Literature DB >> 27507296

Brain atlas of the Mongolian gerbil (Meriones unguiculatus) in CT/MRI-aided stereotaxic coordinates.

Susanne Radtke-Schuller1, Gerd Schuller2, Frank Angenstein3,4, Oliver S Grosser5, Jürgen Goldschmidt6,7, Eike Budinger6,7,4.   

Abstract

A new stereotaxic brain atlas of the Mongolian gerbil (Meriones unguiculatus), an important animal model in neurosciences, is presented. It combines high-quality histological material for identification of brain structures with reliable stereotaxic coordinates. The atlas consists of high-resolution images of frontal sections alternately stained for cell bodies (Nissl) and myelinated fibers (Gallyas) of 62 rostro-caudal levels at intervals of 350 μm. Brain structures were named according to the Paxinos nomenclature for rodents. The accuracy of the stereotaxic coordinate system was improved substantially by comparing and matching the series of histological sections to in vivo brain images of the gerbil obtained by magnetic resonance imaging (MRI). The skull outlines corresponding to the MR images were acquired using X-ray computerized tomography (CT) and were used to establish the relationship between coordinates of brain structures and skull. Landmarks such as lambda, bregma, ear canals and occipital crest can be used to line up skull and brain in standard atlas coordinates. An easily reproducible protocol allows sectioning of experimental brains in the standard frontal plane of the atlas.

Entities:  

Keywords:  Cytoarchitecture; Fiber architecture; Neuroanatomy; Rodent

Mesh:

Year:  2016        PMID: 27507296      PMCID: PMC5005445          DOI: 10.1007/s00429-016-1259-0

Source DB:  PubMed          Journal:  Brain Struct Funct        ISSN: 1863-2653            Impact factor:   3.270


Introduction

During the last decades, the Mongolian gerbil (Meriones unguiculatus, Thomas 1908) has emerged as an important animal model in neuroscience. It is a versatile and advantageous laboratory animal because of its robustness, its ease of handling and its reliable breeding under laboratory conditions. Virtually all sensory systems, especially the auditory system, are being intensively studied in gerbils, involving a wide range of neuroanatomical and neurophysiological approaches. Topics include development and plasticity as well as effects of aging. Research in the motor system and investigations of behavioral mechanisms, learning and memory and of transmitter systems use gerbils as model organism as well. Due to a peculiarity of the cerebral arteries (circle of Willis) in Mongolian gerbils, cerebral infarction can be induced in a controllable way and has made it a widely used model for cerebral ischemia. It is also a model animal for inherited epilepsy, hippocampal seizure and pathogenesis of CNS infections. Despite a large body of literature related to the investigation of the gerbil brain, the availability of brain atlases published for this animal species is limited. To date, there are two stereotaxic atlases of the gerbil’s brain. The ‘Stereotaxic Atlas of the Mongolian Gerbil Brain’ (Loskota et al. 1974) includes photographic montages of corresponding hemispheres of adjacent sections stained for myelinated fibers (Weil) and cell bodies (Nissl). Brain structures are outlined and labeled separately, while the neocortex is represented without subdivisions. The heavy shrinkage of the brain caused by the celloidin embedding technique was not corrected in the stereotaxic coordinates. The brains used for the ‘Stereotaxic Atlas of the Gerbil Brain’ by Thiessen and Yahr (1977) were frozen and cut in a cryostat, which causes only little shrinkage and thus more reliably reproduces stereotaxic coordinates. This atlas incorporates the earlier ‘Stereotaxic Atlas of the Hypothalamus’ by Thiessen and Goar (1970). The atlas presents only schematic outlines of structures and does not provide illustrative material of the underlying Nissl-stained histological sections. In addition, the sectioning plane deviates from the conventional frontal plane in rodents perpendicular to the axis of the brain stem in both atlases. Thus, the need for a new stereotaxic atlas of the gerbil brain that combines high-quality histological material to identify brain structures with reliable stereotaxic coordinates is evident. Brain sections are inevitably subject to distortions during tissue fixation and subsequent histological procedures (embedding, sectioning, staining and section mounting). Here, we improved the accuracy of the stereotaxic coordinate system substantially by comparing and matching the series of histological sections to in vivo brain images of the gerbil obtained by magnetic resonance imaging (MRI). Moreover, X-ray computerized tomography (CT) yielded the outlines of the skull corresponding to the MR images, which helped to establish the relationship between coordinates of brain structures and skull coordinates. This is essential for any stereotaxic procedure using landmarks on the skull to reliably target brain structures for recording, imaging, tracer or virus applications. The atlas can also be used effectively as a common reference base to collect and compare positional data from any kind of research in the gerbil brain.

