al. (1994).
INTERSTITIAL NUCLEUS OF THE POSTERIOR LIMB OF
THE ANTERIOR COMMISSURE (IPAC) Dorsal to the
anterior amygdaloid area and ventral to the fundus striati lies
a region that is less cellular and less reactive for AChE than
the fundus striati (Figs. 22–24 in Paxinos and Watson, 1986).
In the rat, this region is shown to be reactive for substance P
(Fig. 3E of Haber and Nauta, 1983), and this reactivity is
continuous with that of the globus pallidus. The region has
similar characteristics in the mouse. Paxinos and Watson
(1986) named this region the substriatal area (SStr). More
recently it has been suggested (Alheid et al., 1995) that this
region should be named the interstitial nucleus of the
posterior limb of the anterior commissure (IPAC) on the basis
of its association with the posterior limb of the anterior
commissure throughout most of its course, and we have
followed this proposal (Figs. 27–36). This region is distinctive
in receiving particular afferents from the amygdala. It is
densely stained by Timm’s reaction and AChE, and the dorsal
and lateral part of the region is densely supplied with
substance P terminals. In the rat the IPAC is distinguished by
receptor binding for calcitonin (Skofitsch and Jacobowitz,
1992) and vasopressin (Tribollet, 1992).
SUBSTANTIA INNOMINATA (SI) Following the carving
out of the ventral pallidum from the substantia innominata,
the remainder (posterior part) was called the sublenticular
part of the SI (Heimer et al., 1985). Paxinos and Watson
(1986) noticed that a strip of substantia innominata persists
rostrally bounded by the ventral pallidum, the lateral preoptic
area, the nucleus of the horizontal limb of the diagonal band,
and the magnocellular preoptic nucleus. They retained the
term substantia innominata for this panhandle. It has been
argued that the cells of this region, traditionally called
substantia innominata, represent the rostral end of a
continuous column of cells stretching from the amygdala in
the temporal lobe to the forebrain (Alheid et al., 1995).
Alheid et al. (1995) have named this region the sublenticular
extended amygdala and divided it into two parts: a medial
division (SLEAM) and a central division (SLEAC). In the mouse
we have retained the more traditional delineation of the
substantia innominata, but also show the proposed division
into medial and central sublenticular extended amygdala
(Figs. 34–39). The central division corresponds to the
anterodorsal substantia innominata (De Olmos et al., 1985),
or what Grove (1988a,b) termed the dorsal subdivision of the
SI, which is lightly stained with AChE and Timm’s reaction.
The medial division corresponds to Grove’s ventral division of
the substantia innominata, or the posteroventral substantia
innominata of De Olmos et al. (1985), and it stains
moderately for substance P, AChE, and Timm’s reaction.
BASAL NUCLEUS (B) The cholinergic cells of the basal
nucleus of Meynert straddle the border between the globus
pallidus and the internal capsule, invading both of these
structures (Figs. 34–36). For a general description of the
distribution of cholinergic neurons in the basal forebrain in the
mouse, see Kitt et al. (1994).

SUBTHALAMIC NUCLEUS The subthalamic nucleus (Figs.
45–52) is prominent in the mouse. Laterally it is lens shaped,
as in the rat, but medially it becomes more rounded than in
the rat. At the caudal limit of the subthalamic nucleus there
is a tightly packed group of cells that extends caudally from
the posterior limit of the magnocellular nucleus of the lateral
hypothalamus to about 200 mm rostral to the substantia
nigra (Sturrock, 1991; Broadwell and Bleier, 1977). The
appearance of this distinct cluster of cells is quite different
from the subthalamic nucleus in the rat, monkey (Paxinos et
al., 1996), or human (Paxinos and Huang, 1995) and we have
not assimilated it to the subthalamic nucleus as have some
authors (Sturrock, 1991; Broadwell and Bleier, 1977). Wang
(1995) has suggested that the cell group should be
distinguished from the subthalamic nucleus as the
parasubthalamic nucleus (PSTh), and we have followed his
suggestion.
Hypothalamus
Our delineation of the hypothalamus is based on the
description of Simerly (1995). The general cytoarchitecture
of the mouse hypothalamus has been described by Broadwell
and Bleier (1977). The distribution of aromataseimmunoreactive
cells in the hypothalamus and other areas
has been mapped by Foidart et al. (1995). See Ruggiero et
al. (1984) and Baker et al. (1993) for a description of
catecho-laminergic cells in the hypothalamus of the mouse.
The medial preoptic area was delineated in accordance with
Simerly (1995) except for the ventromedial preoptic nucleus
(VMPO), which was delineated in accordance with Elmquist et
al. (1996). See Paxinos and Watson (1997) for additional
discussion of this issue.
A NTEROVENTRAL PERIVENTRICULAR NUCLEUS
(AVPe) This small compact, rostral cell group (Figs.
26–30) was named the medial preoptic nucleus by Bleier et
al. (1979), but most other researchers reserve this term for
the larger nucleus that succeeds it posteriorly. Both of these
nuclei are part of the sexually dimorphic region (Bleier et al.,
1982). For the mouse brain we have adopted the term
“anteroventral periventricular nucleus” (Swanson 1992),
which is descriptive of its position and has become more
widely used.
ANTERODORSAL PREOPTIC NUCLEUS (ADP) This
nucleus is delineated on the basis that it is distinctly labeled
by tyrosine hydroxylase immunoreactivity in the mouse
(Ruggiero et al., 1984). It lies just ventral to decussation of
the anterior commissure, lateral to the periventricular nucleus
and median preoptic nucleus, and medial to the ventral medial
division of the bed nucleus of the stria terminalis (Figs. 3 0
and 31). In Nissl-stained sections it contains small, round t o
ovoid, lightly staining cells. In sections treated to reveal
tyrosine hydroxylase-like immunore-activity, the nucleus
appears as a tongue protruding laterally from the third
ventricle, dorsal to the medial preoptic nucleus. In the rat and
other mammalian orders, the region does not contain
catecholaminergic cells (see Ruggiero et al., 1984). We have
followed the suggestion of Ruggiero et al. (1984) and
identified the catecholamine cell group as an extension of
A14.

ANTERIOR HYPOTHALAMIC NUCLEUS (AH) Controversy
exists over the location of the anterior hypothalamic
nucleus. We followed Paxinos and Watson (1986) in dividing
the AH into three parts that merge into each other. However,
our most anterior part is immediately dorsal to that which
was identified by Saper et al. (1978) as the “anterior part of
the anterior hypothalamic nucleus.” The “anterior part of the
anterior hypothalamic nucleus” of Saper et al. (1978)
corresponds to the “lateral anterior hypothalamic nucleus” of
Bleier et al. (1979). Our “anterior part of the anterior
hypothalamic nucleus” is immediately dorsal to the “lateral
anterior hypothalamic nucleus” and ventral to the bed
nucleus of the stria terminalis (Figs. 34–36). The central part
of the anterior hypothalamic nucleus of Saper et al. (1978)
and our Figs. 37 and 38 correspond to the dorsal tuberal
nucleus of Bleier et al. (1979). The posterior part of the
anterior hypothalamic nucleus is immediately ventral to the
most caudal part of the paraventricular hypothalamic nucleus
(Figs 39–42). Within the dorsal aspects of the posterior par t
of the AH there is a small, dense cluster of cells that is
positive for glutamic acid decarboxylase in the rat. Paxinos
and Watson (1986) named it the stigmoid (dot-like) nucleus
(Stg; Fig. 41).
SU PRAOPTIC AND PARAVENTRICULAR
NUCLEI Delineations are according to Armstrong (1985).
See Silverman and Pickard (1983) for a description of these
nuclei in the mouse (Figs. 36–41).
Thalamus
The delineatation of the thalamic nuclei is based on its
characteristics in the rat as described by Price (1995) and
Paxinos and Watson (1986). For descriptions of the thalamus
of the mouse, see Baker et al. (1993) and Carvell and Simons
(1987). The nomenclature follows Price (1995). The
gelatinosus nucleus (G in Paxinos and Watson) is designated
as the submedial nucleus (O’Gorman and Sidman, 1996)
(Sub; Figs. 39–46) because this term has become more
widely used. The small-celled region in the medial part of the
ventroposteromedial nucleus (designated “Gu” in Paxinos and
Watson, 1986) is recognized as having additional functions
to gustation, but we label it “gustatory” for its principal
function (Figs. 47–50).
We follow Paxinos and Watson (1986) in delineating the
ethmoid nucleus (Eth; Figs. 52–54) and retroethmoid nucleus
(Reth; Figs. 53–55).
MAGNOCELLULAR LATERAL HYPOTHALAMIC NUCLEUS
(MCLH) A
magnocellular nucleus with AChE-positive cells
is found ventromedial to the internal capsule at the
anteroposterior level of the perifornical and subincertal nuclei
(Figs. 43–48). This nucleus has been termed the lateral
tuberal nucleus by Bleier et al. (1979), but this term is
problematic given that it refers to another structure in
primate literature. We have followed Paxinos and Watson
(1986) and used the name magnocellular lateral
hypothalamic nucleus.
Hindbrain
PERIACQUEDUCTAL GRAY The periaqueductal gray (Figs.
52–74) is divided into longitudinal columns as proposed by
Andrezik and Beitz (1985) and Carrive et al. (1987) (see also
Carrive, 1993). Delineation was assisted by the fact that the
dorsolateral lateral column shows a darker
acetylcholinesterase reaction than the other columns,
whereas the dorsomedial PAG is least reactive (Graybiel and

Illing, 1994). In NADPH–diaphorase-stained sections the
dorsolateral column also shows more intense reactivity
(Carrive and Paxinos, 1994). The NADPH–diaphorase reactive
cells and plexus of reactive fibers and terminals in the
supraoculomotor cap (SU3C; Figs. 61–66) (Carrive and
Paxinos, 1994) are clearly visible in the mouse (unpublished
observations).
DORSAL RAPHE The subdivision of the dorsal raphe was
guided by recent descriptions of the raphe in the human
(Huang and Paxinos, 1995).
NUCLEUS OF THE SOLITARY TRACT The delineation of
the solitary tract nucleus (Figs. 83–93) was based on Luan
Ling Zhang (1999) and on McRitchie (1992) and is similar t o
the delineations in the rat described by Norgren (1995) for
the rostral, gustatory part and by Saper (1995) for the
caudal, autonomic part.
SUPERIOR OLIVE The superior olive delineation was based
on Ruigrok and Cella (1995). A similar delineation in the
normal and “lurcher” mutant mouse can be found in Heckroth
and Eisenman (1991).
PARABRACHIAL N UCLEU The subdivisions of the
parabrachial nucleus (Figs. 73–78) were delineated following
the description in the rat by Saper (1995).
CEREBELLUM AND CEREBELLAR NUCLEI The cerebellar
nuclei are delineated according to Voogd (1995). It should be
noted that the folial pattern of the cerebellum is different in
different strains of mice and that the C57BL/J6 strain has
one of the simplest patterns (Inouye and Oda, 1980).

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SKULL DIAGRAM The dorsal surface of the mouse skull showing the horizontal plane reference points, bregma and lambda. Lambda is defined as the point of
intersection of the projection of lines of best fit through the sagittal and lambdoid sutures.

THE BRAIN BLOCKER Designed to reproduce the plane of section of The Mouse Brain in Stereotaxic Coordinates (PA 0021; David Kopf Instruments, P.O. Box
636, Tujunga, CA 91043, davidkopf@earthlink.net).

THE CORTEX OF THE MOUSE FLATTENED
DP
MO
PrL
Cg1
FrA
M2
M1
S1BF
DLO
AI
AIV
LO
VO
IL
RSA
Cg2
RSG
S1HL
S1FL
S1DZ
S2
AIP
PRh
Ect
TeA
AuV
MPtA
LPtA
Au1
AuD
V1
V2ML
V2MM
V2L
AuV
TeA
Ect
PRh
LEnt
MEnt
S1Tr
S1J
S1ULp
Cg/RS
S1ShNc
AIV
Cg1
M2
Pir
PRh
Ect
V1
V2L
V2MM
RSA
AID
AID
M1
GI
DI
DI
GI

THE CORTEX OF THE MOUSE FLATTENED. The bottom of the map (x axis) represents the medioventral limit of the cortex at each
coronal section of the atlas. The vertical axis (y axis) of the map represents distance from the medioventral margin measured
around the surface of the cortex.
The map was constructed from the coronal sections by measuring the distance, around the circumference, from the
medioventral limit of the cortex (e.g. the corpus callossum) to each boundary between cortical regions. These data were
collected for each coronal section and plotted against the anterior posterior position of the sections. The resulting graph was
used as a template to draw the map. Minor irregularities were removed by drawing fair curves through the plotted points. Where
the margin of the cortex is at the corpus callossum, the medioventral margin of the cortex approximates a straight line, and the
distortion in the representation is minimal. However, at the rostral and caudal extremes of the brain the distortion in the
representation increases because the medioventral margin of the cortex increasingly deviates from a straight line.
AI agranular insular cortex
AID agranular insular cortex, dorsal
AIP agranular insular cortex, posterior
AIV agranular insular cx, ventral
Au1 primary auditory cortex
AuD secondary auditory cx, dorsal
AuV secondary auditory cx, ventral
Cg/RS cingulate/retrosplenial
Cg1 cingulate cortex, area 1
Cg2 cingulate cortex, area 2
DLO dorsolateral orbital cortex
DP dorsal peduncular cortex
Ect ectorhinal cortex
FrA frontal association cortex
LEnt lateral entorhinal cortex
LO lateral orbital cortex
M1 primary motor cortex
M2 secondary motor cortex
MEnt medial entorhinal cortex
MO medial orbital cortex
MPtA medial parietal ass cx
Pir piriform cortex
PRh perirhinal cortex
PrL prelimbic cortex
RSA retrosplenial agranular cortex
RSG retrosplenial granular
S1BF S1 cx, barrel field
S1FL S1 cx, forelimb region
S1HL S1 cx, hindlimb region
S1J S1 cx, jaw region
S1ShNc S1 cx, shoulder/neck
S1Tr S1 cx, trunk region
S1ULp S1 cx, upper lip region
S2 secondary somatosensory cortex
TeA temporal association cortex
V1 primary visual cortex
V2L secondary visual cx, lateral area
V2ML secondary visual cx, mediolat
V2MM secondary vis cx, mediomed
VO ventral orbital cortex

6
5
5 4 3 2 1 0 -1 -2 -3 -4 -5 -6 -7 -8
Cerebral Cortex
Bregma
Lambda
Superior
Colliculus
Inferior
Colliculus
Cerebellum
Bregma
0
1
4
Olfactory
Bulb
corpus c allosum
LV
Hippoc
2
3
Septum
posterior c om
3
Thalamus
Midbrain
4V
2
anterior
commissure
fornix
4
1
Preoptic
Area
Hypothalamus
Pons
Medulla
Spinal
5
0
Interaural
Lateral 0.24 mm
Interaural
Cord
6
9 8 7 6 5 4 3 2
1
0 -1 -2 -3 -4
SAGITTAL SECTION OF THE MOUSE BRAIN A drawing of a section of the mouse brain cut in a sagittal plane .24 mm lateral to the midline (Fig 103 of this atlas).
Ventricles are shown in black. The position of the skull marks (bregma, lambda and interaural) are indicated. The top grid line indicates anteroposterior
locations in relation to the 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 place passing through the interaural line.

Other Academic Press Books by Paxinos
1. Paxinos, G. and Watson, C. The Rat Brain in Stereotaxic Coordinates, 4th Edition, Academic Press, 1998. Contains coronal,
sagittal, and horizontal plates and diagrams. The second most cited book in science. Available with and without CDRom.
2. Paxinos, G. and Watson, C., The Rat Brain in Stereotaxic Coordinates, Compact 3rd Edition, Academic Press, San Diego,
1997. Coronal diagrams and CDRom only (student version).
3. Paxinos, G. (Ed.), The Rat Nervous System, Second Edition, Academic Press, San Diego, 1995. A comprehensive description
of regions and systems of the rat brain by some of the most senior scientists in t he field.
4. Paxinos, G, Kus, L, Ashwell, K and Watson, C, Chemoarchitectonic Atlas of the Rat Forebrain, Academic Press, San Diego,
1999. Presents 242 fully delineated photographic plates stained for parvalbumin, calbindin, calretinin, SMI32, Nissl, tyrosine
hydroxylase and NADPH-diaphorase.
5. Paxinos, G, Carrive, P, Wang, H, and Wang, P-Y. Chemoarchitectonic Atlas of the Rat Brainstem, Academic Press, San Diego,
1999. Presents 243 fully delineated photographic plates stained for parvalbumin, calbindin, calretinin, SMI32, Nissl, tyrosine
hydroxylase and NADPH-diaphorase.
6. Paxinos, G, Ashwell, KWS and Törk, I, Atlas of the Developing Rat Nervous System, Academic Press, San Diego, 1994. Serial
sections through the embryonic and neonatal rat brain (E14, E16, E17, E19, P0).
7. Mai, J., Asscheuer, J. and Paxinos, G., Atlas of the Human Brain, Academic Press, 1997. Winner of the Association of
American Publishers Award for Excellence in Medical Publishing.
8. Paxinos, G. (Ed.), The Human Nervous System, Academic Press, San Diego, 1990. A comprehensive description of regions
and systems of the human brain by some of the most senior scientists in the field.
9. Paxinos, G., and Huang, X.-F., The Human Brainstem, Academic Press, San Diego, 1995. Sixty four plates and 64 diagrams
at 1-mm intervals through the brainstem.
10. Paxinos, G., Huang, X.-F. and Toga, A.W., The Rhesus Monkey Brain in Stereotaxic Coordinates, Academic Press, San Diego,
2000. The most comprehensive atlas of the monkey cortex and subcortex ever made. One hundred and fifty one plates and
151 fully labeled diagrams through the brain; Sixty four fully labeled photographs of sections reacted with an antibody t o
neurofilament protein (SMI32).
Web address of Paxinos: http://www.psy.unsw.edu.au/users/gpaxinos Can be ordered via: http://www.academicpress.com

Reproduction
of Figures by Users of the Atlas
Exporting Figures for Annotation and Printing
For permission to reproduce figures contained in this
publication, contact the publisher at the following address:
Academic Press Permissions Department 6277 Sea
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Permission to reproduce a limited set of figures is usually a
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The same procedure should be followed for reproduction of
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The authors would like users of the atlas to consider the
suitability of the nomenclature and abbreviation scheme in
this book for their own work. The scheme used here is
systematic and is based on the principles of the construction
of abbreviations for the elements of the periodic table and
abbreviations of words such as acetylcholinesterase (AChE).
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LIST OF STRUCTURES
Names of the structures are listed in
alphabetical order. Each name is followed by
abbreviation of the structure.
1st Cerebellar lobule 1Cb
3rd ventricle 3V
4&5th Cerebellar lobules 4&5Cb
4th ventricle 4V
5th Cerebellar lobule 5Cb
6th Cerebellar lobule 6Cb
7th Cerebellar lobule 7Cb
8th Cerebellar lobule 8Cb
9th Cerebellar lobule 9Cb
10th Cerebellar lobule 10Cb
A
A11dopamine cells A11
A12 dopamine cells A12
A13 dopamine cells A13
A14 dopamine cells A14
accessory abducens/facial nucleus Acs6/7
accessory facial nucleus Acs7
accessory neurosecretory nuclei Acc
accessory nucleus of the ventral horn Acs
accessory olfactory bulb AOB
accessory olfactory tract aot
accessory optic tract aopt
accessory trigeminal nucleus Acs5
accumbens nucleus Acb
accumbens nucleus, core AcbC
accumbens nucleus, shell AcbSh
acoustic radiation ar
agranular insular cortex, dorsal part AID
agranular insular cortex, posterior part AIP
agranular insular cortex, ventral part AIV
alveus of the hippocampus alv
ambiguus nucleus Amb
amygdalohippocampal area, anterolateral part
AHiAL
amygdalohippocampal area, posterolateral
AHiPL
amygdalohippocampal area, posteromedial part
AHiPM
amygdaloid fissure af
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 commissural nucleus AC
anterior commissure ac
anterior commissure, intrabulbar part aci
anterior cortical amygdaloid nucleus ACo
anterior hypothalamic area AH
anterior hypothalamic area, anterior part AHA
anterior hypothalamic area, central part AHC
anterior hypothalamic area, posterior part
AHP
anterior interposed nucleus AInt
anterior lobe cerebellum Ant
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, posterior part AOP
anterior perifornical nucleus APF
anterior preoptic nucleus APO
anterior pretectal nucleus APT
anterior pretectal nucleus, dorsal part APTD
anterodorsal preoptic nucleus ADP
anterodorsal thalamic nucleus AD
anteromedial thalamic nucleus AM
anteromedial thalamic nucleus, ventral part
AMV
anteroventral preoptic nucleus AVPO
anteroventral thalamic nucleus AV
anteroventral thalamic nucleus, dorsomedial
part AVDM
anteroventral thalamic nucleus, ventrolateral
part AVVL
arcuate hypothalamic nucleus Arc
arcuate hypothalamic nucleus, dorsal part
ArcD
arcuate hypothalamic nucleus, lateral part
ArcL
arcuate hypothalamic nucleus, medial part
ArcM
arcuate hypothalamic nucleus, medial posterior
part ArcMP
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

asal nucleus (Meynert) B
basilar artery bas
basolateral amygdaloid nucleus BL
basolateral amygdaloid nucleus, anterior part
BLA
basolateral amygdaloid nucleus, posterior part
BLP
basomedial amygdaloid nucleus BM
basomedial amygdaloid nucleus, anterior part
BMA
basomedial amygdaloid nucleus, posterior part
BMP
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,
intermediate division BSTI
bed nucleus of the stria terminalis,
intraamygdaloid division BSTIA
bed nucleus of the stria terminalis, lateral
division BSTL
bed nucleus of the stria t erminalis, lateral
division, dorsal part BSTLD
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, posterior part BSTMP
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
bed nucleus of the stria terminalis, ventral
division BSTV
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
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
caudal tuberomammillary nucleus CTM
caudate putamen (striatum) CPu
caudoventral respiratory group CVRG
caudoventrolateral reticular nucleus CVL
cell bridges of the ventral striatum CB
central amygdaloid nucleus, medial division,
anterodorsal part CeMAD
central amygdaloid nucleus, medial division,
anteroventral part CeMAV
central amygdaloid nucleus Ce
central amygdaloid nucleus, capsular part CeC
central amygdaloid nucleus, medial division
CeM
central amygdaloid nucleus, medial
posteroventral part CeMPV
central canal CC
central gray of the pons CGPn
central gray, alpha part CGA
central gray, beta part CGB
central medial thalamic nucleus CM
central tegmental tract ctg
centrolateral thalamic nucleus CL
cerebellar commissure cbc
cerebellar lobule 6a
cerebellar lobule 6b
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
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
crus 1 of the ansiform lobule Crus1
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 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 10N
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 spinocerebellar tract dsc
dorsal tegmental nucleus DTg
dorsal tegmental nucleus, central part DTgC
dorsal tegmental nucleus, pericentral part
DTgP
dorsal transition zone DTr
dorsal tuberomammillary nucleus DTM
dorsolateral orbital cortex DLO
dorsolateral periaqueductal gray DLPAG
dorsolateral pontine nucleus DLPn
dorsomedial hypothalamic nucleus, compact
part DMC
dorsomedial hypothalamic nucleus, dorsal part
DMD
dorsomedial hypothalamic nucleus, ventral part
DMV
dorsomedial pontine nucleus DMPn
dorsomedial spinal trigeminal nucleus DMSp5
dorsomedial spinal trigeminal nucleus, ventral
part DMSp5V
dysgranular insular cortex DI
E
ectorhinal cortex Ect
ectotrigeminal nucleus E5
Edinger-Westphal nucleus EW
entorhinal cortex Ent
ependymal and subendymal layer/olfactory
ventricle E/OV
epifascicular nucleus EF
epilemniscal nucleus ELm
epimicrocellular nucleus EMi
epirubrospinal nucleus ERS
ethmoid thalamic nucleus Eth
external cuneate nucleus ECu
external medullary lamina eml
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 7N
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
forelimb area, cortex FL
fornix f
frontal association cortex FrA
G
gelatinous layer of the caudal spinal trigeminal
nucleus Ge5
gemini hypothalamic nucleus Gem
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 accessory olfactory
bulb GlA
glossopharyngeal nerve 9n
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
gustatory thalamic nucleus Gus
gustatory thalamic nucleus Gus
H
habenular commissure hbc
hilus of the dentate gyrus Hil
hippocampal fissure hf
hypoglossal nucleus 12N
I
indusium griseum IG
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 column IODMC
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
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
intergeniculate leaf IGL
intermediate acoustic stria ias
intermediate geniculate nucleus IntG
intermediate interstitial nucleus of the medial
longitudinal fasciculus II
intermediate lobe of pituitary IPit
intermediate nucleus of the lateral lemniscus
ILL
intermediodorsal thalamic nucleus IMD
intermedioventral thalamic commissure imvc
intermedius nucleus of the medulla InM
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, dorsomedial
subnucleus IPDM
interpeduncular nucleus, intermediate
subnucleus IPI
interpeduncular nucleus, lateral subnucleus
IPL
interpeduncular nucleus, rostral subnucleus
IPR
interpeduncular nucleus, rostrolateral
subnucleus IPRL
interposed cerebellar nucleus, dorsomedial
crest IntDM
interposed cerebellar nucleus, posterior part
IntP
interposed cerebellar nucleus, posterior
parvicellular part IntPPC
interstitial nucleus of Cajal InC
interstitial nucleus of Cajal, greater part InCG
interstitial nucleus of the posterior limb of the
anterior commissure, central part IPACC
interstitial nucleus of the posterior limb of t he
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
interventricular foramen IVF
intramedullary thalamic area IMA
islands of Calleja, major island ICjM
J
juxtarestiform body jx
juxtatrigeminal area Jx5
K
Kölliker-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 nucleus La
lateral amygdaloid nucleus, dorsolateral part
LaDL
lateral amygdaloid nucleus, ventrolateral part
LaVL
lateral amygdaloid nucleus, ventromedial par t
LaVM
lateral cerebellar nucleus, parvicellular part
LatPC
lateral entorhinal cortex LEnt
lateral globus pallidus LGP
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, central part LPBC
lateral parabrachial nucleus, crescent part
LPBCr
lateral parabrachial nucleus, dorsal part LPBD
lateral parabrachial nucleus, ventral part
LPBV
lateral paragigantocellular nucleus LPGi
lateral parietal association cortex LPtA
lateral posterior thalamic nucleus LP
lateral posterior thalamic nucleus, laterocaudal
part LPLC
lateral posterior thalamic nucleus, laterorostral
part LPLR
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 LS
lateral septal nucleus, dorsal part LSD
lateral septal nucleus, intermediate part LSI
lateral septal nucleus, ventral part LSV
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
linear nucleus of the medulla Li
locus coeruleus LC
longitudinal association bundle lab
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, anterior dorsal
MeAD
medial amygdaloid nucleus, anterior part MeA
medial amygdaloid nucleus, anteroventral part
MeAV
medial amygdaloid nucleus, posterodorsal part
MePD
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 geniculate nucleus MG
medial geniculate nucleus, dorsal part MGD
medial geniculate nucleus, medial part MGM
medial globus pallidus (entopeduncular
nucleus) MGP
medial habenular nucleus MHb
medial lemniscus ml
medial longitudinal fasciculus mlf
medial mammillary nucleus, lateral part ML
medial orbital cortex MO
medial parabrachial nucleus MPB
medial parabrachial nucleus external part
MPBE
medial parietal association cortex MPtA
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 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 raphe nucleus MnR
mediodorsal thalamic nucleus, central part
MDC
mediodorsal thalamic nucleus, lateral part
MDL
mediodorsal thalamic nucleus, medial part
MDM
mediodorsal thalamic nucleus, paralaminar part
MDPL
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
noradrenaline/adrenaline cells A1/C1
nucleus O O
nucleus of Darkschewitsch Dk
nucleus of origin of efferents of the vestibular
nerve EVe
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 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, 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 solotary tract, rostral central
part RCe
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
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
oriens layer of the hippocampus Or
outer blade of the dentate gyrus OBl
oval paracentral thalamic nucleus OPC
P
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
paralemniscal nucleus PL
paramedian lobule PM
paramedian raphe nucleus PMnR
paramedian reticular nucleus PMn
paramedian sulcus pms
paranigral nucleus PN
pararubral nucleus PaR
parasolitary nucleus PSol
parastrial nucleus PS
parasubiculum PaS
parasubthalamic nucleus PSTh
paratrigeminal nucleus Pa5
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
parvicellular motor trigeminal nucleus PC5
parvicellular reticular nucleus PCRt
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 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
postsubiculum Post
pre-Bötzinger complex PrBo
precentral fissure pcn
precommissural fornix pcf
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, shoulder region
S1Sh
primary somatosensory cortex, upper lip region
S1ULp
primary visual cortex V1
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
pyramidal decussation pyx
pyramidal fissure pf
pyramidal tract py
R
raphe cap RC
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
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
retroparafascicular nucleus RPF
retrorubral field RRF
retrorubral fields/A8 dopamine cells RRF/A8
retrorubral nucleus RR
retrosplenial agranular cortex RSA
retrosplenial granular a cortex RSGa
retrosplenial granular b cortex RSGb
retrosplenial granular cortex RSG
reuniens thalamic nucleus Re
rhinal fissure rf
rhinal incisura ri
rhomboid thalamic nucleus Rh
root of abducens nerve 6n
root of accessory nerve 11n
root of hypoglossal nerve 12n
rostral interstitial nucleus of medial longitudinal
fasciculus RI
rostral linear nucleus of the raphe RLi
rostral periolivary region RPO
rostroventrolateral reticular nucleus RVL
rostrum of the corpus callosum rcc
rubrospinal tract rs
S
sagulum nucleus Sag
scaphoid thalamic nucleus Sc
secondary auditory cortex, dorsal area AuD
secondary auditory cortex, ventral area AuV
secondary motor cortex M2
secondary somatosensory cortex S2
secondary visual cortex, lateral area V2L
secondary visual cortex, mediolateral area
V2ML
semilunar nucleus SL
sensory root of the trigeminal nerve s5
septofimbrial nucleus SFi
septohippocampal nucleus SHi
simple lobule Sim
simple lobule A SimA
solitary tract sol
sphenoid nucleus Sph
spinal trigeminal nucleus, caudal part Sp5C
spinal trigeminal nucleus, oral part Sp5O

spinal trigeminal nucleus, oral part,
ventrolateral division Sp5OVL
spinal trigeminal tract sp5
spinal vestibular nucleus SpVe
spinocerebellar tract sc
splenium of the corpus callosum scc
stratum lucidum, hippocampus SLu
stria terminalis st
striohypothalamic nucleus StHy
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
sublenticular extended amygdala SLEA
sublenticular extended amygdala, central part
SLEAC
sublenticular extended amygdala, medial part
SLEAM
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 SN
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 paraolivary nucleus SPO
superior salivatory nucleus SuS
superior thalamic radiation str
superior vestibular nucleus SuVe
suprachiasmatic nucleus SCh
suprachiasmatic nucleus, dorsomedial part
SChDM
suprachiasmatic nucleus, ventrolateral part
SChVL
suprageniculate thalamic nucleus SG
supragenual nucleus SGe
supramammillary decussation sumx
supramammillary nucleus SuM
supramammillary nucleus, medial part SuMM
supraoculomotor cap Su3C
supraoculomotor periaqueductal gray Su3
supraoptic decussation sox
supraoptic nucleus SO
supratrigeminal nucleus Su5
T
tectospinal tract ts
terete hypothalamic nucleus Te
trigeminal ganglion 5Gn
trigeminal ganglion 5Gn
trochlear decussation 4x
trochlear nucleus 4N
U
uncinate fasciculus unc
uvula, cerebellum Uvu
uvular fissure uf
V
vagus nerve or its root 10n
ventral anterior thalamic nucleus VA
ventral cochlear nucleus VC
ventral cochlear nucleus, anterior part VCA
ventral cochlear nucleus, posterior part VCP
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 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 tenia tecta VTT
ventral tuberomammillary nucleus VTM
ventrolateral hypothalamic nucleus VLH

ventrolateral preoptic nucleus VLPO
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 preoptic nucleus VMPO
ventromedial thalamic nucleus VM
vertebral artery vert
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, dorsal part ZID
zona incerta, ventral part ZIV
zona limitans ZL
zonal layer of the superior colliculus GI

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.
1 layer 1 10-18, 35-38, 70-74, 102
1Cb 1st Cerebellar lobule 79-80, 101
2 layer 2 10-18, 27, 35-38, 70-74
2Cb 2nd Cerebellar lobule 72-80, 101-111
2n optic nerve 30
3 layer 3 10-14, 35-38, 70-74
3Cb 3rd Cerebellar lobule 74-81, 101-117,
119
3N oculomotor nucleus 62-66, 101-103
3n oculomotor nerve or its root 58, 60-61
3PC oculomotor nucleus, parvicellular part 62-
66, 102-103
3V 3rd ventricle 27-52, 101-107
4&5Cb 4&5th Cerebellar lobules 75-87, 101-
112, 119, 121
4N trochlear nucleus 68, 102-103
4n trochlear nerve or its root 70-75, 108-
110, 112
4V 4th ventricle 74-91, 101, 103-108
6 abducens nucleus 86
6Cb 6th Cerebellar lobule 85, 87-94, 101-
114
6N abducens nucleus 77-79, 103-105
7Cb 7th Cerebellar lobule 91-98, 101-113
7DI facial nucleus, dorsal intermediate
subnucleus 81
7DL facial nucleus, dorsolateral subnucleus 81
7DM facial nucleus, dorsomedial subnucleus
81
7L facial nucleus, lateral subnucleus 81
7N facial nucleus 78-85, 107-115
7n facial nerve or its root 74-78, 106-115
7VI facial nucleus, ventral intermediate
subnucleus 81
7VM facial nucleus, ventromedial subnucleus
81
8Cb 8th Cerebellar lobule 89-102, 104-114
8n vestibulocochlear nerve 74-82, 115-121
8vn vestibular root of the vestibulocochlear
nerve 72-73, 78-80
9Cb 9th Cerebellar lobule 87-110
10 dorsal motor nucleus of vagus 87
10Cb 10th Cerebellar lobule 81-86, 88-89,
101-113
10N dorsal motor nucleus of vagus 84-99,
101-104
11N accessory nerve nucleus 100
11n root of accessory nerve 92
12 hypoglossal nucleus 91
12N hypoglossal nucleus 89-90, 92-99, 101-
103
12n root of hypoglossal nerve 91, 96-98
A
A1 A1 noradrenaline cells 93-96, 100
A1/C1 noradrenaline/adrenaline cells 9 7
A11 A11dopamine cells 47
A12 A12 dopamine cells 47-48
A13 A13 dopamine cells 40-43, 106-108
A14 A14 dopamine cells 32-34
A2 A2 noradrenaline cells 100
A5 A5 noradrenaline cells 75-81, 112, 114
A7 A7 noradrenaline cells 72, 115
A8 A8 dopamine cells 63-65
AAD anterior amygdaloid area, dorsal part 32-
38, 115-119
AAV anterior amygdaloid area, ventral part
32-36, 114-119
AC anterior commissural nucleus 33-35, 102
ac anterior commissure 101-109
aca anterior commissure, anterior part 14-32,
108-113
Acb accumbens nucleus 14, 25-26
AcbC accumbens nucleus, core 15-24, 106-
113
AcbSh accumbens nucleus, shell 15-24, 103-
112
aci anterior commissure, intrabulbar part 1-
13, 107-109, 111

ACo anterior cortical amygdaloid nucleus 33-
45, 119-124
acp anterior commissure, posterior 29-35,
110-123
Acs accessory nucleus of the ventral horn 37
Acs5 accessory trigeminal nucleus 73-75,
109
Acs6/7 accessory abducens/facial nucleus 77
Acs7 accessory facial nucleus 78-82
AD anterodorsal thalamic nucleus 34-40, 106-
109
ADP anterodorsal preoptic nucleus 28-34,
102-103
AHA anterior hypothalamic area, anterior part
34-36, 103-106
AHC anterior hypothalamic area, central part
37-38, 102-106
AHi amygdalohippocampal area 119-124
AHiAL amygdalohippocampal area, anterolateral
part 47-52
AHiPM amygdalohippocampal area,
posteromedial part 51-62, 114-118
AHP anterior hypothalamic area, posterior part
39-42, 103-106
AI agranular insular cortex 0, 10-14
AID agranular insular cortex, dorsal part 0, 15-
27, 114-132
AIP agranular insular cortex, posterior part 0,
28-40, 129-132
AIV agranular insular cortex, ventral part 0,
15-27, 114-132
AL nucleus of the ansa lenticularis 40
al ansa lenticularis 41
alv alveus of the hippocampus 40-67, 105-
123, 125-126, 128-130, 132
AM anteromedial thalamic nucleus 35-41,
104-108
Amb ambiguus nucleus 86-97, 111-112
AMV anteromedial thalamic nucleus, ventral
part 36-38, 105-106
Ang angular thalamic nucleus 43-44, 109-111
Ant anterior lobe cerebellum 71-75
AOB accessory olfactory bulb 4-6, 106-107,
109, 111-112
AOD anterior olfactory nucleus, dorsal part 4-
10, 108-111
AOE anterior olfactory nucleus, external part
3-6, 106-113
AOL anterior olfactory nucleus, lateral part 3-
10, 111-113
AOM anterior olfactory nucleus, medial part 4-
14, 104-107
AOP anterior olfactory nucleus, posterior part
11-14, 105-111
aot accessory olfactory tract 42
AOV anterior olfactory nucleus, ventral part
4-10, 105-111
AP area postrema 91-96
APir amygdalopiriform transition area 51-62,
125-132
APit anterior lobe of pituitary 107
apmf ansoparamedian fissure 85-95, 114-129
APT anterior pretectal nucleus 56-59, 107-
108, 112-115
APTD anterior pretectal nucleus, dorsal part
49-55, 109-111
APTV anterior pretectal nucleus, ventral part
53-55, 110-111
Aq aqueduct (Sylvius) 55-73, 101-102
Arc arcuate hypothalamic nucleus 41-44,
102-103
ArcD arcuate hypothalamic nucleus, dorsal part
45-48
ArcL arcuate hypothalamic nucleus, lateral part
45-48
ArcLP arcuate hypothalamic nucleus,
lateroposterior part 49-52
ArcMP arcuate hypothalamic nucleus, medial
posterior part 49-54, 101
asc7 ascending fibers of the facial nerve 105-
106
AStr amygdalostriatal transition area 39-49,
124-130
ATg anterior tegmental nucleus 65-66, 68-
69, 102-103
Au1 primary auditory cortex 0, 49-61, 131-
132
AuD secondary auditory cortex, dorsal area 0,
48-61, 129-132
AuV secondary auditory cortex, ventral area
0, 45-59, 131-132
AV anteroventral thalamic nucleus 34-35, 39-
41
AVDM anteroventral thalamic nucleus,
dorsomedial part 36-38, 107-110
AVPe anteroventral periventricular nucleus
26-31, 102
AVVL anteroventral thalamic nucleus,
ventrolateral part 36-38, 108-112
B
B basal nucleus (Meynert) 34-40, 42, 113-
121
B4 B4 serotonin cells 88-89
B9 B9 serotonin cells 64-66, 6 8
BAC bed nucleus of the anterior commissure
31-32, 105
BAOT bed nucleus of the accessory olfactory
tract 38-39, 116-117
Bar Barrington’s nucleus 75-78, 107
bas basilar artery 61
BIC nucleus of the brachium of the inferior
colliculus 62-69, 115-118
bic brachium of the inferior colliculus 59-69,
118-119
BL basolateral amygdaloid nucleus 121
BLA basolateral amygdaloid nucleus, anterior
part 36-48, 124-128
BLP basolateral amygdaloid nucleus, posterior
part 47-57, 122-130
BLV basolateral amygdaloid nucleus, ventral
part 40-49, 127-130

BMA basomedial amygdaloid nucleus, anterior
part 36-45, 119-126
BMP basomedial amygdaloid nucleus, posterior
part 43-53, 120-128
Bo Botzinger complex 86
bp brachium pontis (stem of middle cerebellar
peduncle) 62-65
bsc brachium of the superior colliculus 52-66,
105-121
BST bed nucleus of the stria terminalis 26-27
BSTIA bed nucleus of the stria terminalis,
intraamygdaloid division 42-49, 121
BSTLD bed nucleus of the stria terminalis,
lateral division, dorsal part 28-31, 107-110
BSTLI bed nucleus of the stria terminalis, lateral
division, intermediate part 31-32, 108
BSTLJ bed nucleus of the stria terminalis,
lateral division, juxtacapsular part 29-31,
110
BSTLP bed nucleus of the stria terminalis,
lateral division, posterior part 29-33, 107-
110
BSTLV bed nucleus of the stria terminalis,
lateral division, ventral part 27-31, 107-109
BSTMA bed nucleus of the stria terminalis,
medial division, anterior part 26-31, 105-
106
BSTMP bed nucleus of the stria terminalis,
medial division, posterior part 105
BSTMPI bed nucleus of the stria terminalis,
medial division, posterointermediate part 32-
34, 106-108
BSTMPL bed nucleus of the stria terminalis,
medial division, posterolateral part 33-36,
106-110
BSTMPM bed nucleus of the stria terminalis,
medial division, posteromedial part 32-34,
104-108
BSTMV bed nucleus of the stria terminalis,
medial division, ventral part 28-32, 107
BSTS bed nucleus of stria terminalis,
supracapsular part 31, 33-39
C
C1 C1 adrenaline cells 84-89, 98, 107-115
C2 C2 adrenaline cells 88-89
C3 C3 adrenaline cells 86-89
CA1 field CA1 of hippocampus 41-63, 101-
117, 119, 121-132
CA2 field CA2 of hippocampus 41-56, 104-
132
CA3 field CA3 of hippocampus 39-61, 105-
106, 108-132
CB cell bridges of the ventral striatum 23-24
Cb cerebellum 86-87
cbc cerebellar commissure 84-86
CC central canal 93-100
cc corpus callosum 25-51, 101-129
CeC central amygdaloid nucleus, capsular part
38-46, 120-125
CeCv central cervical nucleus 97-100
CeL central amygdaloid nucleus, lateral division
41-48, 122-124
CeM central amygdaloid nucleus, medial division
36-38, 41, 118-122
CeMAD central amygdaloid nucleus, medial
division, anterodorsal part 39-40
CeMAV central amygdaloid nucleus, medial
division, anteroventral part 39-40
CeMPV central amygdaloid nucleus, medial
posteroventral part 42-44
cg cingulum 18-63, 107-110
Cg/RS cingulate/retrosplenial cortex 0, 34-
38, 101-105
Cg1 cingulate cortex, area 1 0, 11-33, 101-
106
Cg2 cingulate cortex, area 2 0, 19-33, 101-
105
CGA central gray, alpha part 75-77, 101-102
CGB central gray, beta part 75
CGPn central gray of the pons 76-79, 104-
106
chp choroid plexus 102, 105-106, 118, 120,
122-123, 125
CI caudal interstitial nucleus of the medial
longitudinal fasciculus 87-90
CIC central nucleus of the inferior colliculus
72-75, 106-114
cic commissure of the inferior colliculus 71-
72, 101-105
Cir circular nucleus 37-39
CL centrolateral thalamic nucleus 40-48, 107-
109
Cl claustrum 14-40, 106-131
CLi caudal linear nucleus of the raphe 64-66,
68, 101-103
CM central medial thalamic nucleus 35-48,
101-105
CnF cuneiform nucleus 68-74, 109-114
Cop copula of the pyramis 87-98, 115-123
cp cerebral peduncle, basal part 46-65, 108-
120
CPO caudal periolivary nucleus 78
CPu caudate putamen (striatum) 15-50, 106-
131
Crus1 crus 1 of the ansiform lobule 76-91,
116-131
Crus2 crus 2 of the ansiform lobule 80-95,
115-132
csc commissure of the superior colliculus 56-
60, 101-102
cst commissural stria terminalis 7 3
Cu cuneate nucleus 91-100, 104-111
cu cuneate fasciculus 96-100, 104-108
CVL caudoventrolateral reticular nucleus 110-
113
CxA cortex-amygdala transition zone 32-42,
120-126
D
D3V dorsal 3rd ventricle 31-54, 101-102,
104-105
das dorsal acoustic stria 84
DC dorsal cochlear nucleus 78-85, 114-121

DCIC dorsal cortex of the inferior colliculus
72-76, 101-109
DEn dorsal endopiriform nucleus 10-54, 110-
132
df dorsal fornix 33-50, 101-102, 104
DG dentate gyrus 39-64, 102-103, 113, 118-
119, 121
dhc dorsal hippocampal commissure 39-71,
101-102
DI dysgranular insular cortex 15-40, 120-132
Dk nucleus of Darkschewitsch 54-61, 102-
104
DLG dorsal lateral geniculate nucleus 45-55,
118-122
DLL dorsal nucleus of the lateral lemniscus
69-72, 116-118
DLO dorsolateral orbital cortex 0, 6-9
dlo dorsal lateral olfactory tract 3-5, 108,
110, 112-113
DLPAG dorsolateral periaqueductal gray 59-
72, 104-107
DM dorsomedial hypothalamic nucleus 42-45,
48-49, 102-106
DMC dorsomedial hypothalamic nucleus,
compact part 46-48
DMD dorsomedial hypothalamic nucleus, dorsal
part 46-47
DMPAG dorsomedial periaqueductal gray 59-
74, 101-103
DMPn dorsomedial pontine nucleus 66, 6 8
DMSp5 dorsomedial spinal trigeminal nucleus
82-91, 113-115
DMTg dorsomedial tegmental area 72-76,
103-107
DMV dorsomedial hypothalamic nucleus, ventral
part 46-47
DP dorsal peduncular cortex 0, 13-23, 102-
106
DpG deep gray layer of the superior colliculus
56-71, 103-113
DPGi dorsal paragigantocellular nucleus 81-89,
101-104
DpMe deep mesencephalic nucleus 55-67,
105, 107-115
DPO dorsal periolivary region 73-77, 107-113
DpWh deep white layer of the superior
colliculus 56-71, 103-111
DR dorsal raphe nucleus 64-66, 102
DRC dorsal raphe nucleus, caudal part 72-74
DRD dorsal raphe nucleus, dorsal part 68-71,
101
DRI dorsal raphe nucleus, interfascicular part
68-75, 101
DRV dorsal raphe nucleus, ventral part 68-71,
101, 103-105
DRVL dorsal raphe nucleus, ventrolateral part
68-71, 103
Dsc lamina dissecans of the entorhinal cortex
69, 126-132
dsc dorsal spinocerebellar tract 97, 99-100
DT dorsal terminal nucleus of the accessory
optic tract 58-61, 116
dtg dorsal tegmental bundle 102
DTgC dorsal tegmental nucleus, central part
74-77, 101-103
DTgP dorsal tegmental nucleus, pericentral part
73-77, 101-103
dtgx dorsal tegmental decussation 63, 101
DTM dorsal tuberomammillary nucleus 49-52,
102
DTr dorsal transition zone 103
DTT dorsal tenia tecta 9-20, 101-107
E
E ependyma and subependymal layer 108
E/OV ependymal and subendymal
layer/olfactory ventricle 1-11, 106, 108
ec external capsule 18-67, 127-128, 130
ECIC external cortex of the inferior colliculus
65-66, 68-75, 106-117
Ect ectorhinal cortex 0, 42-74, 129-132
ECu external cuneate nucleus 87-95, 112
EF epifascicular nucleus 88
EMi epimicrocellular nucleus 66, 68-70
eml external medullary lamina 45-50, 114
Ent entorhinal cortex 128
EPl external plexiform layer of the olfactory
bulb 1-9, 101-115
EPlA external plexiform layer of the accessory
olfactory bulb 3, 5, 108
ERS epirubrospinal nucleus 114
Eth ethmoid thalamic nucleus 52-54, 110-
113
EVe nucleus of origin of efferents of the
vestibular nerve 78-79
EW Edinger-Westphal nucleus 54-64, 101
exc extreme capsule 29-32
F
F nucleus of the fields of Forel 51-53, 108-
110
f fornix 30-56, 101-108
FC fasciola cinereum 45-54
FF fields of Forel 50, 107
fi fimbria of the hippocampus 34-52, 106-
120, 122-126
Fl flocculus 73-82, 122-127
fmi forceps minor of the corpus callosum 14-
20, 109-124
fmj forceps major of the corpus callosum 53-
56, 108-124
fr fasciculus retroflexus 42-57, 103-105
FrA frontal association cortex 0, 4-9, 104-
116
Fu bed nucleus of stria terminalis, fusiform part
29-30, 107-109
FVe F cell group of the vestibular complex 87-
89
G

g7 genu of the facial nerve 79-80, 104-105
gcc genu of the corpus callosum 21-24, 101-
106
Ge5 gelatinous layer of the caudal spinal
trigeminal nucleus 111, 113, 115
Gem gemini hypothalamic nucleus 49-51, 107
GI granular insular cortex 18-40, 121-132
Gi gigantocellular reticular nucleus 78-91,
101-108
GiA gigantocellular reticular nucleus, alpha part
76-85, 101-106
GiV gigantocellular reticular nucleus, ventral
part 86-89, 101-106
Gl glomerular layer of the olfactory bulb 1-8,
101-116
GlA glomerular layer of the accessory olfactory
bulb 3, 5, 108, 110
Gr gracile nucleus 95-103
gr gracile fasciculus 97, 101-102
GrA granule cell layer of the accessory
olfactory bulb 2-3, 108-110
GrC granular layer of the cochlear nuclei 78-
83
GrDG granular layer of the dentate gyrus 39-
64, 104, 106-113, 115-124
GrO granular cell layer of the olfactory bulb 1-
9, 102-113
Gus gustatory thalamic nucleus 47-50, 102-
110
H
hbc habenular commissure 46-50
HDB nucleus of the horizontal limb of the
diagonal band 24-35, 104-111
hf hippocampal fissure 42-63, 103-110, 112-
128
I
I intercalated nuclei of the amygdala 28-38,
40, 42-47, 120-124
I3 interoculomotor nucleus 64
I5 intertrigeminal nucleus 73-75, 115
IAD interanterodorsal thalamic nucleus 36-39,
104-106
IAM interanteromedial thalamic nucleus 37-
41, 101-103
ias intermediate acoustic stria 83
ic internal capsule 29-49, 110-127
icf intercrural fissure 80-91, 114-131
ICj islands of Calleja 15-21, 23, 25, 27, 101-
102, 108, 110, 120
ICjM islands of Calleja, major island 19-24,
104-106
icp inferior cerebellar peduncle (restiform body)
78-94, 115-116, 118-119
IF interfascicular nucleus 56-62, 101-102
IG indusium griseum 21-51, 101-103
IGL intergeniculate leaf 49-55, 120-121
IL infralimbic cortex 14-20, 103-105
ILL intermediate nucleus of the lateral
lemniscus 68-71, 116-118
IM intercalated amygdaloid nucleus, main part
38-39
IMA intramedullary thalamic area 48-54
IMD intermediodorsal thalamic nucleus 41-48,
101
In intercalated nucleus of the medulla 89-93,
101-102
InC interstitial nucleus of Cajal 55-62, 103-
106
InCG interstitial nucleus of Cajal, greater part
55-59
InCo intercollicular nucleus 65-70, 109-114
Inf infracerebellar nucleus 81
InG intermediate gray layer of the superior
colliculus 56-71, 103-115
InM intermedius nucleus of the medulla 94-95
IntA interposed cerebellar nucleus, anterior part
79-84, 109-116
IntDL interposed cerebellar nucleus,
dorsolateral hump 81-85
IntG intermediate geniculate nucleus 54
IntP interposed cerebellar nucleus, posterior
part 83-87, 108-116
InWh intermediate white layer of the superior
colliculus 56-71, 103-116
IO inferior olive 101-102, 105-108
IOA inferior olive, subnucleus A of medial
nucleus 94-97
IOB inferior olive, subnucleus B of medial
nucleus 92-97
IOBe inferior olive, beta subnucleus 91-96
IOC inferior olive, subnucleus C of medial
nucleus 92-97
IOD inferior olive, dorsal nucleus 87-95, 103-
104
IODM inferior olive, dorsomedial cell group 88-
90
IODMC inferior olive, dorsomedial cell column
89
IOK inferior olive, cap of Kooy of the medial
nucleus 91-96
IOM inferior olive, medial nucleus 87-91, 9 8
IOPr inferior olive, principal nucleus 87-93,
103-104
IOVL inferior olive, ventrolateral protrusion
91-92
IP interpeduncular nucleus 65-66
IPA interpeduncular nucleus, apical subnucleus
64, 101-102
IPAC interstitial nucleus of the posterior limb of
the anterior commissure 37-43, 110-121
IPACL interstitial nucleus of the posterior limb
of the anterior commissure, lateral part 27-
36
IPACM interstitial nucleus of the posterior limb
of the anterior commissure, medial part 27-
36
IPC interpeduncular nucleus, caudal subnucleus
59-64, 101-102