Methods

Animals

Twenty-one young adult male Mongolian gerbils (Meriones unguiculatus) at the age of 4 months and weighing between 80 and 100 g were used for this study. Out of them, brains of seven animals were processed for cyto- and myeloarchitectonic features. Six other brains were additionally processed for chemo- and immunoarchitecture to support identification of anatomical structures. This material is not included in the atlas and will be published separately. Overall 10 CT scans of skulls and a total of 13 MR brain scans were performed in various combinations. All experiments were in agreement with the NIH Guide for the Care and Use of Laboratory Animals (2011) and the guidelines of the European Communities Council Directive (86/609/EEC) and approved by the animal care committee of Sachsen-Anhalt, Germany.

CT imaging

Animals were scanned under isoflurane anesthesia (1.0–1.5 % in 2:1 O2:N2O volume ratio) with the CT functionality of a NanoSPECT/CT scanner (Mediso Ltd., Budapest, Hungary). CT scans were made at 45 kVp, 1.77 μA, with 180 projections, 500 ms per projection and 96 μm pixel size. Images were reconstructed with the InVivoScope (vs.1.43) at isotropic voxel sizes of 100 μm and analyzed with the DICOM viewers Osirix (Pixmeo SARL, Bernex, Switzerland, v.5.1.7 64-bit) and the open source program AMIDE: A Medical Imaging Data Examiner (amide.exe 1.0.4, ©Andreas Loening, http://amide.sourceforge.net/; GNU GPL).

MR imaging

Animals were anesthetized with isoflurane (1.0–1.5 % in 1:1 O2:N2 volume ratio) and fixed with bite bars in a head-holder to reduce motion artifacts. MR scans were performed on a Bruker Biospec 47/20 scanner (Bruker Biospin GmbH, Rheinstetten, Germany) at 4.7 T (free bore of 20 cm) equipped with a BGA 09 (400 mT/m) gradient system. A 35 mm Litzcage small animal imaging system (DotyScientific Inc., Colombus, SC, USA) was used for radio frequency (RF) excitation and signal reception. Two days before MRI measurements, animals were injected subcutaneously with an aqueous solution containing 1 μmol/g MnCl2 (manganese enhanced MRI: ME-MRI). A data set of T1-weighted images was obtained using a 3D MDEFT (modified driven equilibrium Fourier transform) pulse sequence with the following parameters: repetition time 13.6 ms; echo time 4.3 ms; flip angle 20°; field of view 30 × 30 mm2; matrix 256 × 256 (yielding a nominal in plane resolution of 117 × 117 µm2); standard frontal orientation; slice thickness 350 µm; 20 averages. Images were reconstructed using Bruker ParaVision 4.0 (Bruker Biospin GmbH, Rheinstetten, Germany) and exported as raw images as well as in DICOM format. The open source program AMIDE (amide.exe 1.0.4, ©Andreas Loening, http://amide.sourceforge.net/) was used to align CT and MR scans and to extract images shown in the atlas.

Histology

Animals were anesthetized with a lethal dose of ketamine (40 mg/100 g body weight, i.p.) and xylazine (2 mg/100 g body weight, i.p.). When a deep anesthetic state marked by a complete loss of the flexor reflex at all limbs was reached, animals were perfused transcardially with 20 mL of phosphate buffered saline (0.1 M PBS, pH 7.4) supplemented with 0.1 % heparin followed by 200 mL of 4 % PFA (in 0.05 M PBS, pH 7.4). The brains were postfixed in the skull with 4 % PFA (in 0.05 M PBS, pH 7.4) at 4 °C for at least 7 days before removal to best preserve the brain shape. Brains were cryo-protected in 22.5 % sucrose in PBS (0.05 M, pH 7.4) overnight and cut in a cryostat (LEICA CM 3050S) into four series of 40 µm thick frontal sections. The sections were directly mounted on gelatine-coated slides and dried overnight. Alternating section series were stained on-slide either for cells (Nissl) or for myelin (Gallyas 1979). The brains additionally processed for chemo- and immunoarchitecture were stained for cytochrome oxidase, acetylcholine-esterase (AChE), NADPH-diaphorase, calcium-binding proteins (parvalbumin, calbindin and calretinin) and neurofilament protein (SMI-32) in various combinations. Sections were imaged with a virtual slide microscope (VS120 S1, Olympus BX61VST, Olympus-Deutschland, Hamburg, Germany) at 10× magnification using the proprietary software dotSlide® (Olympus).