IPDL interpeduncular nucleus, dorsolateral
subnucleus 59-64
IPDM interpeduncular nucleus, dorsomedial
subnucleus 59-64
IPF interpeduncular fossa 56-59, 101-106
IPI interpeduncular nucleus, intermediate
subnucleus 59-64
IPL interpeduncular nucleus, lateral subnucleus
59-64, 103-104
IPl internal plexiform layer of the olfactory bulb
1-9, 101-113
IPR interpeduncular nucleus, rostral subnucleus
58-64, 101-102
IRt intermediate reticular nucleus 76-100,
104-113
IS inferior salivatory nucleus 79-82
IVF interventricular foramen 107
K
KF Ko¨lliker-Fuse nucleus 71-75, 115-116
L
LA lateroanterior hypothalamic nucleus 34-
38, 103-106
La lateral amygdaloid nucleus 37-40, 50,
128-131
LAcbSh lateral accumbens shell 20-21, 23-
25, 113-118
LaDL lateral amygdaloid nucleus, dorsolateral
part 41-51
Lat lateral (dentate) cerebellar nucleus 78-
84, 117-123
LatPC lateral cerebellar nucleus, parvicellular
part 81-83, 113-121
LaVL lateral amygdaloid nucleus, ventrolateral
part 43-49
LaVM lateral amygdaloid nucleus, ventromedial
part 46-51, 127
LC locus coeruleus 75-79, 108-109
LD laterodorsal thalamic nucleus 111
Ld lambdoid septal zone 24-28, 101
LDDM laterodorsal thalamic nucleus,
dorsomedial part 39-45, 108-110
LDTg laterodorsal tegmental nucleus 72-77,
102-107
LDTgV laterodorsal tegmental nucleus, ventral
part 71-73, 107
LDVL laterodorsal thalamic nucleus,
ventrolateral part 38-45, 112-118
LEnt lateral entorhinal cortex 0, 49-73, 125-
132
lfp longitudinal fasciculus of the pons 66-72,
74, 103-109
LGP lateral globus pallidus 31-45, 112-125
LH lateral hypothalamic area 34-54, 107-113
LHb lateral habenular nucleus 39-45, 48-49,
106
LHbL lateral habenular nucleus, lateral part
46-47
LHbM lateral habenular nucleus, medial part
46-47, 103-105
Li linear nucleus of the medulla 88-90, 108
ll lateral lemniscus 65-66, 68-73, 108-118
LM lateral mammillary nucleus 53-56, 107-
110
LMol lacunosum moleculare layer of the
hippocampus 42-64, 104-130
LO lateral orbital cortex 0, 4-15, 17, 112-120
lo lateral olfactory tract 1-30, 40, 109-124
LOT nucleus of the lateral olfactory tract 33-
38, 115-119
LPAG lateral periaqueductal gray 59-74, 104-
108
LPB lateral parabrachial nucleus 72, 109-112
LPBC lateral parabrachial nucleus, central part
73-77
LPBD lateral parabrachial nucleus, dorsal part
74-76, 114
LPBE lateral parabrachial nucleus, external part
73-75, 113-115
LPBI lateral parabrachial nucleus, internal part
75
LPBS lateral parabrachial nucleus, superior part
73
LPBV lateral parabrachial nucleus, ventral part
73-75, 77-78
LPGi lateral paragigantocellular nucleus 78-90,
104-113
LPLC lateral posterior thalamic nucleus,
laterocaudal part 54-55, 116-117
LPLR lateral posterior thalamic nucleus,
laterorostral part 46-53, 113-117
LPMC lateral posterior thalamic nucleus,
mediocaudal part 51-56, 115
LPMR lateral posterior thalamic nucleus,
mediorostral part 43-53, 107-114
LPO lateral preoptic area 26-33, 105-109
LPtA lateral parietal association cortex 43-48,
110-113
LR4V lateral recess of the 4th ventricle 78-
90, 109-117
LRt lateral reticular nucleus 90-100, 108-114
LRtPC lateral reticular nucleus, parvicellular part
90-92, 97-98, 114-11 6
LS lateral septal nucleus 106
LSD lateral septal nucleus, dorsal part 19-35,
102-106
LSI lateral septal nucleus, intermediate part
18-32, 101-105
LSO lateral superior olive 73-77, 110-113
LSS lateral stripe of the striatum 19-29, 114,
117-123
LSV lateral septal nucleus, ventral part 21-32,
105
LT lateral terminal nucleus of the accessory
optic tract 52-55
LV lateral ventricle 15-55, 101, 103, 106-
132
LVe lateral vestibular nucleus 78-83, 111-
115
LVPO lateroventral periolivary nucleus 70-78,
110-113

M
M1 primary motor cortex 0, 11-42, 107-123
M2 secondary motor cortex 0, 10-26, 28-42,
103-120
m5 motor root of the trigeminal nerve 66,
68-73, 114-117
MA3 medial accessory oculomotor nucleus
56-61, 102-103
maopt medial accessory optic tract 36-38
MCLH magnocellular nucleus of the lateral
hypothalamus 44-47, 111-113
mcp middle cerebellar peduncle 66-80, 112-
120
MCPC magnocellular nucleus of the posterior
commissure 53-55, 104-106
MCPO magnocellular preoptic nucleus 27-38,
112-119
MD mediodorsal thalamic nucleus 36-39, 48,
104
MDC mediodorsal thalamic nucleus, central part
40-47, 104-105
MdD medullary reticular nucleus, dorsal part
92-100, 109-112
MDL mediodorsal thalamic nucleus, lateral part
40-47, 105-108
MDM mediodorsal thalamic nucleus, medial part
40-47, 102-103
MdV medullary reticular nucleus, ventral part
92-100, 104-110
ME median eminence 44-49, 101
Me medial amygdaloid nucleus 50
Me5 mesencephalic trigeminal nucleus 65-66,
68-78, 107-110
me5 mesencephalic trigeminal tract 73-77,
109-111
MeA medial amygdaloid nucleus, anterior part
40-41, 115
MeAD medial amygdaloid nucleus, anterior
dorsal 37-39, 116-118
MeAV medial amygdaloid nucleus, anteroventral
part 39, 116, 118
Med medial (fastigial) cerebellar nucleus 80-
88, 104-107, 110-111
MedDL medial cerebellar nucleus, dorsolateral
protuberance 84-88, 108-113
MEnt medial entorhinal cortex 0, 64-66, 68-
74, 122-132
MePD medial amygdaloid nucleus, posterodorsal
part 42-50, 116-120
MePV medial amygdaloid nucleus,
posteroventral part 42-49, 115-118
mfb medial forebrain bundle 15-44, 109-111,
114-116
mfba medial forebrain bundle, ‘a’ component
108
MG medial geniculate nucleus 63-64, 121
MGD medial geniculate nucleus, dorsal part
54-59, 117-120
MGM medial geniculate nucleus, medial part
54-59, 116
MGP medial globus pallidus (entopeduncular
nucleus) 40-44, 114-119
MGV medial geniculate nucleus, ventral part
54-61, 117-120
MHb medial habenular nucleus 38-49, 102-
104
Mi mitral cell layer of the olfactory bulb 1-9,
101-113
MiA mitral cell layer of the accessory olfactory
bulb 3, 5, 108, 110
Min minimus nucleus 61
MiTg microcellular tegmental nucleus 65-66,
68-72, 111-118
ML medial mammillary nucleus, lateral part 53-
57, 103-106
ml medial lemniscus 45-86, 101-113
mlf medial longitudinal fasciculus 59-92, 96-
104
MM medial mammillary nucleus, medial part
53-59, 101-105
MMn medial mammillary nucleus, median part
53-55, 101
MnA median accessory nucleus of the medulla
100
MnPO median preoptic nucleus 26-30, 101-
102
MnR median raphe nucleus 64-73, 101
MO medial orbital cortex 0, 4-14, 101-105
Mo5 motor trigeminal nucleus 71-75, 109-
113
Mol molecular layer of the dentate gyrus 39-
65, 104-123, 125-129
mp mammillary peduncle 55-58
MPA medial preoptic area 25-36, 102-107
MPB medial parabrachial nucleus 72-78, 107-
112
MPBE medial parabrachial nucleus external part
75-76, 113
MPOC medial preoptic nucleus, central part
30-32
MPOL medial preoptic nucleus, lateral part 32-
35
MPOM medial preoptic nucleus, medial part
30-35, 102-104
MPT medial pretectal nucleus 53-54, 103-104
MPtA medial parietal association cortex 0, 43-
48, 108-110
MRe mammillary recess of the 3rd ventricle
53-54
MS medial septal nucleus 21-29, 101-103
MSO medial superior olive 75
MT medial terminal nucleus of the accessory
optic tract 56-59, 108-109
mt mammillothalamic tract 39-52, 105-106
mtg mammillotegmental tract 52-67, 103-
104
MTu medial tuberal nucleus 46-48, 105-110
MVe medial vestibular nucleus 77, 87-90,
113-115
MVeMC medial vestibular nucleus, magnocellular
part 78-86, 103-113
MVePC medial vestibular nucleus, parvicellular
part 78-86, 103-112

MVPO medioventral periolivary nucleus 70-78,
106-109
MZMG marginal zone of the medial geniculate
55-62
N
ns nigrostriatal bundle 40-54, 107, 109, 111,
113
O
O nucleus O 76-77
ocb olivocochlear bundle 76-78, 101, 116,
119
ON olfactory nerve layer 1-3, 109-113
Op optic nerve layer of the superior colliculus
56-71, 101, 103-114, 116
OPC oval paracentral thalamic nucleus 45-49,
107-109
OPT olivary pretectal nucleus 51-54, 105-111
opt optic tract 34-55, 110-124
Or oriens layer of the hippocampus 39-62,
106-110, 112-130, 132
OT nucleus of the optic tract 53-56, 108-115
OV olfactory ventricle (olfactory part of lateral
ventricle) 12-14
ox optic chiasm 31-33, 101-109
P
P5 peritrigeminal zone 70-75, 111-112
P7 perifacial zone 78-85, 107-114
Pa4 paratrochlear nucleus 68-70, 103-106
Pa5 paratrigeminal nucleus 90-93, 97, 117
Pa6 paraabducens nucleus 77-79, 104-105
PaAP paraventricular hypothalamic nucleus,
anterior parvicellular part 36, 101-103
PaDC paraventricular hypothalamic nucleus,
dorsal cap 37-39, 102-103
PAG periaqueductal gray 52-58, 101
PaLM paraventricular hypothalamic nucleus,
lateral magnocellular part 36-39, 102-104
PaMM paraventricular hypothalamic nucleus,
medial magnocellular part 37-39, 102-103
PaMP paraventricular hypothalamic nucleus,
medial parvicellular part 37-41, 101
PaPo paraventricular hypothalamic nucleus,
posterior part 40-41, 102-106
PaR pararubral nucleus 108-111
PaS parasubiculum 65-73, 121-124
PaV paraventricular hypothalamic nucleus,
ventral part 36-37, 101-102
PBG parabigeminal nucleus 65-66, 68-69, 118
PBP parabrachial pigmented nucleus 55-63,
104, 108-112
PBW parabrachial nucleus, waist part 76
PC paracentral thalamic nucleus 35-48, 105-
108
pc posterior commissure 50-58, 101-104
PC5 parvicellular motor trigeminal nucleus 69-
73, 114-115
PCGS paracochlear glial substance 76, 82,
117
pcn precentral fissure 76-80, 101-109
PCom nucleus of the posterior commissure
53-55, 104-105
PCRt parvicellular reticular nucleus 86-91,
109-115
PCRtA parvicellular reticular nucleus, alpha part
75-85, 109-115
pcuf preculminate fissure 76-81, 101-113
PDTg posterodorsal tegmental nucleus 78-79,
101-102
Pe periventricular hypothalamic nucleus 29-47
PeF perifornical nucleus 45-48, 107-108
PF parafascicular thalamic nucleus 48-52,
103-108
PFl paraflocculus 74-87, 125-132
pfs parafloccular sulcus 75-87
PH posterior hypothalamic area 46-53, 101-
106
Pi pineal gland 63
PIL posterior intralaminar thalamic nucleus 54-
59, 114-118
Pir piriform cortex 0, 10-54, 106-132
PL paralemniscal nucleus 65-66, 68-71, 114
PLCo posterolateral cortical amygdaloid nucleus
(C2) 41-52, 119-130
plf posterolateral fissure 75-82, 86-89, 101-
110
PLi posterior limitans thalamic nucleus 54-58
PM paramedian lobule 85-98, 115-128
pm principal mammillary tract 53-57
PMCo posteromedial cortical amygdaloid
nucleus (C3) 46-62, 116-129
PMD premammillary nucleus, dorsal part 51-
53, 102-106
PMn paramedian reticular nucleus 90-96, 102-
103
PMnR paramedian raphe nucleus 64-73, 102-
104
PMV premammillary nucleus, ventral part 50-
52, 103-107
PN paranigral nucleus 59-62, 103-104
Pn pontine nuclei 62-69, 101-111
PnC pontine reticular nucleus, caudal part 73-
78, 101-108
PnO pontine reticular nucleus, oral part 64-72,
104-111
PnR pontine raphe nucleus 74-75
PnV pontine reticular nucleus, ventral part 73-
75, 101-103
Po posterior thalamic nuclear group 42-53,
109-118
PoDG polymorph layer of the dentate gyrus
40-64, 104-106, 108, 110-112, 114-118,
120-126
PoMn posteromedian thalamic nucleus 47-48
Post postsubiculum 111-121
PoT posterior thalamic nuclear group, triangular
part 54-59, 113-114

PP peripeduncular nucleus 53-61, 115-120
ppf prepyramidal fissure 84-98, 101-118,
120-124
PPT posterior pretectal nucleus 52-57, 105-
114
PPTg pedunculopontine tegmental nucleus
65-66, 68-72, 109-114
PPy parapyramidal nucleus 78-85
PR prerubral field 50-54, 106
Pr prepositus nucleus 80-89, 101-102
Pr5 principal sensory trigeminal nucleus 71-
72, 119
Pr5DM principal sensory trigeminal nucleus,
dorsomedial part 73-78, 115-118
Pr5VL principal sensory trigeminal nucleus,
ventrolateral part 73-78, 114-118
prb Probst’s bundle 80
PrC precommissural nucleus 49-51, 102-105
prf primary fissure 75-87, 101-123
PRh perirhinal cortex 0, 42-71, 127-132
PrL prelimbic cortex 0, 5-18, 101-106
PrS presubiculum 59-69, 123-126
PS parastrial nucleus 28-30, 105-106
psf posterior superior fissure 76-89, 94, 102-
125
PSol parasolitary nucleus 91-93, 106
PSTh parasubthalamic nucleus 48-52, 108-
111
PT paratenial thalamic nucleus 34-38, 101-
104
PtA parietal association cortex 114-117
PV paraventricular thalamic nucleus 39-48,
101-103
pv periventricular fiber system 49-50, 101
PVA paraventricular thalamic nucleus, anterior
part 33-38, 101-103
PVG periventricular gray 102
PVP paraventricular thalamic nucleus, posterior
part 49-50, 102
Py pyramidal cell layer of the hippocampus
39-62, 104, 106-110, 112-128, 130, 132
py pyramidal tract 75-97, 101-106
pyx pyramidal decussation 98-102
R
R red nucleus 65, 103, 107
Rad stratum radiatum of the hippocampus 40-
62, 104-128, 130-132
RAmb retroambiguus nucleus 98-99
Rbd rhabdoid nucleus 68, 71, 101
RC raphe cap 68-73
RCh retrochiasmatic area 39
Re reuniens thalamic nucleus 35-46, 101-105
ReIC recess of the inferior colliculus 101-102
REth retroethmoid nucleus 53-55, 112-113
rf rhinal fissure 6-73, 101-104, 107-130
Rh rhomboid thalamic nucleus 39-46, 101-
104
RI rostral interstitial nucleus of medial
longitudinal fasciculus 51-54, 103-106
RLi rostral linear nucleus of the raphe 56-63,
101-102
RMC red nucleus, magnocellular part 59-64,
104-106, 108-110
RMg raphe magnus nucleus 71-85, 101-103
Ro nucleus of Roller 89-95, 102-103
ROb raphe obscurus nucleus 83-99
RPa raphe pallidus nucleus 75-96, 101
RPC red nucleus, parvicellular part 55-59,
104-106, 110
RPF retroparafascicular nucleus 52-55, 105-
106
RPO rostral periolivary region 68-72, 106-114
RR retrorubral nucleus 66-67, 115-117
RRF retrorubral field 62-65, 109-111
RRF/A8 retrorubral fields/A8 dopamine cells
105-108, 112
rs rubrospinal tract 62-100, 112-114, 116
RSA retrosplenial agranular cortex 0, 39-72,
101-107, 109-126
RSG retrosplenial granular cortex 0, 39-66,
108-117
RSGa retrosplenial granular a cortex 103-107
RSGb retrosplenial granular b cortex 101-104,
107
Rt reticular thalamic nucleus 35-49, 106-121
RtTg reticulotegmental nucleus of the pons
65-66, 68-75, 101-107
RtTgP reticulotegmental nucleus of the pons,
pericentral part 66, 68-70, 102, 104-107
RVL rostroventrolateral reticular nucleus 84-
91, 114-115
S
S subiculum 51-67, 104-132
S1 primary somatosensory cortex 14-20, 27,
48-50, 115-123, 125-132
S1BF primary somatosensory cortex, barrel
field 0, 28-47, 118-132
S1DZ primary somatosensory cortex,
dysgranular region 28-37, 39-42, 120, 122
S1FL primary somatosensory cortex, forelimb
region 0, 23-34, 36-37, 116-122
S1HL primary somatosensory cortex, hindlimb
region 0, 26-41, 111-117
S1J primary somatosensory cortex, jaw region
0, 16-23, 121-130
S1Sh primary somatosensory cortex, shoulder
region 40-41, 115-119
S1ShNc primary somatosensory cortex,
shoulder/neck region 0, 35, 38-39, 115-
119
S1Tr primary somatosensory cortex, trunk
region 0, 42-46, 110-119
S1ULp primary somatosensory cortex, upper lip
region 0, 21-26, 121-131
S2 secondary somatosensory cortex 0, 23-
46, 124, 129-132
s5 sensory root of the trigeminal nerve 71-75
Sag sagulum nucleus 70-73, 115
SC superior colliculus 55, 101-102, 117
Sc scaphoid thalamic nucleus 52

scc splenium of the corpus callosum 52, 102-
104, 106
SCh suprachiasmatic nucleus 33-34, 37-38,
102
SChDM suprachiasmatic nucleus, dorsomedial
part 35-36
SChVL suprachiasmatic nucleus, ventrolateral
part 35-36
SCO subcommissural organ 50, 52-54, 101-
102
SCom subcommissural nucleus 54, 105
scp superior cerebellar peduncle (brachium
conjunctivum) 47-65, 71-79, 102-112
sf secondary fissure 91-110
SFi septofimbrial nucleus 29-36, 104
SFO subfornical organ 32-38, 101-102
SG suprageniculate thalamic nucleus 54-59,
116-117
SGl superficial glial zone of the cochlear nuclei
75-77, 79-85
SHi septohippocampal nucleus 15-26, 101-
102
SHy septohypothalamic nucleus 27, 104-105
SI substantia innominata 27-38, 41-42, 109-
119
SID substantia innominata, dorsal part 117
Sim simple lobule 73-84, 115-126
SL semilunar nucleus 15-18
SLEA sublenticular extended amygdala 31-33
SLEAC sublenticular extended amygdala,
central part 34-39
SLEAM sublenticular extended amygdala, medial
part 34-38
SLu stratum lucidum, hippocampus 40-59,
106-113, 116-124
SM nucleus of the stria medullaris 35, 110
sm stria medullaris of the thalamus 33-43,
104-108
SMT submammillothalamic nucleus 49-52
SMV superior medullary velum 76-80, 101-
102, 106
SNC substantia nigra, compact part 52-63,
106-116
SNL substantia nigra, lateral part 54-62, 116-
118
SNR substantia nigra, reticular part 51-64,
108-118
SO supraoptic nucleus 36-39, 108-114
Sol nucleus of the solitary tract 108-111,
113
sol solitary tract 83-100, 104-108
SolC nucleus of the solitary tract, commissural
part 93-103
SolCe nucleus of the solitary tract, central part
89-93
SolDL solitary nucleus, dorsolateral part 90-
97
SolDM nucleus of the solitary tract, dorsomedial
part 85-89
SolG nucleus of the solitary tract, gelatinous
part 90-95, 102
SolI nucleus of the solitary tract, interstitial
part 83-87, 89-91, 94-96
SolIM nucleus of the solitary tract, intermediate
part 83-95, 104-107
SolM nucleus of the solitary tract, medial part
85-100, 102-107
SolV solitary nucleus, ventral part 86-92, 94-
99, 105-106
SolVL nucleus of the solitary tract,
ventrolateral part 86-99, 107
SOR supraoptic nucleus, retrochiasmatic part
42-43
sox supraoptic decussation 36-50, 101-121
sp5 spinal trigeminal tract 76-100, 108-120
Sp5C spinal trigeminal nucleus, caudal part
94-100, 108-118
Sp5I spinal trigeminal nucleus, interpolar part
85-95, 110-119
Sp5O spinal trigeminal nucleus, oral part 78,
84, 116-118
Sp5ODM spinal trigeminal nucleus, oral part,
dorsomedial division 79-81
Sp5OVL spinal trigeminal nucleus, oral part,
ventrolateral division 79-83
SPa subparaventricular zone of the
hypothalamus 37-39
SPF subparafascicular thalamic nucleus 48-50,
103-105
SPFPC subparafascicular thalamic nucleus,
parvicellular part 51-55, 106-112
Sph sphenoid nucleus 76-77, 101-102
SPO superior paraolivary nucleus 73-77, 106-
109
SPTg subpedencular tegmental nucleus 69-
71, 104-108
SpVe spinal vestibular nucleus 82-90, 107-
115
st stria terminalis 31-49, 108-125
StA strial part of the preoptic area 30, 104-
106
Stg stigmoid hypothalamic nucleus 41
STh subthalamic nucleus 45-50, 112-117
StHy striohypothalamic nucleus 105-106
str superior thalamic radiation 51-53, 116-
120
Su3 supraoculomotor periaqueductal gray 62-
66, 103-104
Su3C supraoculomotor cap 61-66, 104-105
Su5 supratrigeminal nucleus 72-75, 110-114
Sub submedius thalamic nucleus 39-46, 103-
104
SubB subbrachial nucleus 60-64, 116-119
SubCD subcoeruleus nucleus, dorsal part 72-
75, 109-112
SubCV subcoeruleus nucleus, ventral part 72-
75, 109-112
SubD submedius thalamic nucleus, dorsal part
108
SubG subgeniculate nucleus 50-55, 118-122
SubI subincertal nucleus 42-45, 109-111
SubV submedius thalamic nucleus, ventral part
108
SuG superficial gray layer of the superior
colliculus 56-71, 101-113

SuM supramammillary nucleus 55-57, 103-
106
SuML supramammillary nucleus, lateral part
53-54, 107-109
SuMM supramammillary nucleus, medial part
51-54, 101-102
sumx supramammillary decussation 53-55,
101-102
SuVe superior vestibular nucleus 78-81, 114-
115
T
TC tuber cinereum area 40-41, 102-103
Te terete hypothalamic nucleus 46-50, 110
TeA temporal association cortex 0, 46-71,
129-132
tfp transverse fibers of the pons 66, 68-69,
101-111
TS triangular septal nucleus 32-37, 102-104
ts tectospinal tract 64-73, 96-100, 105
Tu olfactory tubercle 13-31, 103-121
Tz nucleus of the trapezoid body 71-78, 102-
108
tz trapezoid body 75-83, 101-107, 111-120
U
unc uncinate fasciculus 76-78
V
V1 primary visual cortex 0, 49-74, 114-129
V2L secondary visual cortex, lateral area 0,
47-72, 118-132
V2ML secondary visual cortex, mediolateral
area 0, 50-65, 108-117
V2MM secondary visual cortex, mediomedial
area 0, 49-72, 106-117
VA ventral anterior thalamic nucleus 36-39,
108-110
VCA ventral cochlear nucleus, anterior part
72-77, 119-121, 123
VCP ventral cochlear nucleus, posterior part
78-84, 119-121
VDB nucleus of the vertical limb of the diagonal
band 19-25, 101-103
VeCb vestibulocerebellar nucleus 80-83, 108-
111
VEn ventral endopiriform nucleus 31-51, 120-
132
vert vertebral artery 96-98
vhc ventral hippocampal commissure 33-38,
101-105
VL ventrolateral thalamic nucleus 39-45, 105-
113
VLG ventral lateral geniculate nucleus 45-47,
120-123
VLGMC ventral lateral geniculate nucleus,
magnocellular part 48-55
VLGPC ventral lateral geniculate nucleus,
parvicellular part 48-55
VLH ventrolateral hypothalamic nucleus 108
VLL ventral nucleus of the lateral lemniscus
65-66, 68, 112-118
VLPAG ventrolateral periaqueductal gray 65-
74, 104-107
VLPO ventrolateral preoptic nucleus 30-32,
105-107
VLTg ventrolateral tegmental area 68-69,
108-109
VM ventromedial thalamic nucleus 39-49,
104-110
VMH ventromedial hypothalamic nucleus 40-
41, 48, 103-105, 107
VMHC ventromedial hypothalamic nucleus,
central part 42-47, 106
VMHDM ventromedial hypothalamic nucleus,
dorsomedial part 42-47, 102
VMHVL ventromedial hypothalamic nucleus,
ventrolateral part 42-47, 106, 108
VMPO ventromedial preoptic nucleus 27-32,
102
vn vomeronasal nerve 3
VO ventral orbital cortex 0, 4-14, 105-111
VOLT vascular organ of the lamina terminalis
26-28, 101
VP ventral pallidum 15-34, 104-118
VPL ventral posterolateral thalamic nucleus
38-50, 111-120
VPM ventral posteromedial thalamic nucleus
40-52, 106-118
VRe ventral reuniens thalamic nucleus 40-46,
103-104
vsc ventral spinocerebellar tract 68-100,
109-117
VTA ventral tegmental area 55-63, 103-109
VTg ventral tegmental nucleus 70-73, 102-
103
vtgx ventral tegmental decussation 58-63,
101-103
VTM ventral tuberomammillary nucleus 49-55,
110
VTRZ visual tegmental relay zone 56-58
VTT ventral tenia tecta 9-14, 102-106
X - Z
X nucleus X 82-88, 113-114, 116-117
Xi xiphoid thalamic nucleus 36-45
xscp decussation of the superior cerebellar
peduncle 66-70, 101
Y nucleus Y 81, 115-118
ZI zona incerta 38-42, 55-56, 105-111, 120
ZID zona incerta, dorsal part 43-54, 112-116
ZIV zona incerta, ventral part 43-54, 112-119
ZL zona limitans 25-29
Zo zonal layer of the superior colliculus 56-71,
101-111, 114

4
3
2
1
0
1
2
3
4
corpus callosum
Barrel Field
Lateral Ventricle
Hippocampus
Internal
Capsule
intern
caps
VPL
Mediodorsal nu
Thalamus
VPM
Caudate
Putamen
(Striatum)
Piriform Cx
optic tract
fornix
Hypothalamus
Amygdala
VMH
4 3 2 1 0 1 2 3 4
Click on Coronal diagram to go the corresponding sagittal diagram

5 4 3 2 1 0 -1 -2 -3 -4 -5 -6 -7 -8
Cerebral Cortex
Bregma
corpus callosum
Hippocampus
Lambda
Superior
Colliculus
Inferior
Colliculus
Cerebellum
Bregma
Olfactory
Bulb
LV
Hippoc
Septum
posterior com
Thalamus
Midbrain
4V
anterior
commissure
fornix
Interaural
Lateral 0.24 mm
Preoptic
Area
Hypothalamus
Interaural
9 8 7 6
5
4
3
2
1
0 -1 -2 -3 -4
Pons
Medulla
Spinal
Cord
Click on sagittal diagram to go the corresponding coronal diagram

3 2 1 0 1 2 3
5
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 01
1
0
6
8 6 4 2 0 - 2 - 4
aci
4
IPl
EPl
Mi
Gl
E/OV
2
3
ON
lo
3
GrO
ON
2
4
1
Interaural 8.08 mm
Bregma 4.28 mm
0 5
3
2
1
0 1 2 3

3 2 1 0 1 2 3
4 2 0 -2 - 4 - 6 - 8
5
Bregma
6 Bregma 0
4
2
2
4
FIGURE 02
1
0
6
4
8 6 4 2 0 - 2 - 4
EPl
Gl
GrA
aci
E/OV
2
IPl
Mi
3
lo
3
GrO
2
ON
4
1
Interaural 7.72 mm
Bregma 3.92 mm
0 5
3
2
1
0 1 2 3

3 2 1 0 1 2 3
5
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 03
1
0
8 6 4 2 0 - 2 - 4
6
GlA
vn
4
EPlA
MiA
GrA
aci dlo
2
3
GrO
IPl
EPl
Mi
Gl
E/OV
lo
3
AOL
AOE
2
ON
4
1
Interaural 7.36 mm
Bregma 3.56 mm
0 5
3
2
1
0 1 2 3

3 2 1 0 1 2 3
4 2 0 -2 - 4 - 6 - 8
5
Bregma
6 Bregma 0
4
2
2
4
MO
FIGURE 04
1
0
FrA
8 6 4 2 0 - 2 - 4
6
VO
4
LO
AOB
dlo
2
3
AOD GrO
AOM
AOE
AOL
IPl
AOV
EPl
Mi
Gl
E/OV
aci
lo
3
2
AOE
4
1
Interaural 7.00 mm
Bregma 3.20 mm
0 5
3
2
1
0 1 2 3

3 2 1 0 1 2 3
5
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 05
1
0
8 6 4 2 0 - 2 - 4
6
PrL
4
FrA
LO
VO
MO
2
3
2
GlA
EPlA
AOB
MiA
AOE
AOD
AOM
EPl
GrO
AOL
IPl Gl
AOV Mi
AOE
E/OV
dlo
aci
lo
3
4
1
5
Interaural 6.88 mm
Bregma 3.08 mm
0
3
2
1
0 1 2 3

3 2 1 0 1 2 3
4 2 0 -2 - 4 - 6 - 8
5
Bregma
6 Bregma 0
4
2
2
4
FIGURE 06
1
0
8 6 4 2 0 - 2 - 4
6
FrA
PrL
4
LO
MO
2
VO
3
DLO
AOB
2
AOD
AOL
GrO
AOM
Gl
Mi
IPl EPl
AOV
AOE
E/OV
aci
lo
rf
3
4
1
5
Interaural 6.76 mm
Bregma 2.96 mm
0
3
2
1
0 1 2 3

3 2 1 0 1 2 3
5
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 07
1
0
8 6 4 2 0 - 2 - 4
FrA
6
PrL
4
2
MO
LO
VO
3
2
DLO
AOL
AOD
AOM
GrO
Gl
EPl
Mi
E/OV
aci
rf
3
AOV
IPl
lo
4
1
5
Interaural 6.60 mm
Bregma 2.80 mm
0
3
2
1
0 1 2 3

3 2 1 0 1 2 3
5
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 08
1
0
6
8 6 4 2 0 - 2 - 4
FrA
PrL
4
2
MO
LO
VO
3
DLO
AOD
Gl
3
AOL
AOM
E/OV
aci
rf
2
AOV
GrO
IPl
EPl
Mi
lo
4
1
5
Interaural 6.48 mm
Bregma 2.68 mm
0
3
2
1
0 1 2 3

3 2 1 0 1 2 3
4 2 0 -2 - 4 - 6 - 8
5
Bregma
6 Bregma 0
4
2
2
4
FIGURE 09
1
4
0
FrA
8 6 4 2 0 - 2 - 4
6
PrL
2
LO
VO
MO
3
2
DLO
AOL
AOD
DTT
AOM
GrO
IPl
Mi
EPl
E/OV
aci
rf
3
4
AOV
lo
VTT
1
5
Interaural 6.38 mm
Bregma 2.58 mm
0
3
2
1
0 1 2 3

3 2 1 0 1 2 3
5
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 10
1
0
6
4
8 6 4 2 0 - 2 - 4
M2
PrL
2
3
LO
VO
MO
AI
3
AOD
DTT
2
1
rf
2
Pir
AOL
DEn
AOM
E/OV
aci
4
AOV
lo
1
3 2
VTT
1
5
Interaural 6.26 mm
Bregma 2.46 mm
0
3
2
1
0 1 2 3

3 2
1
0
1 2 3
4 2 0 -2 - 4 - 6 - 8
5
Bregma
6 Bregma 0
4
2
2
4
FIGURE 11
1
0
8 6 4 2 0 - 2 - 4
6
M2
Cg1
4
PrL
2
M1
3
LO
VO
MO
AI
3
2
Pir
DEn
DTT
AOM
2
1
E/OV
aci
rf
4
1
AOP
3 2
VTT
1
lo
5
0
Interaural 6.14 mm
Bregma 2.34 mm
3 2
1
0
1 2 3

3 2 1 0 1 2 3
5
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 12
1
0
6
M2
8 6 4 2 0 - 2 - 4
4
M1
Cg1
PrL
2
3
LO
VO
MO
AI
3
2
DEn
DTT
AOM
2 1
OV
aci
rf
4
Pir
AOP
lo
1
3 2
VTT
1
5
Interaural 6.02 mm
Bregma 2.22 mm
0
3
2
1
0 1 2 3

6
4 3
2
1
0
1 2 3 4
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
FIGURE 13
0
2
4
5
0
6
8 6 4 2 0 - 2 - 4
1
M2
4
M1
Cg1
2
PrL
3
AI
LO
VO
MO
3
DP
2
DTT
2 1
OV
rf
DEn
AOM
aci
4
1
Pir
Tu
AOP
3 2
VTT
1
lo
5
0
Interaural 5.90 mm
Bregma 2.10 mm
4 3
2
1
0
1 2 3 4

6
4 3
2
1
0
1 2 3 4
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
FIGURE 14
0
2
4
5
0
6
8 6 4 2 0 - 2 - 4
M2
1
M1
4
Cg1
PrL
fmi
2
S1
3
AI
Cl
VO
IL
MO
3
2
LO
DEn
DTT
AOM
DP
2
1
OV
Acb
aca
rf
4
1
Pir
Tu
AOP
3
MO
2 1
VTT
lo
5
0
Interaural 5.78 mm
Bregma 1.98 mm
4 3
2
1
0
1 2 3 4