Atlas coordinate system

The coordinate system of the brain atlas is based on the conventional definition of anatomical sectioning planes in rodents. Frontal sections are perpendicular to the brainstem axis, which in the Mongolian gerbil is also parallel to the plane defined by the most dorsal points of cerebrum and cerebellum (Fig. 1). This plane is therefore chosen as origin for the dorsoventral dimension with negative values in ventral direction. The lateral dimension is zeroed to the midsagittal plane with negative values towards the right and positive values towards the left side. The anterior to posterior coordinates of the atlas are given for different origins (bregma, lambda, interaural line and occipital crest as skull landmarks) and are valid for the skull in standard atlas orientation.
Fig. 1

View of fixed gerbil brain positioned for embedding. In the lower part of the figure, the brain is shown in the acrylic glass box used for embedding (rectangular block volume indicated by fine dotted lines). The brain is positioned on three pins (one is hidden by the left front pin) protruding from the base so that the plane defined by the most dorsal elevation of cerebrum and cerebellum (cc) as well as the brainstem axis (bs) are aligned parallel to the base. The anterior and posterior surfaces of the embedding block define the frontal sectioning plane (sp) perpendicular to cc and bs. A pin protruding from a bracket over the side walls of the box (only partly shown) prevents the brain from being washed off when the embedding medium is poured into the box

View of fixed gerbil brain positioned for embedding. In the lower part of the figure, the brain is shown in the acrylic glass box used for embedding (rectangular block volume indicated by fine dotted lines). The brain is positioned on three pins (one is hidden by the left front pin) protruding from the base so that the plane defined by the most dorsal elevation of cerebrum and cerebellum (cc) as well as the brainstem axis (bs) are aligned parallel to the base. The anterior and posterior surfaces of the embedding block define the frontal sectioning plane (sp) perpendicular to cc and bs. A pin protruding from a bracket over the side walls of the box (only partly shown) prevents the brain from being washed off when the embedding medium is poured into the box The frontal sectioning plane was implemented by a standardized embedding procedure using an acrylic glass box (Fig. 1). Each brain was oriented within the box so that the brainstem axis (Fig. 1bs) was parallel to the base of the box and the midsagittal plane lined up with the long axis of the box. Note that in this orientation the plane through the highest point of cerebellum and cerebrum (Fig. 1cc) is parallel to the base of the box and can therefore also be used to align the brain. The brain was stabilized in this orientation by adjustable supporting needles protruding from the bottom and from a bracket on top of the box. The volume around the brain was filled with embedding medium, namely a freshly prepared mixture of gelatin–albumin–glutaraldehyde. After 2–3 min, this mixture had hardened and the block was taken out of the box. Subsequently, the block was shock frozen in dry ice and mounted with its hind surface on the cutting platform of the cryostat. Due to the prior orientation within the box, the sectioning plane was now perpendicular to the long axis of the block and therefore also perpendicular to the brainstem axis and the horizontal plane through the highest cerebellar and cerebral points.

Stereotaxic reference system

In rats and mice, the connecting line through lambda and bregma coincides with that through lambda and occipital crest and is used as a horizontal guideline to align the in vivo brain in the classical planes (Paxinos and Watson 2007; Paxinos and Franklin 2001). In the Mongolian gerbil, the line linking lambda and bregma deviates from that linking lambda and occipital crest (Fig. 2, lower panel) and should, therefore, not be used as horizontal guideline to position the gerbil skull and brain in the atlas coordinate system. A horizontal adjustment of the skull along the line between lambda and occipital crest (Fig. 2, horizontal solid line) results in the best approximation to the atlas orientation (Fig. 2, dotted line) and is recommended as standard orientation.
Fig. 2