4
3
2
1
0
1
2
3
4
5
6
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 15
0
0
6
8 6 4 2 0 - 2 - 4
5
1
M2
M1
4
Cg1
2
S1
PrL
3
2
DI
AID
AIV
LO
Cl
CPu
IL
DP
2 1
DTT
LV
fmi
rf
3
4
Pir
DEn
AcbSh
SHi
aca
1
AcbC
SL
ICj
mfb
lo
5
VP
Tu
0
6
Interaural 5.74 mm
Bregma 1.94 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
6
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma
0
4
2
2
4
FIGURE 16
0
0
6
8 6
4
2
0
- 2 - 4
5
1
M2
M1
4
S1J
Cg1
2
PrL
S1
fmi
3
2
DI
AID
AIV
Pir
DEn
Cl
CPu
AcbC
IL
2 1
DTT
SHi
DP
LV
aca
rf
3
4
1
Tu
VP
AcbSh
ICj
SL
mfb
lo
5
0
6
Interaural 5.58 mm
Bregma 1.78 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
4 2 0 -2 - 4 - 6 - 8
6
Bregma
6 Bregma 0
4
2
2
4
FIGURE 17
0
0
6
8 6 4 2 0 - 2 - 4
5
1
M2
4
M1
S1J
Cg1
2
3
S1
DI
PrL
IL
fmi
3
2
AID
AIV
Cl
CPu
DP
DTT 2 1
LV
1
Pir
LO
DEn
AcbC
AcbSh
VP
SHi
SL
ICj
mfb
aca
lo
rf
4
5
Tu
0
6
Interaural 5.50 mm
Bregma 1.70 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
6
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 18
0
0
6
8 6 4 2 0 - 2 - 4
5
1
M2
M1
4
S1J
Cg1
2
PrL
fmi
3
GI
DI
S1
IL
cg
ec
3
2
AID
AIV
Pir
Cl
DEn
CPu
AcbC
DP
2 1
DTT
SHi
LSI
LV
aca
rf
4
1
AcbSh
SL
VP
VP
ICj
mfb
lo
5
0
Tu
6
Interaural 5.34 mm
Bregma 1.54 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
6
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 19
0
0
6
8 6 4 2 0 - 2 - 4
5
1
M2
4
S1
S1J
M1
Cg1
Cg2
cg
fmi
2
3
2
GI
DI
AID
AIV
Pir
Cl
DEn
LSS
CPu
AcbC
IL
DP
DTT
LSD
SHi
LSI
VDB
ICjM
LV
aca
ec
rf
3
4
1
AcbSh
VP
ICj
mfb
lo
5
Tu
0
6
Interaural 5.22 mm
Bregma 1.42 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
6
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 20
0
0
6
8 6 4 2 0 - 2 - 4
5
1
M2
M1
4
Cg1
S1J
Cg2
cg
fmi
2
3
S1
GI
DI
AID
CPu
LSD
IL
DP
DTT
LV
ec
3
2
AIV
Cl
AcbC
SHi
LSI
rf
4
Pir
DEn
LAcbSh
ICjM
aca
1
LSS
VP
AcbSh
ICj
VDB
mfb
lo
5
0
Tu
6
Interaural 5.14 mm
Bregma 1.34 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
6
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 21
0
0
6
8 6 4 2 0 - 2 - 4
5
1
M2
M1
4
Cg1
S1J
cg
2
Cg2
S1ULp
IG
3
2
GI
DI
AID
AIV
Cl
CPu
IG
DP
LSD
SHi
LSV LSI
MS
gcc
LV
ec
rf
3
4
1
Pir
DEn
LAcbSh
LSS
AcbC
VP
AcbSh
ICjM
VDB
aca
mfb
lo
5
VP
ICj
0
Tu
6
Interaural 4.98 mm
Bregma 1.18 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
6
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 22
0
0
6
8 6 4 2 0 - 2 - 4
5
1
M2
M1
4
S1J
Cg1
Cg2
cg
2
3
GI
DI
S1ULp
CPu
IG
LSD
gcc
DP
SHi
LV
ec
3
2
AID
AIV
Cl
DEn
LSI
LSV
ICjM
MS
aca
rf
4
1
Pir
LSS
AcbSh
VP
AcbC
AcbSh
VDB
mfb
mfb
lo
5
0
Tu
6
Interaural 4.90 mm
Bregma 1.10 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
6
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 23
0
0
6
8 6 4 2 0 - 2 - 4
5
M2
1
M1
4
S1J
S1FL
Cg1
Cg2
cg
2
3
S1ULp
S2
GI
CPu
LSD
IG
gcc
DP
SHi
LV
ec
3
2
DI
AID
AIV
Cl
DEn
LSI
LSV
ICjM
MS
aca
rf
4
1
Pir
LSS
AcbC
LAcbSh
VP
AcbSh
VDB
CB
mfb
lo
5
0
ICj
Tu
6
Interaural 4.78 mm
Bregma 0.98 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
6
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 24
0
0
6
8 6 4 2 0 - 2 - 4
5
1
M2
M1
4
S1FL
Cg1
Cg2
cg
2
S1ULp
3
IGgcc
LV
ec
S2
LSD
SHi
3
GI
DI
CPu
LSI
2
AID
AIV
Cl
DEn
LSV
ICjM
Ld
MS
aca
rf
4
1
Pir
LSS
LAcbSh
VP
AcbC
AcbSh
VP
HDB
VDB
CB
mfb
lo
5
mfb
0
Tu
6
Interaural 4.66 mm
Bregma 0.86 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
6
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 25
0
0
6
8 6 4 2 0 - 2 - 4
5
1
M2
S1FL
M1
Cg1
4
S1ULp
Cg2
cg
2
3
S2
LSD
IG
SHi
cc
LV
ec
3
2
GI
DI
AID
AIV
Cl
CPu
LSI
Ld
LSV
ZL
MS
rf
4
DEn
aca
1
Pir
LSS
Acb
VDB
5
LAcbSh
VP
VP
HDB
MPA
mfb
lo
0
ICj
Tu
ICj
6
Interaural 4.54 mm
Bregma 0.74 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
6
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 26
0
0
6
8 6 4 2 0 - 2 - 4
5
1
S1HL
M1
M2
4
S1FL
Cg1
Cg2
cg
2
3
S1ULp
IG cc
LSD SHi
LV
ec
2
S2
GI
DI
AID
AIV
Cl
CPu
BSTMA
LSI
LSV
ZL
Ld
MS
aca
rf
3
4
1
DEn
Pir
LSS
Acb
BST
LPO
MnPO
5
VP
0
Tu
HDB
MPA
VOLT
AVPe
mfb
lo
6
Interaural 4.42 mm
Bregma 0.62 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
6
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 27
0
0
6
8 6 4 2 0 - 2 - 4
5
S1HL
1
M1
M2
S1FL
Cg1
4
Cg2
cg
2
S1
3
IG
LSD
cc
LV
ec
2
1
0
S2
GI
DI
AID
AIV
Cl
DEn
Pir
LSS
CPu
VP
Tu
BSTMA
IPACL
BST
LSI
Ld
LSV
MS
SHy
ZL
MnPO
BSTLV MPA
LPO
IPACM
VOLT
SI
AVPe
HDB
MCPO
3V
ICj
VMPO
aca
mfb
lo
rf
3
4
5
6
Interaural 4.30 mm
Bregma 0.50 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
6
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 28
0
0
6
8 6 4 2 0 - 2 - 4
5
1
4
S1DZ
S1FL
S1HL
M1
M2
Cg1
Cg2
cg
2
3
S1BF
LSD
IG
cc
LV
ec
3
LSI
S2
CPu
Ld
2
GI
DI
AIP
Cl
BSTLD
LSV
aca
ZL MS
BSTMA
BSTMV
aca
rf
4
1
0
Pir
DEn
LSS
IPACL
Tu
VP
BSTLV
PS
ADP MnPO
IPACM
LPO MPA VOLT
3V
SI
AVPe
HDB
MCPO
VMPO
mfb
I
lo
5
6
Interaural 4.18 mm
Bregma 0.38 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
6
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 29
0
0
6
8 6 4 2 0 - 2 - 4
5
1
S1DZ
S1FL
S1HL
M1
M2
Cg1
S1HL
S1FL
4
S1BF
Cg2
IG
LSD
cc
LV
cg
ec
2
3
S2
LSI
SFi
3
2
1
0
GI
DI
AIP
Cl
DEn
Pir
LSS
I
CPu
IPACL
Tu
BSTLD
LSV
ZL
MS
MnPO
BSTLJ
BSTLP
BSTMA
BSTMV
BSTLV
PS
IPACM
Fu ADP Pe
VP
LPO
AVPe
SI
MPA
MCPO HDB
VMPO
3V
aca
acp
ic
mfb
I
lo
exc
rf
4
5
6
Interaural 4.06 mm
Bregma 0.26 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
6
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 30
0
0
6
8 6 4 2 0 - 2 - 4
5
S1DZ
S1FL
S1HL
M1
M2
Cg1
1
4
Cg2
cg
S1BF
2
LSD
IG
cc
LV
ec
3
S2
LSI
SFi
3
CPu
BSTLD
2
GI
LSV
f
1
0
DI
AIP
Cl
DEn
Pir
IPACL
BSTLJ
BSTLV
IPACM
VP
SI
MCPO
HDB
Tu
MnPO
BSTMA
BSTLP
aca
ADP
BSTMV
StA
PS
MPOC
Fu
Pe
MPOM
LPO MPA AVPe
VLPO
3V
VMPO
2n
ic
acp
mfb
I
lo
exc
rf
4
5
6
Interaural 3.94 mm
Bregma 0.14 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
6
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 31
0
0
6
8 6 4 2 0 - 2 - 4
5
S1FL
S1HL
M1
M2
Cg1
1
4
S1BF
S1DZ
Cg2
IG
LSD
cc
cg
LV
ec
2
3
LSI
2
1
0
S2
GI
DI
AIP
Cl
DEn
Pir
VEn
I
CPu
IPACM
IPACL
VP
MCPO
Tu
BSTLD
LGP
BSTLJ
BSTLP
SI
HDB
SFi
LSV
BSTMA
BSTLI
BSTMV
BAC
aca
ADP
BSTLV MPOC
Pe
MPOM
LPO MPA
AVPe
ox
VMPO
VLPO
f
D3V
BSTS
acp
3V
st
ic
SLEA
acp
mfb
I
exc
rf
3
4
5
6
Interaural 3.82 mm
Bregma 0.02 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
6
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 32
0
0
6
8 6 4 2 0 - 2 - 4
5
S1HL
M1
M2
1
S1DZ
S1FL
Cg1
4
S1BF
Cg2
IG
cc
cg
2
3
LSD
LSI
SFi
LV
ec
S2
CPu
BSTMPM
BSTMPI
SFO
TS
3
2
1
GI
DI
AIP
Cl
DEn
Pir
VEn
I
IPACM
IPACL
LGP
BSTLP
BSTLI
VP
SI LPO
LSV
D3V
BAC
aca
ADP
BSTMV
MPOC
MPOM
f
Pe
A14
st
ic
SLEA
acp
I
exc
rf
4
5
0
CxA
AAD
MCPO
AAV
HDB
MPOL
VLPO
MPA
VMPO
3V
ox
mfb
6
Interaural 3.70 mm
Bregma -0.10 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
6
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 33
0
0
6
8 6 4 2 0 - 2 - 4
5
S1DZ
S1FL
S1HL
M1
M2
Cg1
1
4
S1BF
Cg2
IG
cc
cg
2
LSD
df
LV
ec
3
S2
CPu
SFi
SFO
TS
vhc
3
2
1
0
GI
DI
AIP
Cl
Pir
DEn
IPACM
VEn
CxA
IPACL
I
AAD
LGP
ACo
LOT
BSTMPM
BSTMPI
VP
MCPO
AAV
BSTLP
SI
HDB
BSTS
BSTMPL
LPO
MPOM
MPOL
MPA
ADP
AC
Pe
SCh
D3V
PVA
3V
ox
f
A14
sm
st
ic
SLEA
mfb
acp
I
rf
4
5
6
Interaural 3.58 mm
Bregma -0.22 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
6
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 34
0
0
6
8 6 4 2 0 - 2 - 4
5
S1HL
M1
M2
1
S1DZ
S1FL
Cg/RS
4
cg
S1BF
IG
LSD
cc
df
LV
ec
2
3
SFi
TS
S2
SFO vhc
D3V
fi
3
2
1
0
GI
DI
AIP
Cl
DEn
Pir
CPu
I
VEn
CxA
BSTS AD
AV PVA
BSTMPL
PT
BSTMPM
ADP
LGP
B
A14
AC 3V
IPACL
Pe
IPACM
BSTMPI
VP SI
MPOL
B LH
AAD
AHA
MPOM
MCPO
MPA
HDB
LA
AAV
ACo LOT
SCh
f
sm
opt
st
ic
SLEAC
SLEAM
mfb
acp
I
rf
4
5
6
Interaural 3.46 mm
Bregma -0.34 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
6
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 35
0
0
6
8 6 4 2 0 - 2 - 4
5
S1HL
M1
M2
1
S1DZ
S1ShNc
Cg/RS
4
3
2
1
0
GI
S2
DI
AIP
S1BF
Cl
DEn
Pir
CPu
acp
VEn
CxA
LGP
IPACL
SI
IPACM
AAD
LOT 3
2
ACo
1
B
AAV
BSTS
Rt
LH
MCPO
HDB
AV
SM
SFi
AD
AM
AD
AC
LA
PT
AC
BSTMPL
MPOL
MPOM
AHA
LSD
IG
Pe
MPA
cc
df
TS
vhc
SFO
D3V
PVA
CM
Re
3V
SChDM
SChVL
PC
cg
sm
sm
f
opt
LV
fi
st
ic
SLEAC
SLEAM
mfb
I
ec
acp
rf
2
3
4
5
6
Interaural 3.34 mm
Bregma -0.46 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
4 2 0 -2 - 4 - 6 - 8
6
Bregma
6 Bregma 0
4
2
2
4
FIGURE 36
0
0
6
8 6 4 2 0 - 2 - 4
5
S1DZ
S1FL
S1HL
M1
M2
Cg/RS
1
cg
4
S1BF
IG
cc
TS
df
LV
ec
2
SFi
vhc
3
2
S2
GI
DI
AIP
Cl
CPu
LGP
AD
BSTS
AVDM
AVVL
VA IAD
AM
Rt
AMV
B
SFO
D3V
PC
MD PVA
PT
CM
Re
sm
sm
fi
st
ic
rf
3
4
1
0
DEn
Pir
IPACM IPACL
BLA
SI
I CeM B
VEn
AAD
BMA 3
CxA
ACo
LOT
2
1
PaLM
BSTMPL
SI
LH
MCPO
SO
AAV
Xi
PaAP 3V
PaV
AHA
Pe
MPA
LA
SChVL maopt
SChDM
f
opt
mfb
sox
SLEAC
SLEAM
I
5
6
Interaural 3.22 mm
Bregma -0.58 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
6
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 37
0
0
6
8 6 4 2 0 - 2 - 4
5
S1DZ
S1FL
S1HL
M1
M2
Cg/RS
1
4
S1BF
IG
TS
cc
df
cg
LV
ec
2
3
2
1
0
S2
GI
DI
AIP
Cl
Pir
DEn
CPu
La
VEn
BLA
IPAC
I
CxA
CeM
ACo
LGP
BMA
B
SI
AAD
BSTS
B
3
LOT 2
1
SI
MCPO
MeAD
Rt
AVVL
VA
LH
AVDM
SO
PaLM
AD
AM
AMV
MD
IAD
IAM
AHC
Cir
LA
PC
Re
PT
PaV
SPa
Pe
SCh
vhc
SFO
D3V
PVA
CM
Xi
3V
sm
PaLM
maopt
PaDC
PaMP
PaMM
f
opt
fi
mfb
Acs
sox
st
ic
SLEAC
SLEAM
BLA
I
rf
3
4
5
6
Interaural 3.10 mm
Bregma -0.70 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
4 2 0 -2 - 4 - 6 - 8
6
Bregma
6 Bregma 0
4
2
2
4
FIGURE 38
0
0
6
8 6 4 2 0 - 2 - 4
5
S1ShNc
S1HL
M1
M2
Cg/RS
1
cg
4
3
2
S2
GI
DI
AIP
Cl
S1BF
CPu
LGP
B
BSTS
Rt
LDVL
AD
MHb
MD
AVDM
AVVL PC PVA
IAD
VPL
PT
VA
AM
AMV
vhc
SFO
CM
IAM
Re
IG
cc
df
D3V
sm
LV
fi
st
ic
ec
rf
2
3
4
1
0
DEn
Pir
IPAC
La
CeM
BLA SI
CeC
SI LH
I
MCPO
VEn
IM
BMA
SO
CxA ACo
MeAD
BAOT
ZI
PaDC
PaLM
PaMM
AHC
SPa
Cir
Pe
LA
SCh
Xi
PaMP
3V
sox
maopt
f
opt
mfb
SLEAC
SLEAM
AAD
3
LOT
2
1
I
5
6
Interaural 2.98 mm
Bregma -0.82 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
6
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 39
0
0
6
8 6 4 2 0 - 2 - 4
5
S1DZ
S1ShNc
S1HL
M1 M2
RSA
1
RSG
cg
4
S1BF
Or
Py CA3
GrDG
Mol
DG
IG
cc
df
dhc
D3V
LV
ec
2
3
2
1
0
S2
GI
DI
AIP
Pir
Cl
DEn
La
VEn
CPu
IPAC
AStr
BLA
CxA
LGP
B
CeC
CeMAD
CeMAV
IM
ACo
BSTS
Rt
B
BMA MeAV
VPL
MeAD
SO
BAOT
LDVL
LDDM
VA
VL
LH
AV
AD MHb
VM
IAD
AM
ZI
PaLM
PaMM
AHP
LHb
MD
PC
Sub
IAM
Re
Cir
SPa
Pe
PV
CM
Rh
Xi
PaMP
RCh
3V
sm
mt
PaDC
f
sox
mfb
opt
fi
st
SLEAC
ic
rf
3
4
5
6
Interaural 2.86 mm
Bregma -0.94 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
6
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 40
0
0
6
8 6 4 2 0 - 2 - 4
5
S1DZ
S1Sh
S1HL
M1 M2
RSA
RSG
cg
1
4
3
S2
S1BF
LDVL
Or
Py
SLu
Rad
GrDG
AD
LDDM
CL
AV
Mol
CA3
DG
MHb
LHb
MDL
IG
cc df
D3V
MDM
PV
dhc
sm
alv
PoDG
GrDG
AD
LV
fi
st
ec
2
3
2
1
0
GI
DI
AIP
CPu
Rt
VPL
LGP
Cl IPAC
La
AStr
B
MGP
DEn BLA
CeMAD
CeC
CeMAV
AL
Pir
VEn BLV
I
BMA
MeA
CxA ACo
VL
VPM
LH
VM
ZI
TC
PC
AM
Sub
PaMP
AHP
Pe
VMH
PaPo
MDC
CM
IAM
Rh
Re
VRe
Xi
3V
mt
A13
f
ns
mfb
opt
sox
st
ic
lo
I
rf
4
5
6
Interaural 2.74 mm
Bregma -1.06 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
6
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 41
0
0
6
8 6 4 2 0 - 2 - 4
5
S1DZ
S1Sh
S1HL
M1
M2
RSA
1
RSG
cg
4
3
2
1
0
S2
GI
DI
AIP
DEn
Pir
CPu
LaDL
S1BF
BLA
IPAC
AStr
CeL
CeC
VEn
BLV
CxA
LGP
PLCo
CeM
BMA
Rt VPL VPM
AM
MDM
IMD
Or
Py
Rad
CA2 CA1
IG cc df
CA3 PoDG
dhc
SLu
GrDG DG
D3V
LDDM
Mol
MHb
LDVL
LHb
PV
CL
MDC
AV
MDL
PC
CM
VL
IAM
ACo
MGP
SI
MeA
LH
VM
ZI
TC
PaPo
Sub
VRe
Stg
AHP
VMH
Pe
Rh
Re
Xi
PaMP
A13
Arc
3V
sm
mt
f
alv
ns
mfb
sox
opt
al
fi
LV
st
st
ic
ec
rf
2
3
4
5
6
Interaural 2.58 mm
Bregma -1.22 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
6
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 42
0
0
6
5
8 6 4 2 0 - 2 - 4
S1Tr
M1
M2
RSA
4
3
S2
S1BF
S1DZ
LDVL
Or
RSG
Py
IG cc df
CA2 Rad CA1
SLu
dhc
CA3
LMol GrDG
Mol
DG
D3V
Po
LDDM
PoDG
CL MDL
MHb
LHb
PV
cg
hf
sm
fr
alv
LV
fi
st
ec
1
2
3
2
1
0
Ect
PRh
CPu
LGP
DEn LaDL AStr
IPAC
BLA
Pir
VEn
CeL
CeC
CeMPV
BLV
BSTIA
CxA PLCo
I
BMA
Rt
ACo
VPM
VPL
MGP
MePD
MePV
SI
B
LH
VL
SOR
VM
ZI
SubI
PC
AHP
MDM
MDC
IMD
Sub
VRe
A13
DM
Xi
VMHDM
VMHC
VMHVL
Pe
CM
Rh
Re
Arc
3V
mt
f
ns
mfb
aot
sox
opt
ic
st
I
rf
4
5
6
Interaural 2.46 mm
Bregma -1.34 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
4 2 0 -2 - 4 - 6 - 8
6
Bregma
6 Bregma 0
4
2
2
4
FIGURE 43
0
5
0
8 6 4 2 0 - 2 - 4
6
LPtA
S1Tr
MPtA
RSA
4
3
S2
S1BF
RSG
Or
Py
Rad
IG cc df
CA2 LMol
CA1
SLu Mol
dhc
CA3
GrDG
DG
D3V
LDDM PoDG
sm
LDVL LPMR MHb
CL LHb
PV
Ang
Po
MDL MDC
fr
hf
cg
alv
fi
LV
st
ec
1
2
3
2
1
0
Ect
PRh
DEn
Pir
CPu
LaDL
LaVL
IPAC
AStr
CeL
CeC I
BSTIA
VEn
CeMPV
BLA
BMP
BLV
LGP
PLCo
BMA
Rt
ACo
VPM
VPL
MGP
MePD
MePV
MDM
IMD
PC
VL
CM
Rh
VM
Sub
ZID
Re
ZIV
VRe
A13 Xi
SubI Pe
DM
LH
VMHDM
3V
VMHC
VMHVL
SOR
Arc
mt
f
ns
mfb
sox
opt
st
ic
I
rf
4
5
6
Interaural 2.34 mm
Bregma -1.46 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
6
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 44
0
5
0
8 6 4 2 0 - 2 - 4
6
S1Tr
LPtA
MPtA
RSA
4
3
S2
S1BF
CA2
SLu
CA3
LDVL
Or
Po
Py
Rad CA1
LMol
Mol
LPMR
GrDG
PoDG
CL
MDL
Ang
RSG
DG
IG
MHb
LHb
cc
D3V
PV
df
dhc
fr
cg
hf
LDDM
alv
LV
fi
st
ec
1
2
3
2
1
0
Ect
PRh
Pir
DEn
CPu
LGP
LaDL AStr
LaVL
CeL
CeC
BLA CeMPV
VEn
BLV
BMA
VMHC
PLCo
Rt
VPL
I
BSTIA
BMP MePD
MGP
MePV
ACo
VPM
LH
VL
MCLH
VM
ZID
ZIV
MDC
MDM IMD
SubI
PC
VMHVL
Rh
Sub
Re
VRe
DM
Xi
Pe
VMHDM
Arc
CM
3V
mt
f
ns
mfb
sox
opt
st
ic
I
rf
4
5
ME
6
Interaural 2.22 mm
Bregma -1.58 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
6
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 45
0
5
4
3
2
1
0
0
6
8 6 4 2 0 - 2 - 4
S1BF
S2
AuV
Rt
Ect
CPu
LaDL
LGP
PRh
AStr
CeL
DEn LaVL
CeC
BSTIA
BLA
Pir
I
BMP
VEn
BLV
BMA
PLCo
VPL
VLG
STh
MePD
ACo
DLG
MePV
S1Tr
CA2
SLu
CA3
LDVL
LPtA
Or
Py
Rad CA1
LMol
LDDM
Po
VPM
MCLH
Mol
LH
LPMR
VL
OPC
GrDG
PoDG
VM
ZID
ZIV
PeF
CL
SubI
MPtA
RSA
MDL
MDC
MDM
PC
Sub
VRe
DM
FC
DG
VMHDM
VMHC
VMHVL
RSG
IG cc df
LHb
MHb
PV
Xi
D3V
IMD
CM
Pe
Rh
Re
3V
dhc
fr
ArcD
mt
ArcL
hf
cg
f
ns
alv
ml
sox
eml
opt
LV
fi
st
ic
st
I
ec
rf
1
2
3
4
5
ME
6
Interaural 2.10 mm
Bregma -1.70 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
6
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 46
0
0
6
8 6 4 2 0 - 2 - 4
S1Tr
LPtA MPtA
RSA
5
4
S2
S1BF
CA2
SLu
CA3
Or
Py
Rad
LMol
Mol
CA1
PoDG
GrDG
RSG
IG cc df
dhc
FC
DG D3V
hf
cg
alv
1
2
3
2
1
AuV
TeA
Ect
PRh
Pir
DEn
CPu
AStr
LaDL CeL
LaVL
CeC
LaVM
VEn
BLA
BLV
st
BSTIA
BMP
VLG
I
Rt
DLG
VPL
MePD
MePV
LPLR
VPM
STh
MCLH
ZIV
LPMR
Po
CL
OPC
ZID
LH
PeF
Te
PC
VM
LHbM MHb
LHbL
MDL
DMV
MDC
MDM
Sub
VRe
PH
DMC
DMD
PV
Pe
IMD
CM
Rh
Re
fr
hbc
mt
f
ns
ml
sox
eml
cp
opt
LV
fi
st
ic
st
I
ec
rf
3
4
5
0
PLCo
PMCo
MTu
VMHDM
VMHC
VMHVL
3V
ArcD
ArcL
ME
6
Interaural 1.98 mm
Bregma -1.82 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
6
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 47
0
0
8 6 4 2 0 - 2 - 4
6
LPtA
MPtA
RSA
5
V2L
4
3
2
1
0
TeA
Ect
PRh
AuV
CPu
LaDL
S1BF
AStr
CA2
SLu
DEn
CeL
LaVL
LaVM BSTIA
BLA
Pir BLP
VEn
BLV
BMP
PLCo
VLG
Rt
CA3
DLG
MePD
AHiAL
PMCo
VPL
LPLR
STh
MePV
Or
Py
Rad CA1
LMol
Mol
GrDG
VPM
MCLH
PoDG
LPMR
Po
ZIV
Te
OPC
FC
DG
MHb
CL
LHbL
LHbM
PC
ZID
DMC
LH
PeF
MDL
Gus
VM
DMV
MDC
RSG
IG
MDM
cc
PV IMD
PH
DMD
CM
Pe
MTu
ArcD
VMHDM
VMHC 3V
VMHVL
ME
D3V
df
dhc
hbc
fr
PoMn
A11
mt
A12
ArcL
cg
f
hf
scp
ns
alv
eml
ml
cp
sox
opt
ic
fi
I
ec
LV
ic
st
rf
1
2
3
4
5
6
Interaural 1.86 mm
Bregma -1.94 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
6
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 48
0
0
8 6 4 2 0 - 2 - 4
6
LPtA
MPtA
RSA
5
4
3
2
1
0
AuV
TeA
Ect
AuD
CPu
PRh LaDL AStr
Pir
DEn
LaVM
LaVL
VEn
S1
BLP
BLV
BLA
BMP
PLCo
V2L
CA2
SLu
CA3
BSTIA
CA1
DLG
VLGMC
VLGPC
Rt
AHiAL
VPL
MePD
MePV
PMCo
IMA
Or
Py
Rad
LMol
Mol
GrDG
LPLR
VPM
STh
PoDG
Po
LPMR
CL
PC
OPC
VM
ZIV ZID
PSTh
LH
Te
MTu
PeF
DG
PF
LHb
MD
Gus
DM
VMH
ArcL
RSG
FC
MHb
SPF
PH
DMC
IG
ArcD
PV
cc
D3V
IMD
PoMn
CM
ME
df
dhc
3V
A12
fr
hbc
mt
cg
hf
ml
scp
ns
f
alv
eml
cp
sox
ic
opt
fi
LV
st
CeL
ec
rf
1
2
3
4
5
6
Interaural 1.74 mm
Bregma -2.06 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
6
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 49
0
0
6
5
4
3
2
8 6 4 2 0 - 2 - 4
TeA
Ect
AuV
PRh
LEnt
Au1
AuD
DEn
CPu
AStr
LaDL
S1
LaVM
LaVL
V2L
CA2
SLu
IGL
V1
CA3
VLGMC
VLGPC
Rt
CA1
DLG
V2MM
VPL
Or
Py
Rad
LMol
Mol
GrDG
LPLR
VPM
ZIV ZID
V2MM
PoDG
LPMR
Po
OPC
VM
RSA
DG
APTD
PF
Gus
FC
MHb
LHb
PrC
RSG
SPF
IG
cc
dhc
D3V
PVP
pv
df
hbc
fr
cg
scp
ml
hf
alv
IMA
eml
opt
ic
opt
sox
st
fi
LV
ec
rf
1
2
3
4
1
0
Pir
VEn
BLV
BLP
PLCo
BMP
BSTIA
AHiAL
PMCo
MePV
DG
STh
PSTh
LH
VTM
Te
Gem
SMT
ArcMP
ArcLP
PH
DTM
DM 3V
ME
mt
f
ns
cp
MePD
st
5
6
Interaural 1.62 mm
Bregma -2.18 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
6
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 50
0
0
6
5
4
3
8 6 4 2 0 - 2 - 4
AuV
TeA
Ect
Au1
CPu
AuD
S1
V2L
CA2
CA3
SLu
V1
VLGMC
VLGPC
SubG
IGL
CA1
V2ML
DLG
VPL
Or
Py
Rad
LMol
Mol GrDG
LPLR
IMA
VPM
V2MM
PoDG
LPMR
Po
DG
APTD
RSA
PF
RSG
FC
IG
hbc
cc
dhc
D3V
PVP
df
SCO 3V
pc
PrC
pv
fr
cg
hf
eml
alv
fi
ec
rf
1
2
3
2
PRh
LEnt
DEn
La
ZIV
ZID
Gus
FF
Gem
PR
SPF
scp
ml
opt
sox
LV
LaVM
LaDL
4
1
0
Pir
VEn
BLP
BMP
PLCo
AHiAL
PMCo
STh
DG
PSTh
LH
Te
VTM
ArcMP
PMV
ArcLP
PH
SMT
DTM
3V
Me
mt
f
ns
cp
MePD
5
6
Interaural 1.50 mm
Bregma -2.30 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
4 2 0 -2 - 4 - 6 - 8
6
Bregma
6 Bregma 0
4
2
2
4
FIGURE 51
0
5
0
6
8 6 4 2 0 - 2 - 4
V2L
V1
V2ML
Or
V2MM
RSA
RSG
cg
1
4
3
2
Au1
AuV
TeA
Ect
PRh
LEnt
AuD
DEn
CA2
SLu
CA3
VLGMC
Or
Py
Rad
IG
LMol
CA1
Mol GrDG
S FC
PoDG DG
OPT
APTD
LPMC
LPMR
DLG
IMA
PrC
LPLR
IGL
Po
VPM
PF
VLGPC
ZID
SPFPC
RI
SubG
ZIV F PR
cc
dhc
pc
D3V
fr
scp
ml
hf
str
alv
opt
fi
LV
ec
LaDL
rf
2
3
4
SNR
Gem
PH
LaVM
1
0
Pir VEn BLP
CA3
BMP
AHiAL AHiPM Py
APir
PMCo
PLCo
DG
PSTh
SMT SuMM
LH
DTM
PMD
3V
PMV
VTM
ArcLP ArcMP
mt
f
ns
cp
5
6
Interaural 1.34 mm
Bregma -2.46 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
6
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 52
0
0
6
5
4
3
8 6 4 2 0 - 2 - 4
AuV
Au1
AuD
V2L
SLu
CA3
CA2
V1
CA1
V2ML
Or
Py
Rad
LMol
Mol GrDG
DG
PoDG
LPMC
V2MM
LPMR
DLG
APTD
IGL IMA LPLR
RSA
S
OPT
PPT
FC
RPF
RSG
SCO
PAG
pc
D3V
scc
dhc
cg
alv
hf
bsc
1
2
3
2
1
0
TeA
Ect
PRh
LEnt
Pir
DEn
alv
APir
BLP
PLCo
Or
BMP
alv
AHiAL
VLGMC
VLGPC
CA3
PMCo
SubG
Py
LT
AHiPM
VPM
SPFPC
SNC
DG
SNR
Po
ZID
ZIV
Sc
Eth
PSTh
F
LH
VTM
PR
SMT
PMD
RI
PF
PMV
ArcLP
SuMM
ArcMP
PH
DTM
3V
fr
mt
scp
mtg
f
ns
ml
cp
str
opt
Py CA3
fi
LV
ec
rf
4
5
6
Interaural 1.26 mm
Bregma -2.54 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
6
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 53
0
0
6
5
4
3
2
1
8 6 4 2 0 - 2 - 4
V2L
AuD
Au1
AuV
CA2
SLu
TeA
Ect
CA3
PRh
Or
LEnt DEn
Pir
BLP
APir
CA1
Py
PMCo
Or
V1
CA3
AHiPM
DLG
VLGMC
SubG
Or
Py
Rad
LMol
Mol
GrDG
IMA
PoDG
V2ML
DG
IGL
Eth
VLGPC
Po
LT
PP
SLu
DG
SPFPC
SNC
V2MM
S
RSA
FC
RSG
MPT
OPT
PPT
LPMR APTD
PCom
LPMC
MCPC
LPLR
APTV
ZID
ZIV
SNR
SNC
REth
LH
PR
F
RPF
SuML
OT
SCO
PAG
RI
D3V
pc
PH
sumx
SuMM
MMn
LM ML MM
VTM
PMD
MRe
D3V
fr
pm
mtg
cg
fmj
dhc
scp
ns
f
ml
alv
cp
hf
bsc
str
opt
Py
alv
CA1
LV
BMP
ec
rf
1
2
3
4
5
0
ArcMP
6
Interaural 1.10 mm
Bregma -2.70 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
6
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 54
0
0
6
5
4
3
2
1
0
8 6 4 2 0 - 2 - 4
AuV
TeA
Ect
Au1
PRh
LEnt
AuD
Pir
DEn
V2L
SLu
CA3
Or
APir
CA2
IGL
BLP
Py
Or
PMCo
V1
CA2
Or
Py
Rad
LMol
CA1
Mol
GrDG
V2ML
PoDG
DLG IMA
SG
VLGMC MGD
VLGPC
MGV
MGM
SLu
CA3
AHiPM
DG
LPMC
LPLC
IntG
SubG
SNR
V2MM
REth
SPFPC
PP
LT
ZID
SNL ZIV
GrDG
PIL
SNC
PLi
PoT
APTV
S
RSA
FC
RSG
MPT
OT
PPT
OPT
PCom
APTD MCPC
pc
Eth
LH
RPF
LM
VTM
SCom
PR
SuML
RI
SCO
PAG
Dk
ML MM
EW
ArcMP
sumx
SuMM
MMn
D3V
MRe
fr
mtg
pm
cg
fmj
dhc
scp
ml
ns
f
cp
alv
hf
bsc
opt
alv
LV
ec
rf
1
2
3
4
5
6
Interaural 1.00 mm
Bregma -2.80 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
6
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 55
0
0
8 6 4 2 0 - 2 - 4
6
V2MM
V2ML
RSA
5
V1
V2L
Or
S
RSG
cg
fmj
dhc
alv
1
4
3
2
1
AuD
Au1
AuV
TeA
Ect
PRh
LEnt
SLu
CA1
Mol
CA3
SLu
CA3
VLGMC
VLGPC
CA2
Rad Or
APir
CA2
Or
BLP
Py
PMCo
Py
Rad
LMol
CA1
AHiPM
GrDG
PoDG
DLG
IGL
LPLC
MGD
SubG
SPFPC
LT ZI
PP
SNL
DG
LPMC
APTD
PLi
SNR
VTM
GrDG
PoDG
OT
PPT
MCPC
MGV SG
APTV
MGM
RPF
DpMe
MZMG
PoT InC
PIL
REth
RPC
InCG
VTA
PBP
SNC
SC
PCom
LM ML MM
VTM
PAG
Dk
pc
EW
sumx
SuM
MMn
Aq
fr
mtg
scp
mp
pm
f
ml
cp
bsc
hf
opt
alv
LV
ec
rf
2
3
4
5
0
6
Interaural 0.88 mm
Bregma -2.92 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
6
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 56
0
0
6
5
4
3
2
1
8 6 4 2 0 - 2 - 4
AuV
TeA
Ect
PRh
Au1
LEnt
AuD
Or
V2L
CA2
CA3
SLu
APir
BLP
CA1
Py
Or
Rad
Py LMol
Mol
GrDG
PoDG
Py Or
Rad
AHiPM
PMCo
V1
CA3
SNL
DG
SG
MGD
MGV
MZMG
PP
V2ML
S
PIL
ZI
PoDG
LPMC
APT
PLi
MGM
SNR
PoT
GrDG
V2MM
PPT
OT
SNC
RSA
RSG
InC
InCG
DpMe
SuG
InWh
DpG
csc
pc
ML
LM
PAG
Dk
RPC
MA3
EW
VTRZ
RLi
VTA
PBP
MT
Op
InG
DpWh
Zo
IF
IPF
SuM
MM
Aq
mtg
fr
mp
pm
scp
f
cg
fmj
dhc
bsc
ml
cp
hf
alv
alv
ec
rf
1
2
3
4
5
0
6
Interaural 0.72 mm
Bregma -3.08 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
6
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 57
0
0
6
5
8 6 4 2 0 - 2 - 4
V1
V2ML
V2MM
RSA
RSG
cg
1
dhc
4
V2L
S
Op
SuG
Zo
alv
3
2
1
AuV
TeA
Ect
PRh
Au1
AuD
LEnt
Or
Rad
LMol
APir
BLP
CA1
Py
CA1
Mol
SLu
AHiPM
PoDG
Or
Py
Rad
CA3
GrDG
DG
MGD
MGV
MZMG
MGM
PP
SNL
PPT
SG
PoT
PIL
SNC
PLi
PoDG
GrDG
APT
SNR
DpMe
RPC
MT
InG
InWh
DpWh
InCG
InC
RPC
VTRZ
PBP
VTA
SNC
SuM
ML
DpG
MA3
PAG
Dk
csc
EW
RLi
IF
IPF
MM
pc
Aq
mtg
fr
scp
mp
pm
bsc
ml
cp
hf
alv
ec
rf
2
3
4
5
PMCo
0
6
Interaural 0.64 mm
Bregma -3.16 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
6
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 58
0
0
8 6 4 2 0 - 2 - 4
6
V2ML
V2MM
RSA
5
V1
RSG
cg
1
4
V2L
S
Zo
SuG
Op
InG
dhc
3
2
1
AuD
Au1
AuV
Or
TeA
Ect
PRh
LEnt
DG
InWh
GrDG
CA1
PoDG
csc
DpG
DT
SG
DpWh PAG Aq
pc
Py
MGD APT
PLi
MGV
Dk
Rad
InCG
MZMG
LMol
MGM
DpMe InC
PoT
MA3
SLu
EW
PIL
PP
scp
Or
RPC
CA3 Py
Rad
VTRZ RLi
SNL MT
Mol
mtg
CA1
SNC
VTA
IF vtgx
SNR
PBP IPR mp
SNC
PoDG
S
IPF
APir
3n
AHiPM
MM
GrDG
ml
bsc
alv
hf
cp
alv
ec
rf
2
3
4
5
PMCo
0
6
Interaural 0.52 mm
Bregma -3.28 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
6
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 59
0
0
8 6 4 2 0 - 2 - 4
6
V2ML
V2MM
RSA
5
V1
RSG
SuG
Zo
cg
dhc
1
4
3
2
1
V2L
AuD
Au1
CA1
AuV
Or
Py
TeA
Rad
LMol
Ect
PRh
CA1
LEnt
APir
PoDG
CA3
S
SLu
AHiPM
GrDG
Rad
Mol
Or
Py
S
DG
MGD
MGV
MZMG
PP
SNL
DT
SG
APT
PIL
MGM
SNC
PrS
PoT
PoDG
GrDG
SNR
MT
DpMe
SNC
Op
RPC
RMC
InG
InWh
DpG
DpWh
InCG
InC
DLPAG
LPAG
PBP
VTA
IPDL
PN
IPL
Dk
MA3
csc
DMPAG
RLi
IF
IPR
IPC
Aq
EW
IPI IPF
MM
mlf
scp
mtg
vtgx
IPDM
ml
cp
bsc
bic
alv
hf
alv
ec
rf
2
3
4
5
PMCo
0
6
Interaural 0.40 mm
Bregma -3.40 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
6
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 60
0
0
8 6 4 2 0 - 2 - 4
6
V2ML
V2MM
RSA
5
4
3
2
1
TeA
Ect
PRh
V2L
AuD
Au1
CA1
Or
Py
Rad
LMol
CA1
LEnt
APir
GrDG
PoDG
Or
Py
CA3 Rad
Mol
S
V1
S
DG
MGV
SubB
PP
DT
MZMG
SNL
GrDG
PrS
SNC
SNR
PoDG
DpMe
RSG
SuG
Op
InG
InWh
DpG
DpWh
InC
Zo
DLPAG
LPAG
Dk
MA3
RMC
csc
EW
RLi
PBP
IPDM
VTA IF
PN
IPDL
IPR
IPL
IPI
DMPAG
IPC
Aq
mlf
mtg
vtgx
scp
ml
cp
3n
cg
bsc
dhc
bic
hf
alv
ec
rf
1
2
3
4
5
PMCo
AHiPM
0
6
Interaural 0.28 mm
Bregma -3.52 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
6
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 61
0
0
8 6 4 2 0 - 2 - 4
6
V2ML
V2MM
RSA
5
V1
RSG
SuG
Op
Zo
cg
dhc
1
4
V2L
S
PrS
InG
InWh
bsc
alv
2
AuD
DpG
DMPAG
DLPAG
hf
3
Au1
TeA
CA1
DG
DT
MZMG
MGV
DpMe
DpWh
LPAG
Su3C
InC
Dk
EW
Aq
bic
3
2
Ect
PRh
Or Py
Rad
LMol
LEnt
PoDG
GrDG
Or
CA3
SubB
PP
SNL
SNR
SNC
Min
RMC
VTA
PBP
MA3
PN
IPDL
RLi
IF
IPR
mlf
mtg
vtgx
scp
IPDM
ml
3n
Py
Rad
Or
ec
rf
4
1
APir
S
Py
Mol
IPL
IPI
IPC
bas
cp
5
PMCo
AHiPM
0
6
Interaural 0.16 mm
Bregma -3.64 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
6
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 62
0
0
8 6 4 2 0 - 2 - 4
6
V2ML
V2MM
RSA
5
V1
RSG
SuG
Zo
cg
1
4
V2L
S
PrS
Op
InG
InWh
DpG
DMPAG
DLPAG
bsc
dhc
alv
2
3
2
1
TeA
Ect
PRh
Mol GrDG
CA1
DG
Or
Py
Rad
LMol
PoDG
LEnt
S
Py
AHiPM
APir
PMCo
SubB
BIC
MZMG
SNL
SNC
SNR
DpMe
DpWh
RRF
LPAG
InC
Su3C
Su3
RMC
PBP
IPL
3PC
3N
EW
IPDL PN
VTA
Pn
RLi
IF
IPR
IPC
IPI
Aq
mlf
mtg
vtgx
scp
rs
IPDM
ml
cp
bp
bic
hf
ec
rf
3
4
5
0
6
Interaural 0.00 mm
Bregma -3.80 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
6
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 63
0
0
6
8 6 4 2 0 - 2 - 4
V2ML
V2MM
RSA
5
Pi
V1
RSG
SuG
Op
Zo
cg
1
4
V2L
PrS
InWh
DpG
InG
DMPAG
DLPAG
bsc
dhc
alv
2
3
2
Ect
TeA
PRh
LEnt
S
CA1
LMol
Mol
DG
GrDG
PoDG
BIC
SubB
DpWh
DpMe
RRF
SNR
SNC
LPAG
RMC
PBP
IPDM
VTA
IPDL
Su3C
Su3
3PC
3N
dtgx
RLi
IPR
Aq
EW
mlf
mtg
scp
vtgx
rs
A8
bic
MG
hf
ec
rf
3
4
1
IPL
IPI
Pn
IPC
ml
cp
bp
5
0
6
Interaural -0.08 mm
Bregma -3.88 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
6
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 64
0
0
6
5
8 6 4 2 0 - 2 - 4
V2ML
V2MM
RSA
Zo
1
V1
RSG
SuG
Op
InG
4
V2L
PrS
InWh
DpG
DLPAG
LPAG
DMPAG
Aq
bsc
dhc
alv
ec
2
3
2
1
Ect
TeA
PRh
LEnt
S
LMol
Mol
DG
MEnt
BIC
SubB
SNR
DpWh
DpMe
RRF
PnO
3PC
IPDL
Su3C
Su3
RMC
IPL
Pn
IPDM
3N
IPI
EW
DR
CLi
PMnR
MnR
IPR
I3
IPC
mtg
IPA
scp
mlf
ml
ts
B9
cp
rs
A8
bp
bic
MG
PoDG
GrDG
rf
3
4
5
0
6
Interaural -0.24 mm
Bregma -4.04 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
6
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 65
0
0
8 6 4 2 0 - 2 - 4
6
V2ML
V2MM
5
RSA
V1
RSG
SuG
Op
InG
Zo
1
4
V2L
InWh
DpG
DpWh
DLPAG
DMPAG
bsc
dhc
ec
2
3
2
TeA
Ect
PRh
LEnt
S
PaS
PrS
InCo
LPAG Aq
BIC
ECIC
Me5
VLPAG
Su3C Su3
DpMe
3PC
3N
mlf
MiTg
DR
PBG RRF
R CLi
scp
PPTg
mtg
ATg
PMnR
VLL
MnR ts
PnO
A8
rs
ll
bic
Mol
alv
rf
3
4
1
MEnt
PL
RtTg
IP
ml
B9
cp
bp
5
Pn
0
6
Interaural -0.36 mm
Bregma -4.16 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
6
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 66
0
0
6
5
4
3
8 6 4 2 0 - 2 - 4
V2L
TeA
V1
PrS
RSG
V2MM
BIC
ECIC
RSA
SuG
Op
InG
InWh
InCo
Zo
DpWh
DpG
DLPAG
LPAG
VLPAG
DMPAG
Aq
DR
Me5
bsc
bic
dhc
ec
alv
1
2
2
Ect
PRh
S
PaS
PBG
PL
RR
EMi
MiTg
DpMe
PPTg
3PC
3N
ATg
CLi
xscp
mlf
mtg
rf
3
4
Su3C
Su3
Pn
1
LEnt
MEnt
VLL
PMnR
PnO
RtTg RtTgP
MnR
IP
DMPn
tfp
ml
ts
B9
lfp
mcp
ll
rs
m5
5
0
6
Interaural -0.44 mm
Bregma -4.24 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
4 2 0 -2 - 4 - 6 - 8
6
Bregma
6 Bregma 0
4
2
2
4
FIGURE 67
0
0
6
8 6 4 2 0 - 2 - 4
5
4
3
2
TeA
Ect
PRh
V2L
S
V1
PrS
PaS
V2MM
PL
RSA
BIC
ECIC
EMi
MiTg
PBG
RR
DpWh
InCo
CnF
DpMe
PPTg
SuG
Zo
Op
InG
InWh
DpG
DMPAG
DLPAG
LPAG
VLPAG
RC
Pa4
4N
Aq
DR
mlf
CLi mtg
xscp
Me5
bsc
bic
dhc
alv
ec
rf
1
2
3
1
LEnt
MEnt
ILL
ERS
VLTg
VLL
PnO
PMnR
RtTgP
ATg
MnR
RtTg
DMPn
ts
B9
ml
lfp
ll
mcp
rs
m5
4
5
Pn
tfp
0
6
Interaural -0.56 mm
Bregma -4.36 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
6
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 68
0
0
6
8 6 4 2 0 - 2 - 4
5
4
3
2
1
TeA
Ect
PRh
LEnt
V2L
MEnt
V1
PrS
PaS
V2MM
RSA
EMi
PBG
PL
ILL
BIC
ECIC
MiTg
VLL
CnF
DpWh
InCo
PPTg
VLTg
RPO
PnO
SuG
Op
InG
InWh
DpG
DLPAG
LPAG
VLPAG
RC
RtTgP
Pn
Pa4
Zo
4N
DMPAG
Aq
DRD
DRV
DRI
mlf
CLi
xscp
ATg
Rbd
PMnR
MnR
RtTg
ml
DMPn
tfp
DRVL
ts
B9
lfp
Me5
ll
rs
bic
ll
mcp
m5
vsc
dhc
rf
1
2
3
4
5
0
6
Interaural -0.68 mm
Bregma -4.48 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
6
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 69
0
0
6
8 6 4 2 0 - 2 - 4
5
V2MM
SuG
Zo
1
4
V1
RSA
InG
InWh
DpG
DpWh
Op
bic
3
2
1
TeA
Ect
PRh
LEnt
V2L
Dsc
MEnt
PaS
PrS
BIC
EMi
MiTg
PBG
DLL
ILL
ECIC
PL
PL
CnF
PPTg
VLTg
RPO
InCo
DLPAG
LPAG
VLPAG
RC
PnO
SPTg
DRVL
Pa4
RtTgP
PMnR
RtTg
ATg
DMPAG
Aq
DRD
DRV
DRI
mlf
xscp
MnR
ml
ts
Me5
lfp
ll
vsc
ll
rs
PC5
vsc
mcp
m5
dhc
rf
2
3
4
5
0
Pn
tfp
6
Interaural -0.80 mm
Bregma -4.60 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
6
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 70
0
0
6
8 6 4 2 0 - 2 - 4
5
V2MM
SuG
InG Op
Zo
1
4
V2L
TeA
Ect
V1
RSA
1 2 3
ECIC
InCo
InWh
DpG DpWh
DLPAG
LPAG
DMPAG
Aq
Me5
dhc
2
3
PRh
LEnt
PaS
Sag
DLL
EMi
PL
MiTg
CnF
PPTg
VLPAG
RC
Pa4
DRD
DRVL
DRV
DRI
mlf
xscp
4n
ll
rf
3
2
MEnt
ILL
P5
PnO
SPTg
VTg
PMnR
MnR
ts
vsc
mcp
4
1
RPO
RtTgP
RtTg
rs
vsc
ll
m5
PC5
5
LVPO
MVPO
ml
lfp
0
6
Interaural -0.92 mm
Bregma -4.72 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
6
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 71
0
0
6
8 6 4 2 0 - 2 - 4
5
4
V2L
V1
V2MM
ECIC
Op
InG
InWh
DpG
Zo
SuG
cic
DpWh
DLPAG DMPAG
1
2
3
TeA
Ect
PRh
LEnt
PaS
Ant
Sag
DLL
ILL
MiTg
PL
PPTg
CnF
LPAG
VLPAG
RC
DRVL
Aq
DRD
DRV
DRI
mlf
Me5
scp
4n
ll
dhc
rf
3
RSA 1 2 3 MVPO
2
MEnt
KF
P5
SPTg
Mo5
LDTgV
Rbd
VTg
PMnR
MnR
ts
vsc
mcp
4
1
0
Pr5
PC5
LVPO RPO
PnO
Tz
RMg
RtTg
ml
lfp
m5
rs
vsc
s5
5
6
Interaural -1.04 mm
Bregma -4.84 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
6
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 72
0
0
6
8 6 4 2 0 - 2 - 4
5
1
V2MM
DCIC
cic
4
V1
ECIC
DMPAG
3
Ect
LEnt
V2L
PaS
RSA
Ant
1 2 3
Sag
CIC
CnF
MiTg
PPTg
DLPAG
LPAG
VLPAG
RC
LDTg
2Cb
Aq
DRC
Me5
4n
ll
DLL
rf
2
3
2
1
MEnt
Pr5
KF
LPB
MPB
SubCD
Su5
P5
Mo5
SubCV
PC5
RPO
LDTgV
DMTg
PnO
VTg
PMnR
RtTg
RMg
DRI
mlf
MnR
ts
scp
m5
vsc
vsc
A7
rs
mcp
VCA
s5
8vn
4
5
0
LVPO
Tz
MVPO
ml
lfp
6
Interaural -1.16 mm
Bregma -4.96 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
6
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
Figure 73
0
0
6
8 6 4 2 0 - 2 - 4
5
DCIC
1
ECIC
DMPAG
4
V1
CIC
LPAG
2
Ect
PaS
Sim
Sag
2Cb
Aq
rf
3
LEnt
Ant
1 2 3 4n
LPBV
CnF
LPBS LPBC
VLPAG
RC
LDTg
DTgP
DRC
Me5
scp
me5
ll
vsc
3
2
1
MEnt
Fl
VCA
Pr5DM
Pr5VL
KF
I5
Su5
Mo5
PC5
MPB
LPBE
SubCV
SubCD
P5
Acs5
LDTgV
DMTg
PMnR
PnC
VTg
RtTg
mlf
DRI
ts
MnR
m5
mcp
s5
8vn
4
5
0
LSO
DPO
SPO
Tz
LVPO
MVPO
PnV
ml
cst
RMg
rs
vsc
6
Interaural -1.22 mm
Bregma -5.02 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
6
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 74
0
0
6
8 6 4 2 0 - 2 - 4
5
1
DCIC
DMPAG
4
ECIC
CIC
LPAG
3Cb
2
3
2
MEnt
CnF
1 2 3 4n
V1
Ect
Sim
2Cb
PFl
Ant
KF
LPBD
LPBC
LPBV
MPB
LPBE
VLPAG
LDTg
DTgP
DTgC
4V
DRC
DRI
Me5
scp
me5
vsc
mcp
3
1
Fl
VCA
Pr5DM
I5
Pr5VL
Su5
Mo5
P5
Acs5
SubCD
DMTg
PnR
PnC
RtTg
mlf
s5
8n
4
5
0
SubCV
DPO
LSO
SPO
LVPO
MVPO
Tz
PnV
RMg
ml
lfp
vsc
rs 7n
6
Interaural -1.40 mm
Bregma -5.20 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
6
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 75
0
0
6
8 6 4 2 0 - 2 - 4
5
1
4&5Cb
4
ECIC
CIC
DCIC
3Cb
2
3
2
1
Sim
PFl
Fl
SGl
VCA
Ant
MPBE
KF
Pr5DM
Pr5VL
2Cb
LPBD LPBI LPBV
4V
LPBC
LDTg
MPB LC DTgC
Bar
LPBE
DTgP
DRI
Su5
CGB
CGA
SubCD
mlf
Mo5 DMTg PnR
P5
I5 Acs5
RtTg
PCRtA
SubCV PnC
4n
Me5
vsc
scp
me5
A5
prf
mcp
s5 8n
tz
pfs
plf
3
4
5
0
LSO
LVPO
DPO
SPO
MVPO
Tz
PnV
RPa
RMg
tz
ml
py
rs
MSO
7n
vsc
6
Interaural -1.54 mm
Bregma -5.34 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
6
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 76
0
0
6
8 6 4 2 0 - 2 - 4
5
4&5Cb
1
DCIC
pcuf
4
Sim
4&5Cb
3Cb
2
Crus1
pcn
prf
psf
Crus1
3
LPBD
LPBC
PBW
SMV
2Cb
vsc
unc
3
2
1
PFl
Fl
VCA
SGl
MPBE
PCGS
Pr5DM
PCRtA
Pr5VL
MPB
4V
LDTg Sph
Bar
LC
DTgP
CGPn
DTgC
O
CGA
DMTg
IRt
PnC
mlf
Me5
scp
me5
7n
A5
mcp
sp5 ocb
8n
tz
plf
pfs
4
5
0
DPO
LSO
LVPO
SPO
Tz
MVPO
GiA
RMg
ml
py
RPa
tz
rs
vsc
6
Interaural -1.60 mm
Bregma -5.40 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
6
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 77
0
0
6
8 6 4 2 0 - 2 - 4
5
4&5Cb
1
pcuf
4
Sim
4&5Cb
3Cb
2
Crus1
pcn
prf
psf
Crus1
3
2
1
0
PFl
Fl
VCA
SGl
Pr5DM
Pr5VL
LPBC LPBV
PCRtA
DPO
LSO
LVPO
MPB
Bar LDTg
LC
MVe
IRt
Acs6/7
SPO
MVPO
Tz
PnC
GiA
SMV
DTgP
DTgC
CGA O
Pa6
6N
2Cb
4V
Sph
RMg
mlf
ml tz
py
RPa
CGPn
me5
ocb
vsc
unc
scp
Me5
7n
A5
rs
vsc
mcp
sp5
8n
tz
plf
pfs
3
4
5
6
Interaural -1.72 mm
Bregma -5.52 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
6
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 78
0
0
6
8 6 4 2 0 - 2 - 4
5
4&5Cb
1
pcuf
4
Sim
3Cb
2
Crus1
prf
psf
3
2
1
0
PFl
Fl
Lat
DC
GrC
VCP
LVe
Pr5DM
Pr5VL
SuVe
LVPO
MVeMC
PCRtA
Sp5O
LPBV
LC
MPB
7N
CPO
MVePC
IRt
Acs7
P7
LPGi
MVPO
Bar
CGPn
EVe
Gi
6N
Pa6
PnC
GiA
PPy
SMV
PDTg
Tz
pcn
2Cb
4V
RMg
ocb
ml tz
py
RPa
mlf
7n
vsc unc
scp
Me5
rs
A5
vsc
mcp
icp
8vn
ocb
sp5
tz
8n
plf
LR4V
pfs
3
4
5
6
Interaural -1.88 mm
Bregma -5.68 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
6
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 79
0
0
6
8 6 4 2 0 - 2 - 4
5
4&5Cb
1
4
Sim
pcuf
3Cb
2
Crus1
prf
psf
3
Lat
IntA
LC
SMV
pcn
2Cb
1Cb
scp
mcp
pfs
3
2
1
PFl
Fl
SGl
DC
GrC
VCP
Sp5ODM
Sp5OVL
SuVe
MVePC
PDTg
LVe
EVe
MVeMC
IS Pa6
PCRtA
IRt
Acs7
P7
7N
LPGi
4V
CGPn
6N mlf
Gi
GiA
RMg
g7
A5
rs
icp
8vn
sp5
tz
8n
plf
LR4V
4
5
0
PPy
ml
py
RPa
vsc
6
Interaural -2.00 mm
Bregma -5.80 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
6
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 80
0
0
6
8 6 4 2 0 - 2 - 4
5
4&5Cb
1
4
Sim
pcuf
2
Crus1
3Cb
prf
psf
3
icp
mcp
pcn
2Cb
icf
3
2
1
0
Crus2
PFl
Fl
Lat
SGl
DC
GrC
VCP
Sp5ODM
Sp5OVL
IntA
Med
VeCb
SuVe
MVePC
LVe
MVeMC
IS
PCRtA
IRt
Acs7
P7
7N LPGi
SMV
1Cb
4V
Pr
mlf
Gi
GiA
RMg
PPy
RPa
prb
ml
py
g7
A5
rs
vsc
icp
sp5
8vn
tz
pfs
plf
LR4V
8n
4
5
6
Interaural -2.08 mm
Bregma -5.88 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
6
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 81
0
0
6
8 6 4 2 0 - 2 - 4
5
1
4&5Cb
4
Sim
pcuf
2
3Cb
prf
psf
3
Crus1
icp
2
1
0
PFl
Crus2
Fl
IntDL
IntA
Med
Lat
LatPC SuVe VeCb
Y
SGl Inf
LVe
MVePC
DC
GrC
VCP
MVeMC
IS
PCRtA
IRt
Sp5ODM
Acs7
Sp5OVL
P7
7DI
7DL LPGi
7L 7DM
7VI
7N 7VM
10Cb
4V
Pr
mlf
DPGi
Gi
GiA
RMg
PPy ml
py
RPa
A5
icp
sp5
tz
rs
vsc
8n
icf
pfs
plf
LR4V
3
4
5
6
Interaural -2.20 mm
Bregma -6.00 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
6
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
FIGURE 82
0
2
4
0
6
8 6 4 2 0 - 2 - 4
5
1
4
Sim
2
4&5Cb
psf
prf
Crus1
3
icp
icf
3
IntDL
IntA
Med
2
1
0
PFl
Crus2
Fl
LatPC
Lat
SGl
DC
GrC
VCP
VeCb
10Cb
PCGS
MVePC 4V
LVe
Pr
SpVe MVeMC
X
mlf
DPGi
DMSp5
IS
PCRtA IRt
Gi
Acs7
Sp5OVL
P7
LPGi
GiA
RMg
7N
ml
PPy
py
RPa
icp
sp5
rs
vsc
tz
8n
pfs
plf
LR4V
4
5
6
Interaural -2.32 mm
Bregma -6.12 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
5
6
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 83
0
0
6
8 6 4 2 0 - 2 - 4
5
1
4
Sim
2
Crus1
4&5Cb
prf
psf
3
icp
icf
3
IntDL
IntA
Med
2
1
PFl
Crus2
GrC
Lat
SGl
DC
VCP
IntP
LatPC VeCb
LVe
MVePC
SpVe
X
MVeMC
SolIM
DMSp5 SolI
PCRtA IRt
Sp5OVL
P7
10Cb
4V
Pr
mlf
DPGi
Gi
ROb
ias
sol
icp
sp5
tz
pfs
LR4V
4
5
0
7N
LPGi
GiA
PPy
RMg
ml
py
RPa
rs
vsc
6
Interaural -2.44 mm
Bregma -6.24 mm
1
5
4 3 2 1 0 1 2 3 4 5