Atlas coordinate system and stereotaxic reference system. Upper panel landmarks bregma, lambda and occipital crest (encircled) on the skull of a Mongolian gerbil in a top view. They are defined by the intersection of lines (dotted lines) approximating the course of the bone sutures. Lower panel montage of CT skull image and MR brain image at a parasagittal distance of 1 mm in standard orientation of the atlas. The solid line corresponds to the horizontal plane through lambda and occipital crest, which is parallel to the plane through the highest points of cerebrum and cerebellum (dotted line)

Atlas coordinate system and stereotaxic reference system. Upper panel landmarks bregma, lambda and occipital crest (encircled) on the skull of a Mongolian gerbil in a top view. They are defined by the intersection of lines (dotted lines) approximating the course of the bone sutures. Lower panel montage of CT skull image and MR brain image at a parasagittal distance of 1 mm in standard orientation of the atlas. The solid line corresponds to the horizontal plane through lambda and occipital crest, which is parallel to the plane through the highest points of cerebrum and cerebellum (dotted line)

Selection of atlas series

The atlas series of histological sections was selected according to the following criteria: the entire series, alternately stained for cell bodies (Nissl) and myelin (Gallyas), had to show good staining quality and tissue preservation the atlas series had to match the MR scan of an average-sized brain, and relative distances of indicative structures of the brain had to show congruency with the distances in the available MR scans. The following structures that could clearly be determined both in histological sections and in MR slices were used as ‘indicative structures’ (Fig. 3): the rostral beginning of neocortex (1), the crossing of the anterior commissure (2), the distinct appearance of the medial habenular nucleus (3), the end of the superior colliculus concurrent with the middle of the inferior colliculus (4) and the end of the cerebellum (5). To judge brain size and to probe the consistency of individual histology series, the distances between indicative brain structures and the rostral pole of neocortex were evaluated and compared to the corresponding median distances in 13 MR scans (Fig. 3; Table 1).
Fig. 3

Indicative structures in histological and MRI brain series. The following structures were used (from rostral to caudal): beginning of neocortex (1), midline crossing of anterior commissure (2), distinct appearance of medial habenular nucleus (3), end of the superior colliculus (concurrent with the middle of the inferior colliculus) and (4) end of the cerebellum (5). Montages combine CT and MR scans and half of the corresponding Nissl-stained section. The anterior–posterior location of the corresponding atlas plates is indicated by dotted lines and respective numbers in the central brain image

Table 1

Distances between indicative structures in the atlas series

Distance from beginning of neocortex toATLAS hist. series (mm)ATLAS MRI (mm)All MRI (N = 13)
Median (mm)Min/max (mm)
Middle of anterior commissure5.955.7865.7/6.3
Medial habenular nucleus7.357.357.357.05/7.7
Middle of inferior colliculus12.2512.0812.1512.0/12.78
Posterior end of cerebellum18.218.0318.0317.68/18.73

Distances of indicative structures relative to the rostral beginning of the neocortex were determined in the histological atlas series (column: ATLAS hist. series), in the atlas MRI series (column: ATLAS MRI) and across MRI series (columns: all MRI). Median values and minimal and maximal values are from thirteen MRI scans

Indicative structures in histological and MRI brain series. The following structures were used (from rostral to caudal): beginning of neocortex (1), midline crossing of anterior commissure (2), distinct appearance of medial habenular nucleus (3), end of the superior colliculus (concurrent with the middle of the inferior colliculus) and (4) end of the cerebellum (5). Montages combine CT and MR scans and half of the corresponding Nissl-stained section. The anterior–posterior location of the corresponding atlas plates is indicated by dotted lines and respective numbers in the central brain image Distances between indicative structures in the atlas series Distances of indicative structures relative to the rostral beginning of the neocortex were determined in the histological atlas series (column: ATLAS hist. series), in the atlas MRI series (column: ATLAS MRI) and across MRI series (columns: all MRI). Median values and minimal and maximal values are from thirteen MRI scans The MR series that corresponded best to the median values was chosen as ‘ATLAS MRI’. The same distance measurements were performed in seven high-quality histological series. The series that corresponded best to the atlas MRI median values was designated as ‘ATLAS histology series’. Table 1 shows the conformance of the atlas histology series with the atlas MR scan and the median values of MRI series. CT scans of the skull provide the interface to the brain coordinate system in vivo. Therefore, the available CT scans were overlaid to the atlas MRI. The CT scan matching best was chosen as ‘ATLAS CT’ series. For all CT scans the distances between bregma and the skull landmarks lambda, interaural line and occipital crest were calculated (Table 2). The comparison across animals corresponded well to the values of the atlas CT scan.
Table 2