4
3
2
1
0
1
2
3
4
4 2 0 -2 - 4 - 6 - 8
5
Bregma
6 Bregma 0
4
2
2
4
FIGURE 84
1
0
6
8 6 4 2 0 - 2 - 4
4
Sim
2
Crus1
4&5Cb
prf
psf
icf
3
MedDL
cbc
icp
3
Crus2
IntDL
Lat
IntA
IntP
Med
10Cb
ppf
2
SGl
pfs
MVePC
das
4
DC
4V
SpVe
icp
MVeMC Pr
LR4V
X SolI
sol
SolIM
mlf
10N
DPGi
sp5
1
PFl
5
VCP DMSp5
PCRtA IRt
Gi
Sp5O
ROb
P7
rs
0
7N
GiA
LPGi
RMg
ml
vsc
C1
6
PPy
py
RPa
RVL
Interaural -2.56 mm
Bregma -6.36 mm
1
4 3 2 1 0 1 2 3 4

4
3
2
1
0
1
2
3
4
5
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 85
1
0
8 6 4 2 0 - 2 - 4
6
6Cb
4
prf
psf
2
Crus1
4&5Cb
icf
3
cbc
MedDL
3
2
1
Crus2
PFl
PFl
SGl
IntDL
DC
Sp5I
IntP
MVePC
SpVe
SolDM
X SolI MVeMC Pr
PCRtA
DMSp5
IRt
Med
sol
10N
SolM
SolIM
DPGi
Gi
10Cb
4V
mlf
ROb
icp
sp5
LR4V pfs
ppf
apmf
PM
4
5
0
7N
P7
LPGi
RVL
PPy
GiA
RMg
RPa
py
ml
C1
P7
rs
vsc
6
Interaural -2.68 mm
Bregma -6.48 mm
1
4 3 2 1 0 1 2 3 4

4
3
2
1
0
1
2
3
4
5
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 86
1
0
8 6 4 2 0 - 2 - 4
6
6Cb
4
Crus1
prf
4&5Cb
psf
2
icf
3
Crus2
MedDL
Med
cbc
plf
3
IntP
apmf
2
1
0
PM
PFl
PFl
10Cb
SpVe
MVePC
SolDM
4V
X SolI
SolVL MVeMC Pr
C3
10N mlf
SolIM DPGi
SolV SolM
DMSp5
PCRt
Sp5I
IRt
Amb
Gi
ROb
Bo
LPGi GiV
ml
py
RPa
sol
RVL
C1
LR4V
icp
sp5
rs
vsc
pfs
ppf
4
5
6
Interaural -2.84 mm
Bregma -6.64 mm
1
4 3 2 1 0 1 2 3 4

4
3
2
1
0
1
2
3
4
5
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 87
1
0
6
8 6 4 2 0 - 2 - 4
6Cb
4
Crus1
prf
4&5Cb
psf
icf
2
3
Crus2
MedDL
Med
6Cb
9Cb
plf
apmf
3
2
PM
IntP
10Cb
ppf
Cop
X
SpVe
MVe
SolI
SolDM
Pr
10N
4V
C3
sol
icp
sp5
LR4V
pfs
4
1
PFl
ECu FVe CI
SolV SolM
SolVL
SolIM
DMSp5
PCRt IRt
Sp5I
Amb Gi
DPGi
mlf
ROb
rs
5
0
RVL
LPGi
GiV
IOM
IOPr
RPa
py
IOD
C1
vsc
6
Interaural -2.92 mm
Bregma -6.72 mm
1
4 3 2 1 0 1 2 3 4

4
3
2
1
0
1
2
3
4
5
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 88
1
0
6
8 6 4 2 0 - 2 - 4
4
Crus1
psf
2
6Cb
icf
3
Crus2
MedDL
3
Med
9Cb
plf
apmf
2
PM
10Cb
ppf
1
Cop
ECu
X
FVe
SpVe
MVe
SolDM
SolVL SolIM
Pr
10N
SolV SolM EF
DMSp5
DPGi
PCRt
IRt
Sp5I
Li Gi
Amb
4V
C3
CI B4
mlf
ROb
C2
sol
icp
rs
sp5
LR4V
4
5
0
RVL
LPGi
IODM
IOM
IOPr
IOD
RPa GiV
py
C1
vsc
6
Interaural -3.04 mm
Bregma -6.84 mm
1
4 3 2 1 0 1 2 3 4

4
3
2
1
0
1
2
3
4
5
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 89
1
0
6
8 6 4 2 0 - 2 - 4
4
psf
Crus1
6Cb
2
icf
3
Crus2
8Cb
3
apmf
9Cb
2
1
PM
10Cb
Cop ECu SpVe
MVe
SolI
SolDM 4V C2
10N
SolVL
Pr
FVe
In C3
SolCe 12N B4
SolM
DMSp5
Ro
SolV SolIM
CI
DPGi mlf
PCRt
IRt
Sp5I
plf
sol
icp
sp5
ppf
LR4V
4
5
0
Amb
Li
RVL
LPGi
Gi
IODM
IOD IOM
ROb
GiV
IODMC
RPa
py
C1
vsc
rs
6
IOPr
Interaural -3.16 mm
Bregma -6.96 mm
1
4 3 2 1 0 1 2 3 4

4
3
2
1
0
1
2
3
4
5
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 90
1
0
6
8 6 4 2 0 - 2 - 4
4
6Cb
2
Crus1
icf
3
Crus2
8Cb
ppf
apmf
3
2
1
PM
DMSp5
Pa5
Sp5I
Cop
9Cb
SolDL
SolI SolG
SolM
ECu
SpVe MVe
4V
10N
SolVL
SolV In 12N
SolIM
SolCe CI
Ro
PCRt IRt
Gi
mlf
sol
sp5
icp
LR4V
4
5
Amb
Li
PMn
0
LRt
RVL
LPGi
IODM
IOM
IOD
ROb
RPa
py
vsc
rs
LRtPC
6
Interaural -3.28 mm
IOPr
Bregma -7.08 mm
1
4 3 2 1 0 1 2 3 4

4
3
2
1
0
1
2
3
4
5
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 91
1
0
6
8 6 4 2 0 - 2 - 4
4
6Cb
2
Crus1
icf
3
Crus2
7Cb
8Cb
sf
ppf
apmf
3
2
1
0
Interaural -3.40 mm
PM
DMSp5
Sp5I
LRtPC
Cop
Pa5
LRt
ECu
PCRt
RVL
PSol
SolI
Cu
SolVL
IRt
SolG
SolDL
SolV In
SolCe
SolIM
Amb
LRt
IOD
IOPr
Gi
IOVL
Bregma -7.20 mm
1
4 3 2 1 0 1 2 3 4
9Cb
SolM
12
Ro
PMn
IOK
IOM
AP
4V
mlf
10N
12n
ROb
IOBe
RPa
py
sol
vsc
icp
sp5
rs
4
5
6

4
3
2
1
0
1
2
3
4
5
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 92
1
0
6
8 6 4 2 0 - 2 - 4
4
6Cb
2
3
Crus2
7Cb
8Cb
sf
ppf
apmf
3
2
1
0
PM
Pa5
Pa5
Sp5I
LRtPC
Cop
LRt
ECu
SolVL
MdD
IRt
9Cb
SolDL
PSol
SolG
SolC
Cu
SolM
AP
10N
SolV SolCe
SolIM
In 12N
Amb
IOD
IOPr
Ro mlf
ROb
MdV
PMn
IOK
IOVL IOBe
IOC
IOB
RPa
py
sol
vsc
icp
sp5
11n
rs
4
5
6
Interaural -3.52 mm
Bregma -7.32 mm
1
4 3 2 1 0 1 2 3 4

4
3
2
1
0
1
2
3
4
5
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 93
1
0
6
8 6 4 2 0 - 2 - 4
4
6Cb
2
3
7Cb
ppf
Crus2
apmf
8Cb
sf
3
PM
2
1
0
Pa5
Sp5I
Cop
LRt
ECu
SolVL
MdD
Cu
Amb
IRt
9Cb
SolDL
SolG
SolM
PSol
AP
SolC
SolIM
In
SolCe
IOD
IOPr
MdV
IOB
10N
Ro
CC
12N
ROb
IOK
IOBe
PMn
IOC
RPa
py
sol
A1
icp
vsc
sp5
rs
4
5
6
Interaural -3.68 mm
Bregma -7.48 mm
1
4 3 2 1 0 1 2 3 4

4
3
2
1
0
1
2
3
4
5
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 94
1
0
6
4
8 6 4 2 0 - 2 - 4
6Cb
psf
7Cb
ppf
2
Crus2
3
PM
8Cb
sf
apmf
3
2
1
0
C
Sp5I
Cop
Sp5C
MdD
IRt
IOB
IOD
10N
InM
9Cb
ECu
SolG
SolM
SolDL
Cu
AP
SolI
SolVL
Amb
LRt
SolV
IOA
SolIM
MdV
Ro
CC
12N
IOK
IOC
SolC
IOBe
ROb
PMn
RPa
py
sol
A1
icp
sp5
vsc
rs
4
5
6
Interaural -3.76 mm
Bregma -7.56 mm
1
4 3 2 1 0 1 2 3 4

4
3
2
1
0
1
2
3
4
5
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 95
1
0
6
8 6 4 2 0 - 2 - 4
4
7Cb
ppf
2
3
Crus2
8Cb
sf
apmf
PM
3
9Cb
2
1
0
Sp5I
Cop
Sp5C
MdD
ECu
Amb
LRt
IRt
Cu
IOA
SolI
SolVL
SolV
SolIM
SolDL
SolM
Gr
MdV
IOD
IOB
SolG
10N
SolC
InM
CC
12N
Ro
IOK
IOC
RPa
AP
IOBe
ROb
PMn
py
sol
A1
sp5
vsc
rs
4
5
6
Interaural -3.84 mm
Bregma - 7.64 mm
1
4 3 2 1 0 1 2 3 4

4
3
2
1
0
1
2
3
4
5
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 96
1
0
6
8 6 4 2 0 - 2 - 4
4
7Cb
ppf
2
8Cb
3
sf
PM
3
9Cb
2
1
0
Interaural -3.96 mm
Cop
Sp5C
SolDL
SolM
Cu Gr
AP
SolI
SolVL
10N
SolC
SolV
12N
CC
MdD
IRt
mlf
Amb MdV IOK ROb
PMn
ts
IOB IOBe
LRt
IOC
RPa
IOA
py
12n
vert
sol
cu
sp5
A1
vsc
rs
Bregma - 7.76 mm
4
5
6
1
4 3 2 1 0 1 2 3 4

4
3
2
1
0
1
2
3
4
5
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 97
1
0
6
8 6 4 2 0 - 2 - 4
4
7Cb
ppf
2
3
8Cb
sf
PM
3
Cop
9Cb
2
1
Sp5C
MdD
LRtPC Amb
SolDL
SolM
Gr gr
Cu
SolC
SolVL
10N
SolV
12N CC
IRt
mlf
MdV ROb
IOC ts
sol
cu
A1/C1
sp5
Pa5
rs
4
5
0
LRt
IOB
IOA
py
vsc
dsc
6
12n vert
Interaural -4.12 mm
Bregma -7.92 mm
1
4 3 2 1 0 1 2 3 4

4
3
2
1
0
1
2
3
4
5
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 98
1
0
6
8 6 4 2 0 - 2 - 4
4
7Cb
ppf
2
8Cb
3
sf
PM
3
Cop
9Cb
2
Sp5C
Cu
SolVL
SolV
SolM
Gr
SolC
10N
sol
cu
sp5
4
1
0
MdD
CeCv
IRt
LRtPC RAmb
MdV
LRt
IOM
12N
CC
ROb
pyx
mlf
ts
C1
vsc
rs
dsc
5
6
12n
vert
Interaural -4.20 mm
Bregma - 8.00 mm
1
4 3 2 1 0 1 2 3 4

4
3
2
1
0
1
2
3
4
5
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 99
1
0
6
8 6 4 2 0 - 2 - 4
4
2
8Cb
3
sf
3
9Cb
2
1
0
Sp5C
SolM
cu
Gr
Cu
SolC
SolVL
10N
sol
SolV
MdD
IRt
CeCv
CC
12N
mlf
RAmb MdV
ROb
LRt
pyx
ts
vsc
sp5
rs
dsc
4
5
6
Interaural -4.32 mm
Bregma - 8.12 mm
1
4 3 2 1 0 1 2 3 4

4
3
2
1
0
1
2
3
4
5
4 2 0 -2 - 4 - 6 - 8
Bregma
6 Bregma 0
4
2
2
4
FIGURE 100
1
0
6
8 6 4 2 0 - 2 - 4
4
2
3
8Cb
sf
3
9Cb
2
1
Sp5C
MdD
Cu
Gr MnA
sol
SolC
SolM
A2
cu
sp5
4
IRt
CeCv
CC
5
0
LRt
MdV
11N
mlf
pyx ts
vsc
A1
rs
dsc
6
Interaural -4.44 mm
Bregma - 8.24 mm
1
4 3 2 1 0 1 2 3 4

6
5
4
3
2
1
0
5 4 3 2 1 0 -1 -2 -3 -4 -5 -6 -7 -8
4&5Cb
RSA
RSGb
Cg1
Zo
Cg/RS
Cg1
6Cb
Mi
rf
SuG
RSGb
cic 3Cb
IPl
DCIC
cc
Gl
PrL
Cg2
Op SC
dhc
IG
df
7Cb
CA1
SCO
ReIC
DMPAG
3V vhc
prf
gcc LV
csc Aq
ppf
SMV
pcn
MO
SHi
SFO
pc
pcuf
Gl
D3V SCO
2Cb
Aq
D3V
DRD
DTT
f
PV
PVP
4V
plf 8Cb
LSI
PAG 3N DRV
1Cb
sf
MS
IMD
DRI DTgP
PT
Sph
dtgx
4V
EPl
CM
EW CLi xscp DTgC
PVA
RLi
PDTg
Ld
pv
mlf
10Cb
9Cb
ac
IAM
SolC
vtgx
Rbd
Pr
Rh
10N Gr
PaAP
3V sumx MnR CGA
In
VDB MnPO
Re
IF
ocb
ICj
DPGi
12N
PH
IPA
PaV
IPR
gr
PaMP
RtTg
SuMM
mlf
IPC
Gi
VOLT
IPF
PnC
MMn MM
RtTg
3V
ml PnV
pyx
GiA
ox
Pn tz
GiV
RMg
IO
tfp
py
sox
ME ArcMP Interaural RPa
Figure 101
9 8 7 6
5
4
3
2
1
0 -1 -2 -3 -4
Interaural
Lateral -0.04 mm
Bregma
Bregma
0
1
2
3
4
5
6

6
5 4 3 2 1 0 -1 -2 -3 -4 -5 -6 -7 -8
Bregma
Bregma
0
5
4
3
2
1
0
GrO
EPl
RSA
4&5Cb
Cg1
Cg/RS
IPl
RSGb
prf
rf
Cg1
Mi
SuG
Zo
RSGb
6Cb
cic DCIC
dhc
SC
scc
3Cb
PrL
ReIC
Cg2
cc
psf
CA1
df
DMPAG
DG
SCO csc
7Cb
IG
vhc MHb
D3V
MO
LSD SFO
pc
Aq
q SMV
ppf
gcc
pcn pcuf
Gl
TS
PrC
LDTg
8Cb
DP
PVP
3PC
2Cb
DR
plf
EPl
LSI
DTT
PV
Dk 3N 4N DTgC
1
sf
MDM
mlf
DTgP
SHi MS f PT
9Cb
MA3
dtg
Sph chp 10Cb
PVG
Mi
PVA
CM
RLi scp
PDTg
VTg
ac
Gus
VTT
MnPO
vtgx
Pr SolG
IAM
PaAP
Rh
CLi
ATg
In 10N SolM
Gr
ADP PaDC
IF
IPA CGA
VDB
Re sumx
PMnR
RtTg
DPGi Ro 12N
AC
IPR
PaLM
SolC
ICj
PH SuMM
IPC RtTgP
gr
PaV
AVPe
DTM
IPF
PnC Gi
PMn
MPOM
DM
MM
PaMM PaPo
RtTg
VMPO MPA AHC
VMHDM
tfp Pn ml PnV
GiA
GiV
pyx
SCh
TC
RMg
IO
PMD
ox
Tz tz
py
Arc
Interaural
sox
Figure 102
9 8 7 6
5
4
3
2
1
0 -1 -2 -3 -4
Interaural
Lateral 0.12 mm
3V
1
2
3
4
5
6

6
5
4
3
2
1
0
GrO
Interaural
5 4 3 2 1 0 -1 -2 -3 -4 -5 -6 -7 -8
Mi
IPl
EPl
Gl
Gl
Lateral 0.24 mm
rf
EPl
IPl
Mi
GrO
Bregma
4&5Cb
RSA
Zo
M2
6Cb
SuG
Cg1
Cg/RS
RSGb
Op DCIC
InG cic 3Cb
PrL
cc scc RSGa InWh
DpG
Cg2
psf
DpWh
CA1
7Cb
hf
DG
DMPAG
IG
MPT
prf
LSD
vhc
ppf
3V
MHb
pcn pcuf
MO IL gcc LV
LHbM
PrC pc
fr
MA3
MO
PV
Su3 DRV
2Cb
plf sf
DTT
TS 3V
DP
LSI
PF
3N 3PC 4N DRVL
Pa4 LDTg
DTr
MDM PF Dk
CLi
4V
DTgP
DTT
PT
mlf
10Cb
MS PVA
DTgC
9Cb
f IAM
scp
VTg
CM
MVePC
Rh
InC R
SolM
ATg
Gus MVeMC 10N Gr
SPF
ac
RI
DMTg
Re Sub
vtgx
6N
VTA PMnR
12N
PaDC
VTT
PaLM
mtg fr
DPGi
SolC
ADP
VRe
PN
Ro
AcbSh
PaAP
VDB
PaPo PH
SuM IPL
MPA PaMM
PMD
IPF
PnC Gi PMn
MPOM AHP
AHA AHC DM
ML
RtTg
MPA
Tu
MM
Pn
IOD
tfp
PnV ml
GiV
LA TC VMH
lfp Tz GiA
IOPr
ox
Arc
tz py
sox
PMV
Interaural RMg Figure 103
9 8 7 6
5
4
3
2
1
0 -1 -2 -3 -4
Bregma
0
1
2
3
4
5
6

6
5
4
3
2
1
0
Gl
GrO
EPl
Mi
IPl
Interaural
5 4 3 2 1 0 -1 -2 -3 -4 -5 -6 -7 -8
IPl
Mi
EPl
Gl
Lateral 0.36 mm
IPl
rf
Mi
FrA
GrO
Bregma
RSA
M2
SuG
Cg/RS
RSGa
Op
InG
DCIC
6Cb
RSGb
scc
InWh
cic
Cg1
DpG
3Cb
cc
CA1
CA2
Py S
DpWh
Cg2
df Mol
Rad
DLPAG
prf psf
LMol
GrDG
7Cb
hf MHb
PrL
PoDG
MPT DLPAG
LSD
2Cb
ppf
vhc
PCom
LPAG
3V
MHb
pcn
gcc
pcuf
MHb
VLPAG
D3V
LHbM PrC pc LPAG
Med
8Cb
MO IL
MCPC Su3C DRV
3V sm MDC
sf
PF
Su3
plf
mlf Pa4
DP
LDTg
TS
IAD MD PF
Dk
4V 10Cb
InC
9Cb
DTT
LSI
SFi
PT AM
scp
fr
RMC
CGPn
f
MVePC
sol
Rh CM
SPTg
Gus
RPC
SolIM
Sub
MVeMC
Cu
AOM
ac
RI
DMTg
SHy B Re
PBP
VM
PMnR
g7
SolM 10N
IRt
ICjM
ST SPF VTA
PnO 6N
StA
mtg
PN
DPGi
cu
VTT AcbSh
PaLM VRe
M
PaPo PH
RtTgP
P SuM IPL
Pa6
VP
M
PMD
IPF
ML
PnC
Gi
HDB MPA
RtTg
MdV
Tu
AHA AHCAHP DM
MM
tfp
LPGi
MPOM
Pn lfp
GiV IOD
LA VMH
ml
IOPr
GiA
ox
py Tz
tz
sox
PMV
9 8 7 6
5
4
3
2
1
0 -1 -2 -3 -4
Zo
4&5Cb
Interaural Figure 104
Bregma
0
1
2
3
4
5
6

6
5
4
3
2
1
0
GrO
5 4 3 2 1 0 -1 -2 -3 -4 -5 -6 -7 -8
IPl
Mi
EPl
Gl
EPl
Mi
Interaural
Lateral 0.48 mm
IPl
FrA
Bregma
RSA
Zo
4&5Cb
M2
SuG
RSGa
6Cb
Cg/RS
Op
DCIC
InG
alv scc
InWh DpG
3Cb
Cg1
cc
Rad
cic
CA2 CA1 S
DpWh
psf
Cg2
hf
PrL
CA3
LMol
7Cb
PoDG
DLPAG
Mol
prf
MO
gcc
vhc
OPT PPT
bsc
LPAG
2Cb
pcuf
ppf
3V
pcn
D3V LSD
PrC PCom
8Cb
LHbM
sf
VO IL
sm
MCPC
VLPAG
Med
fr RPF
Su3C DRV
LSI
plf
MDL
DP
MDL
DpMe
Pa4
3V
LDTg
9Cb
IAD
InC
4V
SCom
chp 10Cb
scp
DTT
BSTMABAC
3V
MDCCM
PF
AM
RMC
MVePC
LSV
scp
PC
RPC
CGPn
sol
SPTg
SolM
Re
Gus
Cu cu
AOM ICjM ac f
VL
VM
RI
ts
DMTg MVeMC
SolIM
SHy
g7
SolV
SPF
RRF/A8
6N
StA
ZI
VTA
PnO
IRt
AMV
AOV AOP AcbSh
PS
VP
mt
PaPo
ml RtTgP
asc7
Pa6
MPA
PH SuM IPF
StHy
RtTg
PnC
Gi
BSTMP
PMD
Tu
VTT
HDB
LPO BSTMPM AHP
ML
MdV
AHA AHC DM
tfp lfp
LPGi
Pn ml
GiV
LA VMH PMV
GiA
IO
py
ox
MM
Tz
VLPO
tz
sox MTu
Interaural Figure 105
9 8 7 6
5
4
3
2
1
0 -1 -2 -3 -4
Bregma
0
1
2
3
4
5
6

5 4 3 2 1 0 -1 -2 -3 -4 -5 -6 -7 -8
Bregma
6
RSA
V2MM
Zo
4&5Cb
Bregma
0
5
4
3
2
1
0
EPl
Mi
IPl
Gl
Interaural
GrO
Lateral 0.60 mm
FrA
AOB
AOM
Pir
AOE
AOV
VO
DTT
AOM
VTT
AOP
RSGa SuG DCIC
6Cb
Op
alv
ECIC
M2
InG
scc
cc
Or
InWh
CA2
Rad Py
bsc
S
DpG DpWh CIC
LMol
3Cb
SLu
psf
Mol
CA1
DLPAG
CA3 PoDG hf
prf
GrDG
LPAG
Cg1 gcc
fi
LHb OPT PPT
pcuf
pcn
ppf
LPAG VLPAG
LV
PrL
AD
Cl
MCPC
SMV 2Cb
LSD
Med
sf
PF InC
CPu
plf
IAD MDL
DP
3V
Pa4
4V chp
RPF
10Cb
RRF/A8
LS
scp LDTg
PSol
sm
AM PC
RMC
MVePC
E/OV
BSTMPM
CGPn
sol
cu
VL
ICjM BSTMA
VPMGus
RPC
SPTg
AMV
RI
MVeMC
Cu
AcbC
ac
VM SPFPC
PnO
SolM
7n
SolV
PR
StA
Rt
PS
f ZI
mt
RtTgP DMTg IRt SolIM
VTA ml
asc7
AcbSh
A13
BSTMPI
mt SNC
VP
PaPo PH SuM
RtTg
PnC
LPO StHy
BSTMPL
IPF
MdV
HDB MPA AHAAHC AHP DM
ML
lfp
Gi
Tu
RPO
LA
VMHC
tfp Pn
LPGi
PMV
tz Tz SPO
GiV
VMHVL
VLPO ox
py GiA
MTu
PMD
IO
sox
MTu
MVPO
Interaural Figure 106
9 8 7 6
5
4
3
2
1
0 -1 -2 -3 -4
7Cb
9Cb
8Cb
1
2
3
4
5
6

6
5
4
3
2
1
0
5 4 3 2 1 0 -1 -2 -3 -4 -5 -6 -7 -8
Gl
EPl
Mi
IPl
Interaural
AOB
GrO
Lateral 0.72 mm
AOE
rf
FrA
AOM
aci
AOV
VO
AOP
Pir
DTT
Bregma
V2MM
M2 RSA
Zo
RSGb
4&5Cb
M1
SuG DCIC
alv
6Cb
RSGa
M2
Op
ECIC
Or
InG
cc
Py
InWh
CA1
CA2 Rad
LMol S
DpG CIC 3Cb
SLu
psf
Mol
bsc
DpWh
cg
hf
7Cb
GrDG
DLPAG
prf
pcuf
LV
Me5
LPMR
ppf
pcn
CL
Cl
APT
LPAG
8Cb
AD
OPT
CPu
fi
PPT
VLPAG 2Cb
MDL
Med
IVF
DpMe
LDTg
sf
MPB
plf
3V
PF
AVDM PC
RRF/A8
4V
scp
10Cb
BSTLD AM
VL OPC
Bar
BSTMPM
VPM SPFPC R
MVePC SpVe
9Cb
LDTgV
cu
BSTLP sm
Gus scp
SPTg
sol Cu
AcbC ac
Rt VM
MVeMC
FF
ml VTA
DMTg
7n
BSTMV
PnO
BSTMPI
Fu
IRt
SolIM
ZI A13
ns
RtTg
SolM
Gem
BSTLV
SNC
RtTgP
AcbSh
f
VP LPO
LV
PnC
SolVL
BSTMPL
SuML tfp lfp DPO
Gi
VP
MdV
MPA LH PeF
LH
f LM
P7
Tu HDB
Pn RPO
PMV APit
Tz SPO 7N LPGi
VMH
tz
ox
C1 IO
VLPO
MTu
sox
MTu
MVPO
Interaural Figure 107
9 8 7 6
5
4
3
2
1
0 -1 -2 -3 -4
Bregma
0
1
2
3
4
5
6

Lateral 0.84 mm
4V
LV
SpVe
LV
LV
M2
M1
cc
VO
rf
Cl
VA
Rt
ac
Pir
Tu
ox
CPu
fmj
alv
Or
S
Py
CA2
Rad
hf
Mol
LMol
CA1
PoDG
bsc
sox
psf
fi
VPM
PC
LDDM
AcbSh
VP
SNR
sp5
Sp5C
ppf
ECIC
LPMR
GrDG
RSG
V2MM
3Cb
Gl
FrA
MDL
InWh
IntP IntP
LPGi
EPl
CA3
InG
V2ML
OT
APT
7n
MVePC
7N
C1
PPT
CIC
Op
LRt
8Cb
6Cb
RPO
P7
GrO
Mi
IPl
AcbC
LH
ml
VL
SLu
SuG
DpG
SPTg
SPO
DPO
MVPO
MVeMC
DpWh
pcuf
10Cb
MedDL
7Cb
aca
AVVL
cp
RRF/A8
SubD
SubV
scp
MPB
Cu
IRt
AOV
AOD
AOP
HDB
PaR
OPT
Zo
tfp
PnO
2Cb
VeCb
PSTh
AOE
GrA
cg
MPtA
BSTLD
BSTLP
BSTMPL
AVDM
VM
SO
MTu
LM
F
RMC
Gus
DpMe
MdV
4n
prf
sf
9Cb
plf
aci
Fu
BSTLV
OPC
CL
SuML
Pn
LPO
AD
VTA
lfp
VLTg
Me5
LC
DCIC
4&5Cb
pcn
GlA
E/OV
dlo
MiA
EPlA
E/OV
E
ICj
mfba
st
sm
BSTMPM
VLH
f
PeF
VMHVL
A13
scp
PBP
MT
SNC
ll
Tz
AM
BSTLI
BSTMPI
PF
SPFPC
M2
LPAG
Me5
PnC
Gi
Li
Sol
sol
IO
cu
ECIC
ZI
5 4 3 2 1 0 -1 -2 -3 -4 -5 -6 -7 -8
0
1
2
3
4
5
6
0
1
2
3
4
5
6
0
Interaural
Bregma
Interaural Figure 108
1
2
3
4
5
6
7
8
9 -1 -2 -3 -4
Bregma

5 4 3 2 1 0 -1 -2 -3 -4 -5 -6 -7 -8
0
1
2
3
4
5
6
0
1
2
3
4
5
6
0
Interaural
Bregma
Interaural Figure 109
1
2
3
4
5
6
7
8
9 -1 -2 -3 -4
Bregma
Lateral 0.96
LV
LR4V
SpVe
LV
LV
M2
M1
fmi
cc
VO
rf
Cl
VA
Rt
ac
Pir
lo
Tu
ox
CPu
fmj
alv
Or
S
Py
CA2
Rad
hf
Mol
LMol
CA1
bsc
ZI
sox
psf
SI
fi
VPM
Po
LDDM
AcbSh
VP
SNR
sp5
Sp5C
ppf
ECIC
LPMR
GrDG
RSG
V2MM
3Cb
Gl
FrA
SNC
InWh
IntA IntP
LPGi
EPl
CA3
InG
V2ML
OT
APTD
7n
MVePC
LPB
Mo5
7N
PCRt
C1
PPT
InCo
CIC
CnF
Op
ll
LRt
PCRtA
8Cb
6Cb
RPO
P7
ON
GrO
Mi
IPl
AcbC
LH
ml
VL
SLu
SuG
DpG
PPTg
SPO
DPO
MVPO
MVeMC
DpWh
pcuf
10Cb
MedDL
7Cb
SubI
aca
AVVL
cp
RRF
SubCD
SubCV
scp
MPB
Cu
IRt
MdD
AOV
AOD
AOP
HDB
mfb
Ang
PaR
OPT
Zo
Sol
tfp
PnO
2Cb
VeCb
PSTh
AOB
AOE
GrA
cg
MPtA
BSTLD
BSTLP
BSTMPL
AVDM
VM
SO
MTu
LM
F
RMC
Gus
DpMe
MdV
4n
prf
sf
9Cb
plf
ac
aci
aci
Fu
BSTLV
ns
OPC
CL
SuML
Pn
LPO
AD
MT
VTA
lfp
VLTg
Me5
vsc
LC
DCIC
Acs5
me5
ac
RSA
4&5Cb
pcn
st
SPFPC
PBP

LV
LR4V
SpVe
LV
LV
M2
M1
fmi
cc
VO
rf
Cl
VA
ic
st
Rt
DEn
acp
Pir
lo
Tu
IPAC
opt
CPu
fmj
alv
Or
S
Py
CA2
Rad
hf
Mol
LMol
CA1
PoDG
bsc
ZI
sox
psf
SI
fi
S1Tr
Sp5I
VPM
Po
LDDM
AcbSh
VP
SNR
V2MM
sp5
Sp5C
ppf
ECIC
LPMR
RSA
GrDG
RSG
V2MM
LPtA
3Cb
Gl
FrA
SNC
InWh
IntA
IntP
LPGi
EPl
CA3
InG
V2ML
OT
APTD
7n
MVePC
LPB
Mo5
7N
PCRt
C1
PBP
PPT
InCo
CIC
CnF
Op
ll
LRt
Su5
PCRtA
8Cb
6Cb
RPO
P7
ON
GrO
Mi
IPl
AOE
AcbC
LH
ml
VL
Eth
SLu
SuG
DpG
PPTg
CVL
LSO
DPO
LVPO
MVeMC
DpWh
pcuf
10Cb
MedDL
7Cb
SubI
aca
AVVL
cp
RRF
SPFPC
SubCD
SubCV
scp
MPB
Cu
IRt
MdD
AOV
AOD
AOP
HDB
mfb
Ang
APTV
PaR
OPT
Zo
Sol
tfp
PnO
me5
2Cb
Med
VeCb
PSTh
dlo
MiA
GlA
AOE
GrA
cg
MPtA
ICj
ICj
BSTLJ
BSTLD
BSTLP
BSTMPL
AVDM
VM
SM
SO
MTu
Te
VTM
LM
F
RPC
RMC
Gus
DpMe
MdV
4n
vsc
prf
sf
9Cb
plf
Pn
4&5Cb
Me5
5 4 3 2 1 0 -1 -2 -3 -4 -5 -6 -7 -8
0
1
2
3
4
5
6
0
1
2
3
4
5
6
0
Interaural
Bregma
Interaural Figure 110
1
2
3
4
5
6
7
8
9 -1 -2 -3 -4
Bregma
Lateral 1.08 mm