Distances between landmarks on the gerbil skull

Distance between bregma andATLAS CT (mm)All CT (N = 10)
Median (mm)Min/max (mm)
Lambda4.454.53.79/4.8
Interaural line7.257.256.19/7.6
Occipital crest9.989.959.79/10.9

Distances of skull landmarks lambda, interaural line and occipital crest are evaluated relative to bregma for the atlas CT scan (column: ATLAS CT) and as median distance values across all CT scans (columns: All CT). The range of values around the median is indicated by the minimum and maximum distance values taken from ten CT scans

Distances between landmarks on the gerbil skull Distances of skull landmarks lambda, interaural line and occipital crest are evaluated relative to bregma for the atlas CT scan (column: ATLAS CT) and as median distance values across all CT scans (columns: All CT). The range of values around the median is indicated by the minimum and maximum distance values taken from ten CT scans

Preparation of images and plates

For each 350 µm thick slice of the atlas MR series a corresponding Nissl-stained section of the atlas series was selected and grouped with the adjacent myelin-stained section to represent one of the 62 rostro-caudal levels (Fig. 4). Usually, every forth Nissl-stained section fitted best to the subsequent MR slice, which corresponded to a distance of 320 µm between the matching Nissl-stained sections. The 30 µm difference between the MR slices and the Nissl-stained sections can be explained by the shrinkage of the atlas brain due to histological processing, mainly fixation. This shrinkage is in the range of 8–10 % generally observed for cryo-protected frozen-cut brains with PFA fixation (4 %). Contrast and brightness of the images of the sections were corrected with Photoshop (CS6, Adobe Systems, San Jose, CA, USA), and distortions due to histological processing were compensated by slightly transforming the sections to optimize the congruency of anatomical structures between histological sections and MR images. Images were arranged in the atlas coordinate frame using CorelDraw graphics suite version X6 or X7 (Corel Corporation, Ottawa, ON, Canada). MR and CT images were adjusted according to the definition of the atlas coordinate system in 62 plates and reflect the in vivo orientation of the brain and skull. The images of cell- and myelin-stained sections were inserted in line with the corresponding MR image. The anterior–posterior coordinates of the plates are indicated relative to bregma, lambda, interaural line and the occipital crest. All outlines were drawn in CorelDraw on the base of the Nissl-stained section of each atlas plate. The structural boundaries seen in the corresponding myelin-stained section generally correlate well with these outlines.
Fig. 4

Anterior–posterior location of the atlas plates on the gerbil brain. Upper panel view from above. Lower panel side view. Distance between plates is 350 µm

Anatomical structures, nomenclature and abbreviations

Anatomical structures were identified on the basis of cyto- and myeloarchitecture and their relative location. For comparison we mainly used the published atlases of the Mongolian gerbil brain (Loskota et al. 1974; Thiessen and Yahr 1977), the atlases and books for rat brain of Paxinos, Swanson and Zilles (Paxinos 1995, 2004; Paxinos and Watson 2007; Paxinos et al. 2009; Swanson 1992, 2004; Zilles 1985) and for mouse brain (Paxinos and Franklin 2001; Dong 2008; Franklin and Paxinos 2008; Watson and Paxinos 2010; Watson et al. 2012). Brain series stained for chemoarchitectonic markers were consulted to support the structural identification. Unfortunately, no unified neuroanatomical nomenclature exists to date (Swanson 2015). Therefore, we decided to use the widely accepted Paxinos nomenclature and abbreviations for naming structures. Auditory midbrain and brainstem nuclei for which gerbil specific terms were already established (Budinger et al. 2000, 2013; Mylius et al. 2013; Radtke-Schuller et al. 2015) were labeled according to these studies.

Practical hints

Sectioning in atlas coordinates: It is also possible to section the brain in the standard atlas plane without the above described embedding procedure. In this case, the brain is positioned upside down on a flat surface so that it is seated with the cerebellum and cerebrum on the base. Then, part of the brain is cut off perpendicular to the base to create a surface for mounting the brain’s portion of interest on the cryostat platform. By subsequent sectioning of the brain parallel to this cutting surface the resulting sections correspond best to the frontal plane of the atlas. Stereotaxic procedure: In addition to traditional landmarks and reference points such as lambda, bregma and interaural line, we recommend the occipital crest (Fig. 2) for anterior–posterior reference and adjustment of the skull in vivo. The traditional landmarks are often difficult to discern, show individual variations and cannot be accessed in some experimental approaches (e.g., interaural coordinates in auditory research where ear bars are avoided). In general, a higher precision of in vivo positioning of the skull can be achieved by using the specific pattern of skull profiles instead of single reference points [for profile oriented stereotaxic procedure see Schuller et al. (1986)]. Index of structures The structures are listed in alphabetical order followed by their abbreviation and the plate number(s) of occurrence Index of abbreviations The abbreviations are listed in alphabetical order followed by the name of the structure and the plate number(s) of occurrence. Anterior–posterior location of the atlas plates on the gerbil brain. Upper panel view from above. Lower panel side view. Distance between plates is 350 µm
1st cerebellar lobule (lingula)1Cb46–48
2nd cerebellar lobule2Cb43–46
3rd cerebellar lobule3Cb43–49
3rd ventricle3V23–34
4th cerebellar lobule4Cb41–49
4th ventricle4V43–54
5th cerebellar lobule5Cb42–50
6th cerebellar lobule6Cb46–54
7th cerebellar lobule7Cb51–56
8th cerebellar lobule8Cb51–58
9th cerebellar lobule9Cb50–51
9th cerebellar lobule, a9aCb52–59
9th cerebellar lobule, b9bCb52–59
9th cerebellar lobule, c9cCb52–59
10th cerebellar lobule (nodule)10Cb50–55
A
A11 dopamine cellsA1130–31
A13 dopamine cellsA1328–29
A5 noradrenaline cellsA544–47
abducens nerve6n46–47
abducens nucleus6N47
accessory nerve nucleus11N60–62
accessory neurosecretory nucleiANS27–28
accumbens nucleus, coreAcbC16–21
accumbens nucleus, shellAcbSh16–21
agranular insular cortexAI11–27
alveus of the hippocampusalv27–38
ambiguus nucleus, compact partAmbC52
ambiguus nucleus, loose partAmbL55
ambiguus nucleus, subcompact partAmbSC53–54
amygdalohippocampal areaAHi29–33
amygdaloid fissureaf31–32
amygdaloid intramedullary grayIMG27–28
amygdalopiriform transition areaAPir30–35
amygdalostriatal transition areaASt26–30
angular thalamic nucleusAngT28–28
ansoparamedian fissureapmf52–55
anterior amygdaloid areaAA24–26
anterior auditory fieldAAF28–29
anterior cerebral arteryacer23
anterior commissure, anterior partaca11–24
anterior commissure, intrabulbar partaci1–10
anterior commissure, posterior partacp23–25
anterior cortical amygdaloid nucleusACo24–28
anterior hypothalamic area, anterior partAHA25–26
anterior hypothalamic area, central partAHC27–28
anterior hypothalamic area, posterior partAHP28
anterior olfactory nucleus, dorsal partAOD8–12
anterior olfactory nucleus, external partAOE6–10
anterior olfactory nucleus, lateral partAOL6–12
anterior olfactory nucleus, medial partAOM9–13
anterior olfactory nucleus, posterior partAOP14–16
anterior olfactory nucleus, ventral partAOV8–11
anterior olfactory nucleus, ventroposterior partAOVP11–15
anterior pretectal nucleusAPT35
anterior pretectal nucleus, dorsal partAPTD31–34
anterior pretectal nucleus, ventral partAPTV32–34
anterior tegmental nucleusATg40–41
anterodorsal thalamic nucleusAD26–27
anterolateral periolivary nucleusALPO44