6
5
4
3
2
1
0
5 4 3 2 1 0 -1 -2 -3 -4 -5 -6 -7 -8
Bregma
Bregma
S1Tr LPtA V2MM V2ML
V2MM
4&5Cb
S1HL alv
RSG RSA
fmj Zo
M1
Post
6Cb
CA1
SuG
cc
Rad
Op
M2
CA2 LMol
CIC
FrA
S
SLu Mol
InG
GrDG
EPl GrO
LV
OT InWh
LV
psf
AOB
PoDG
fmi
CA3
bsc PPT
pcuf
Mi IPl
7Cb
DpG
APTD OPT
DpWh ECIC 3Cb
VO
fi
LPMR
InCo
MedDL
Gl
Cl
LD
CnF
ppf
ON
AOE
2Cb IntA
AOD
AVVL
MiTg
vsc
CPu
IntP
Ang Po APTV DpMe
Med
LPB scp
8Cb
PPTg
AOL
st
VeCb 10Cb
Pir
VL
me5
LVe LR4V
AOV
ic Rt
VPM
Eth
PaR
MPB
sp5
MVePC
DEn
VPL
SPFPC
Su5
rf
SpVe Cu
ml RRF
AOP
IPAC
SubCD MVeMC
PBP
Ge5
aci
acp
lo
ZI
Sp5I
SNC
PnO Mo5
Sol
aca
P5
Pir
PCRtA
Sp5C
AcbC
SNR
PCRt
ns
MdD
LV SubI
cp SubCV
ll
7n
VP
PSTh
AcbSh
SI mfb MCLH
P7 IRt
IRt
RPO DPO
Amb
tfp Pn
LH
CVL
C1
HDB
opt
7N
Tu
tz LSO
LPGi LRt
SO sox
Interaural
LVPO
Lateral 1.20 mm
Interaural Figure 111
9 8 7 6
5
4
3
2
1
0 -1 -2 -3 -4
0
1
2
3
4
5
6

6
5
4
3
2
1
0
5 4 3 2 1 0 -1 -2 -3 -4 -5 -6 -7 -8
ON
Interaural
EPl
Mi
Gl
GrO
Lateral 1.32 mm
IPl
dlo
rf
FrA
AOE
lo
AOB
M2
AOL
Pir
LO
DEn
aca
Cl
Bregma
S1Tr LPtA
V2MM V2ML
V2MM
S1HL
4&5Cb
alv
RSG
prf
Or
RSA
fmj
6Cb
Py
M1
CA1
Post
hf
Rad
SuG
LMol
CA2
Op
cc
Mol S
SLu
GrDG
ECIC
CIC
InG
psf
LV
bsc
LV
InWh DpG
CA3 PoDG OT
InWh
PPT
pcuf
fmi
LPMR
7Cb
LDVL
3Cb
fi
APT
InCo
MedDL
CnF
AVVL
CPu
4n IntA
ppf
Po
MiTg vsc
st
IntP
Eth
LPB
DpMe
scp
VL
10Cb
8Cb
Rt
VPM
PPTg MPB MVePC LR4V
LGP ic VPL
SPFPC REth RRF/A8
LVe
Su5
ECu
ml
IPAC
SpVe
sp5
ZID PBP
SubCD MVeMC
Sp5I
rs
acp
P5 Mo5
aca
ZIV
SNC
Sp5C
SNR
PCRt
AcbC
LV
ll
PCRtA
MdD
STh
cp
VP
VLL SubCV
AcbSh
SI MCLH cp
7n
IRt
A5 P7 IRt
LH
mcp RPO
Amb
CVL
opt
DPO
C1
sox
tz
Tu
MCPO
LSO 7N
LPGi LRt
SO
LVPO
Interaural Figure 112
9 8 7 6
5
4
3
2
1
0 -1 -2 -3 -4
Bregma
0
1
2
3
4
5
6

6
5
4
3
2
1
0
5 4 3 2 1 0 -1 -2 -3 -4 -5 -6 -7 -8
ON
Interaural
EPl
Mi
Gl
GrO
IPl
dlo
Lateral 1.44 mm
rf
FrA
AOE
lo
AOL
M2
LO
Pir
Bregma
S1Tr LPtA
V2MM V2ML
S1HL
V2MM
alv
Or
RSG
M1
fmj
Py
CA1
RSA ECIC
CA2 Rad
Post
6Cb
LMol
SuG
cc
hf
S
Op
Mol
SLu
GrDG
InG
LV
InWh CIC
LV
psf
CA3
OT
DpG
prf
LPLR bsc
PPT
InWh
fmi
LDVL
fi
LPMR
InCo
pcuf
7Cb
3Cb
Cl
APT
MedDL
CnF vsc
CPu
st
Po
IntA
ppf
MiTg
VL
DpMe
IntP
ic
Eth
PPTg LPBE
Rt
10Cb 8Cb
PoT
VPL VPM
MVe LVe LR4V
ml REth
MPBE
DEn
PPTg Su5
sp5
IPAC LGP
ZID
LatPC
SpVe X
MVeMC
B
Sp5I
aca
ZIV
rs Mo5
AcbC
SNR
Sol
acp
ll
Ge5
ns
STh SNC
VLL
DMSp5
LV
PCRtA PCRt Sp5C
LAcbSh VP
MCLH
SI
cp
ll
LH
RPO 7n
IRt
mcp
P7 CVL
opt
DG
DPO 7N C1
Tu MCPO
sox
tz LSO
LRt
LPGi
SO
LVPO
Interaural Figure 113
9 8 7 6
5
4
3
2
1
0 -1 -2 -3 -4
Bregma
0
1
2
3
4
5
6

6
5
4
3
2
1
0
5 4 3 2 1 0 -1 -2 -3 -4 -5 -6 -7 -8
EPl
Gl
Interaural
Lateral 1.56 mm
FrA
rf
lo
M2
AID
AIV
LO
Pir
Bregma
PtA
S1Tr
V2ML V1
V2ML
alv
S1HL
V2MM
Or
6Cb
RSA
Py
M1
Rad fmj
CA2
CA1 Post
RSG
LMol
ECIC
psf
S
cc
hf Mol
Zo
Op
icf
LV
LV
InG CIC
CA3
PoDG
bsc
OT
prf
apmf
fmi
fi
LPMR PPT InWh
LDVL LPLR
InCo
3Cb
Cl
st
Po APT
CnF
IntA
CPu
MiTg vsc
DpMe
ic Rt
IntP
ppf
LPBE
SuVe
PPTg
VPL
VPM
PoT
PIL
LVe LR4V 8Cb
LPBD
LGP eml
PL
MVe DC
IPAC
ZID
Su5
DEn
B
ERS
SpVe X
sp5
ZIV
SNR
LatPC
B
acp
MGP
STh SNC
VLL
ll
PC5
PCRtA
Sp5I
LSS
m5 DMSp5
Sp5C
SI B
cp
RPO
sox LV
LAcbSh VP
Pr5VL
mcp ll
PCRt
opt CA3
7n P7
mfb MCPO
A5
AAV
tz rs
AHiPM
7N
RVL LRt
Tu
SO
C1
LRtPC
Interaural Figure 114
9 8 7 6
5
4
3
2
1
0 -1 -2 -3 -4
Bregma
0
1
2
3
4
5
6

6
5
4
3
2
1
0
Interaural
5 4 3 2 1 0 -1 -2 -3 -4 -5 -6 -7 -8
Gl
EPl
Lateral 1.68 mm
M2
FrA
rf
AID
AIV
lo
Pir
LO
S1
M1
Cl
DEn
Tu
fmi
LV
CPu
IPAC
LAcbSh
mfb
acp
Bregma
S1Sh
S1ShNc
S1HL
cc
ic
LGP
B
B
LV
fi
st
Rt
VPL
MGP
S1Tr
cp
SI B
sox
VP
LV
opt
AHiPM
MCPO AAD MeA
MePV CA3
LOT
AAV
ll A7
SpVe icp
8n
LatPC I5
x
sp5
VLL
LR4V
PC5 Pr5DM DMSp5 Sp5I
mcp m5
Pr5VL
PCRtA PCRt
7n
tz
RVL
7N
Interaural Figure 115
9 8 7 6
5
4
3
2
1
0 -1 -2 -3 -4
CA2
CA3
LDVL
VPM
PtA
alv
Or Py
Rad
LMol CA1
Mol
PoDG GrDG
bsc
LPLR OT
LPMC
ZIV
STh
V2ML
APT
Po
ZID
PP
SNC
GrDG
S
PIL
hf
fmj
SNR
V1
InG
Post
InWh
DpMe
RSG
V2MM
MiTg
RR
V2ML
RSA
BIC
ECIC
prf
Sim
Sag
ll
3Cb
IntA
vsc
IntP
LPBE SuVe Y
LVe
KF MVe DC LR4V
C1
psf
LRtPC
icf
Crus2
Ge5
Sp5C
apmf
ppf
Cop
PM
Bregma
0
1
2
3
4
5
6

6
5
4
3
2
1
0
Interaural
5 4 3 2 1 0 -1 -2 -3 -4 -5 -6 -7 -8
Gl
FrA
Lateral 1.80 mm
rf
M2
AID
AIV
lo
Pir
S1
LO
M1
Cl
DEn
Tu
LV
Bregma
S1HL
S1FL
S1Sh
S1ShNc
cc
LV
BAOT
S1Tr
CA2
LR4V
DC DC
icp
8n X
ocb sp5
Interaural Figure 116
9 8 7 6
5
4
3
2
1
0 -1 -2 -3 -4
SLu
PtA
V2ML
alv
Py Or
Rad CA1
LMol
Mol
GrDG
PoDG
S
V1
fmj
hf Op
Post
V2MM
RSA
RSG
ECIC
fmi
fi LDVL LPLR bsc
InWh
LPLC DT
st
Po
SG
str
BIC
ll
CPu
MGM
SubB MiTg
Rt VPL VPM
DLL 3Cb
PIL
RR
ic
PP SNL ILL
LGP
ZID
KF
Pr5DM
ZIV
IPAC
SNC
VLL vsc
MGP STh
B
SNR
LatPC
acp
sox LV cp
SI
LR4V Pr5VL
m5
opt Or
mcp
LAcbSh VP
MeAD
CA3
MePD AHiPM
AAD
GrDG
mfb MCPO
MeAV
tz
AAV
MePV
LOT
PMCo
Sim
Y
Sp5O
sp5
prf
IntA
IntP
Sp5I
LRtPC
psf
Crus1
icf
rs
Crus2
Cop
Sp5C
apmf
ppf
PM
Bregma
0
1
2
3
4
5
6

6
5
4
3
2
1
0
Interaural
5 4 3 2 1 0 -1 -2 -3 -4 -5 -6 -7 -8
Lateral 1.92 mm
M2
AID
rf
AIV
lo
LO
M1
S1
Cl
DEn
Pir
Tu
LV
fmi
CPu
Bregma
S1HL
S1Sh
S1ShNc
S1FL
LGP
cc
ic
LV
st
Rt
fi
Interaural Figure 117
9 8 7 6
5
4
3
2
1
0 -1 -2 -3 -4
S1Tr
VPL
alv
Or
Py
Rad CA1
CA2 LMol
SLu
ZIV
IPAC
MGP STh
B
acp
cp
sox LV
LSS
SI
opt
CA3
LAcbSh
MeAD
MePD AHiPM
VP MCPO AAD
MePV
AAV LOT
PMCo
BAOT
CA3
LDVL
Mol
S
PoDG
LPLR GrDG
bsc
LPLC SG
Po str
MGD
VPM
V2ML
PtA
SNR
V1
fmj
hf
SC
BIC
MGV
SubB
PIL
SID PP SNL
Mol
Post
RR
VLL
LatPC
ll
V2MM
LR4V
m5
mcp
RSG
ll
MiTg
DLL
ILL
ECIC
vsc
Pr5DM
Pr5VL
RSA
3Cb
sp5
tz
8n
Sp5O
Sim
prf
Y
PCGS
Lat
LatPC
X
sp5
Crus1
psf
DC
LR4V
Sp5I
icf
Cop
Crus2
apmf
PM
ppf
Pa5
Sp5C
Bregma
0
1
2
3
4
5
6

6
5
4
3
2
1
0
Interaural
5 4 3 2 1 0 -1 -2 -3 -4 -5 -6 -7 -8
Lateral 2.04 mm
M2
rf
AID
AIV
lo
Bregma
S1Tr
S1BF
S1Sh
S1ShNc
S1 V2L
alv
S1FL
Or
Py
M1
Rad fmj
RSA
CA2 LMol
cc
S
SLu Mol
Post
LV
CA3
S1
PoDG
bsc
hf
fi LDVL
DG
bic
fmi
DLG
st
MiTg
Po
MGD
Cl
BIC
CPu
str
ll
VPM MGV
LO
DLL
Rt
PIL SubB
ic VPL
ILL
SubG PP
LGP
SNL PBG
DEn
ZIV
VLL
MGP
IPAC
cp
SNR
Pr5DM
B
LSS
sox alv
Or
acp
SI
Pir
opt
Py
LV
Mol mcp Pr5VL
LAcbSh VP
Rad
CeM
GrDG
MePD CA3 PoDG
MCPO AAD
AHiPM
MeAD
tz
AAV
MePV
LOT MeAV
PMCo
Tu
Interaural Figure 118
9 8 7 6
5
4
3
2
1
0 -1 -2 -3 -4
V1
8n
Sim
icp
sp5
sp5
prf
Sp5O
Lat
LatPC
Y
DC
psf
icf
chp
Sp5I
Crus1
apmf
ppf
Cop
Sp5C
Crus2
PM
Bregma
0
1
2
3
4
5
6

6
5
4
3
2
1
0
Interaural
5 4 3 2 1 0 -1 -2 -3 -4 -5 -6 -7 -8
Lateral 2.16 mm
M2
AID
rf
AIV
lo
M1
LO
S1
Cl
DEn
Pir
fmi
Tu
LSS
CPu
Bregma
S1FL
IPAC
acp
S1Tr
S1BF
S1Sh
S1ShNc
LGP
MCPO
AAD
AAV
SI
LOT
cc
B
CeM
ic
LV
CA3
st
BMA
ACo
Rt
fi
MGP
Interaural Figure 119
9 8 7 6
5
4
3
2
1
0 -1 -2 -3 -4
VPL
str
sox
opt
LV
MePD
PLCo
S1
DLG
SubG
ZIV
AHi
V2L
CA2
Py
SLu
PMCo
Or
alv
Rad
CA1
LMol
Mol
bsc
MGD
MGV
PP
cp
Or
Py
Rad
V1
S
hf
GrDG
fmj
SubB
DG
Mol
GrDG
Post
bic
mcp
RSA
4&5Cb
3Cb
Pr5
ocb
sp5
tz
Sim
prf
icp
DC
VCA
VCP
8n
Lat
LatPC
Crus1
psf
icf
Cop
Sp5I
Crus2
apmf
PM
Bregma
0
1
2
3
4
5
6

6
5
4
3
2
1
0
Interaural
5 4 3 2 1 0 -1 -2 -3 -4 -5 -6 -7 -8
Lateral 2.28 mm
M2
AID
rf
AIV
M1
LO
lo
DI
S1
Cl
DEn
Pir
ICj
fmi
Tu
LSS
CPu
CxA
Bregma
S1FL
IPAC
acp
VEn
CeC
BMA
ACo
cc
CeM
S1DZ S1BF S1
Interaural Figure 120
9 8 7 6
5
4
3
2
1
0 -1 -2 -3 -4
LV
chp
BMP
PLCo
MePD
I
CA2
SLu
LV
AHi
V2L
CA3
Py
PMCo
Or
alv
Rad
LMol
Mol
fi bsc
GrDG
st
DLG
ic str
MGD
VPL
Rt
IGL MGV
VLG
PP
LGP
SubG ZI
Or
sox cp
B
Py CA3
st
opt
Rad
S
V1
fmj
hf
Post
GrDG
PoDG
RSA
mcp
sp5
tz
8n
prf
Sim
VCA
LatPC
VCP
Lat
DC
psf
icf
Crus1
ppf
Cop
apmf
Crus2
PM
Bregma
0
1
2
3
4
5
6

6
5
4
3
2
1
0
Interaural
Lateral 2.40
5 4 3 2 1 0 -1 -2 -3 -4 -5 -6 -7 -8
rf
M1
AID
S1
AIV
S1J
lo
GI
DI
Cl
DEn
S1ULp
Pir
Tu
fmi
Bregma
S1FL
CxA
S1BF
cc
S1
LV
CA3
st
V2L
CA2
SLu
Rad
LMol
IGL
DLG
bsc
alv
Mol
CA1
Mol
ic
CPu
Rt VLG MG
Mol
LGP
SubG Or
sox
Py
CA3
st opt
LSS IPAC
B
SLu Rad PoDG
CeM LV
Mol
acp
BSTIA
LMol
CeC BL
VEn I I AHi CA1 S
BMA
BMP
PMCo
ACo
PLCo
9 8 7 6
5
4
3
2
1
0 -1 -2 -3 -4
Py
Or
DG
S
V1
GrDG
fmj
hf
Post
PaS
RSA
8n
prf
4&5Cb
VCA
VCP
Sim
Lat
LatPC
DC
psf
Cop
Crus1
icf
ppf
Crus2
apmf
PM
Interaural Figure 121
Bregma
0
1
2
3
4
5
6

6
5
4
3
2
1
0
5 4 3 2 1 0 -1 -2 -3 -4 -5 -6 -7 -8
Interaural
Lateral 2.52 mm
M1
AID
rf
AIV
S1J
S1
GI
DI
Cl
DEn
Pir
lo
S1ULp
fmi
Bregma
S1FL
CPu
VEn
CxA
S1DZ
LSS acp
S1BF
ACo
LGP
CeL
Interaural Figure 122
9 8 7 6
5
4
3
2
1
0 -1 -2 -3 -4
ic
CeM
st
CeC
I
BLP
I
BMP
BMA
PLCo
S1
opt
LV
V2L
VLG
SubG
AHi
PMCo
GrDG
Or
Py CA3
SLu
CA1
hf
S
V1
alv Or
Py
cc CA2 Rad CA1
LMol
Mol
S
LV CA3
SLu
fi
PoDG
DLG
st
GrDG
fmj
PaS
MEnt
RSA
Fl
prf
Sim
chp
Lat
psf
Crus1
ppf
Cop
icf
Crus2
PM
Bregma
apmf
0
1
2
3
4
5
6

6
5 4 3 2 1 0 -1 -2 -3 -4 -5 -6 -7 -8
Bregma
Bregma
0
5
4
3
2
1
0
Interaural
Lateral 2.64 mm
M1
rf
AID
AIV
S1J
S1ULp
GI
DI
Pir
Cl
DEn
fmi
lo
CPu
VEn
LSS
acp
CxA
S1BF
CeC
I
LGP
BMA
ACo
Interaural Figure 123
9 8 7 6
5
4
3
2
1
0 -1 -2 -3 -4
cc
ic
CeL
LV
SLu
fi
BLP
alv
st
BMP
PLCo
S1
fi
LV
V2L
VLG
opt
AHi
Or
CA2 Py Rad
LMol
Mol
CA3
PMCo
S
V1
PoDG
CA3
CA2
CA1
S
GrDG
hf
LMol
fmj
PrS
PaS
RSA
rf
MEnt
Fl
prf
VCA
Sim
chp
psf
Lat
ppf
Crus1
icf
Cop
apmf
Crus2
PM
1
2
3
4
5
6

6
5 4 3 2 1 0 -1 -2 -3 -4 -5 -6 -7 -8
Bregma
Bregma
0
5
S1J
S1BF
S2 V2L V1
Or
Sim
Crus1
1
4
3
2
1
0
Interaural
Lateral 2.76 mm
GI
DI
S1ULp
fmi
AID
CPu
AIV Cl
rf
DEn
Pir VEn
lo
cc
ic
LGP
AStr
LV
CeC CeL
BLA BLP
I
BMA
BMP
CxA ACo PLCo
CA2
Rad CA1
RSA
fmj
LV
rf
hf
S
SLu
MEnt psf
fi
PoDG PrS
opt
CA3 GrDG
Py
PaS
st
Rad
LMol
Fl
CA2
CA1
S
AHi
PMCo
Crus2
icf
apmf
ppf
PM
Interaural Figure 124
9 8 7 6
5
4
3
2
1
0 -1 -2 -3 -4
2
3
4
5
6

6
5 4 3 2 1 0 -1 -2 -3 -4 -5 -6 -7 -8
Bregma
Bregma
0
S1
V2L
5
S1J
S1BF
V1
Sim
psf
1
4
GI
DI
S1
S1ULp
cc
alv
CA2
Or
CA1
Py Rad
LMol
Mol
S
RSA
Crus1
icf
Crus2
2
3
2
AID
AIV
rf
Cl
DEn
CPu
LGP
LV
ic
AStr
CeC
fi
st
chp
CA3
CA2
PoDG
hf
LMol
PrS
MEnt
Fl
prf
apmf
PM
3
4
1
Pir
VEn
BLA
BMA
BLP
BMP
APir
PMCo
CA1
S
LEnt
PFl
5
0
Interaural
Lateral 2.88 mm
CxA
PLCo
Interaural Figure 125
6
9 8 7 6
5
4
3
2
1
0 -1 -2 -3 -4

6
5 4 3 2 1 0 -1 -2 -3 -4 -5 -6 -7 -8
Bregma
Bregma
0
5
4
3
2
1
0
Interaural
Lateral 3.00 mm
AID
rf
S1J
S1ULp
AIV
GI
DI
Cl
DEn
Pir
CPu
VEn
S1BF
CxA
BLA
Interaural Figure 126
9 8 7 6
5
4
3
2
1
0 -1 -2 -3 -4
ic
AStr
BMA
cc
PLCo
fi
S1
LV
BMP
BLP
alv
V2L
CA1
Or
CA2
Py
Rad
LMol
Mol
CA3
PoDG
PMCo
hf
LMol
CA2
APir
CA1
S
S
LEnt
V1
PrS
Dsc
MEnt
RSA
Fl
Sim
PFl
Crus1
PM
icf
Crus2
apmf
1
2
3
4
5
6

6
5 4 3 2 1 0 -1 -2 -3 -4 -5 -6 -7 -8
Bregma
Bregma
0
5
4
3
2
1
0
Interaural
Lateral 3.12 mm
GI
DI
AID
rf
S1J
S1ULp
AIV
Pir
Cl
ec
DEn
VEn
S1BF
CPu
LaVM
BLA
BLV
Interaural Figure 127
9 8 7 6
5
4
3
2
1
0 -1 -2 -3 -4
cc
ic
AStr
PLCo
BMP
LV
S1
BLP
V2L
Py
Or
CA2
C
A
3
Rad
CA1
PMCo
CA2
APir
CA1
Mol
hf
LMol
S
V1
LEnt
S
V2L PRh
Dsc
Fl
MEnt
PFl
Crus1
icf
Crus2
apmf
PM
1
2
3
4
5
6

6
5 4 3 2 1 0 -1 -2 -3 -4 -5 -6 -7 -8
Bregma
Bregma
0
5
4
3
S1J
S1ULp
GI
DI
AID
AIV
Cl
S1BF
ec
CPu
cc
S1 V2L
alv
Or
CA1
CA2 Py
LMol
Rad
hf
Mol
CA3
V1
S
V2L
Dsc
Ent
PRh
M
Ent
Crus1
icf
Crus2
apmf
PM
1
2
3
2
rf
DEn
AStr
LV
CA2
4
La
CA1
1
Pir
VEn
BLA
BLP
BMP
APir
LEnt
PFl
5
0
Interaural
Lateral 3.25 mm
BLV
PLCo
PMCo
Interaural Figure 128
6
9 8 7 6
5
4
3
2
1
0 -1 -2 -3 -4

6
5 4 3 2 1 0 -1 -2 -3 -4 -5 -6 -7 -8
Bregma
Bregma
0
5
4
3
S1
S1J
S1ULp
GI
DI
AID
AIP
S1BF
S2
Cl
CPu
AStr
S1
AuD
cc
alv
Or
V2L
CA1
CA2
C Mol
A
3
LMol
V1
S
PRh
Dsc
TeA
Ect
MEnt
Crus1
icf
Crus2
apmf
1
2
3
2
rf
AIV
DEn
ec
La
LV
CA2
CA1
4
1
Pir
VEn
BLV
BLP
APir
LEnt
PFl
5
PMCo
0
Interaural
Lateral 3.36 mm
PLCo
Interaural Figure 129
6
9 8 7 6
5
4
3
2
1
0 -1 -2 -3 -4

6
5 4 3 2 1 0 -1 -2 -3 -4 -5 -6 -7 -8
Bregma
Bregma
0
S1
5
4
3
2
S1J
GI
DI
rf
S1ULp
AID
AIV
S1BF
S2
ec
AIP Cl
DEn
V2L
AuD
Or
alv
CA1 Py
CA2
Rad
CPu
CA3 LMol
AStr
LV
CA2
La
CA1
S
TeA
Ect
Crus1
PRh
Dsc
MEnt
icf
Crus2
1
2
3
4
1
Pir
VEn
BLV
BLP
APir
LEnt
PFl
5
0
Interaural
Lateral 3.44 mm
Interaural Figure 130
9 8 7 6
5
4
3
2
1
0 -1 -2 -3 -4
PLCo
6

6
5 4 3 2 1 0 -1 -2 -3 -4 -5 -6 -7 -8
Bregma
Bregma
0
5
4
3
2
S1ULp
GI
DI
AID
AIV
AIP
S1BF
S2
Cl
Ect
PRh
DEn
S1
AuD V2L
Au1
AuV
TeA
CPu
LV
La
CA2
CA1
CA3 Rad
CA2
CA1
TeA
S
Ect
PRh
Dsc
Crus1
MEnt
icf
Crus2
1
2
3
4
1
VEn
APir
LEnt
PFl
5
0
Interaural
Lateral 3.60 mm
Interaural Figure 131
9 8 7 6
5
4
3
2
1
0 -1 -2 -3 -4
Pir
6

6
5 4 3 2 1 0 -1 -2 -3 -4 -5 -6 -7 -8
Bregma
Bregma
0
5
S1
V2L
1
4
3
2
1
GI
DI
AID
AIV
S1BF
S2
AIP
VEn
Pir
AuD
Au1
AuV
TeA
Ect
PRh
LV
DEn
CA3
Or alv
Py
Rad
CA2
CA1
APir
S
TeA
LEnt
Ect
PRh
Dsc MEnt
PFl
Crus2
2
3
4
5
0
Interaural
Lateral 3.72 mm
Interaural Figure 132
9 8 7 6
5
4
3
2
1
0 -1 -2 -3 -4
6