anteromedial thalamic nucleusAM25–28
anteromedial thalamic nucleus, ventral partAMV27
anterovent thalamic nucleus, dorsomedial partAVDM26–28
anteroventral periventricular nucleusAVPe23
anteroventral thalamic nucleusAV25
anteroventral thalamic nucleus, ventrolateral partAVVL26–27
aqueductAq35–42
arcuate hypothalamic nucleusArc27–33
area postremaAP55–56
ascending fibers of the facial nerveasc748
B
Barrington’s nucleusBar43–44
basal nucleus (Meynert)B24–29
basolateral amygdaloid nucleus, anterior partBLA25–29
basolateral amygdaloid nucleus, posterior partBLP27–32
basolateral amygdaloid nucleus, ventral partBLV25–27
basomedial amygdaloid nucleus, anterior partBMA25–27
basomedial amygdaloid nucleus, posterior partBMP28–31
bed nucleus of stria terminalis, fusiform partFu23
bed nucleus of the accessory olfactory tractBAOT27
bed nucleus of the anterior commissureBAC24
bed nucleus of the stria terminalisST22
bed nucleus of the stria terminalis, intraamygdaloid divisionSTIA28–29
bed nucleus of the stria terminalis, lateral division, intermediate partSTLI24
bed nucleus of the stria terminalis, lateral division, posterior partSTLP23–24
bed nucleus of the stria terminalis, lateral division, ventral partSTLV23–24
bed nucleus of the stria terminalis, medial division, anterior partSTMA23–24
bed nucleus of the stria terminalis, medial division, posterior partSTMP25–26
bed nucleus of the stria terminalis, medial division, ventral partSTMV23–24
blood vesselBV21
Bötzinger complexBo52
brachium of the inferior colliculusbic36–40
brachium of the superior colliculusbsc33–35
C
caudal linear nucleus of the rapheCLi37–39
caudal periolivary nucleusCPO48
caudate putamen (striatum)CPu17–30
caudomedial entothinal cortexCEnt35–41
caudoventrolateral reticular nucleusCVL52–53
cell bridges of the ventral striatumCB20–22
central amygdaloid nucleus, capsular partCeC26–29
central amygdaloid nucleus, lateral divisionCeL27–28
central amygdaloid nucleus, medial divisionCeM25–29
central canalCC55–62
central cervical nucleus of the spinal cordCeCv56–62
central grayCG43
central gray of the ponsCGPn45
central gray, alpha partCGA44–46
central gray, beta partCGB44–45
central gray, gamma partCGG46
central gray, nucleus OCGO44–45
central medial thalamic nucleusCM26–31
central nucleus of the inferior colliculusCIC39–42
centrolateral thalamic nucleusCL28–31
cerebellar white mattercbw43–57
cerebral pedunclecp28–39
choroid plexuschp24–54
cingulate cortex, area 1Cg110–27
cingulate cortex, area 2Cg219–27
cingulumcg17–34
claustrumCl12–27
commissural stria terminaliscst26–27
commissure of the inferior colliculuscic42–43
commissure of the lateral lemniscuscll41–42
commissure of the superior colliculuscsc34–36
copula of the pyramisCop49–57
corpus callosumcc20–30
cortex-amygdala transition zoneCxA24–26
crus 1 of the ansiform lobuleCrus143–54
crus 2 of the ansiform lobuleCrus249–55
cuneate fasciculuscu53–62
cuneate nucleusCu52–62
cuneate nucleus, rotundus partCuR55–56
cuneiform nucleusCnF41–43
D
decussation of the superior cerebellar pedunclexscp39–41
decussation of the trapezoid bodytzx44–47
deep cerebral white matterdcw29–39
deep gray layer of the superior colliculusDpG33–41
deep white layer of the superior colliculusDpWh34–41
dentate gyrusDG30
dorsal acoustic striadas49–50
dorsal cochlear nucleus, deep coreDCDp49–50
dorsal cochlear nucleus, fusiform layerDCFu48–50
dorsal cochlear nucleus, molecular layerDCMo48–50
dorsal cortex of the inferior colliculusDCIC40–43
dorsal corticospinal tractdcs60–62
dorsal endopiriform nucleusDEn12–32
dorsal fornixdf26–27
dorsal hippocampal commissuredhc28–38
dorsal hypothalamic areaDA29–30
dorsal lateral geniculate nucleusDLG29–33
dorsal lateral olfactory tractdlo5–12
dorsal motor nucleus of vagus10N53–58
dorsal nucleus of the lateral lemniscusDNLL41–42
dorsal paragigantocellular nucleusDPGi48–51
dorsal part of claustrumDCl16–26
dorsal peduncular cortexDP12–18
dorsal periolivary nucleusDPO45–47
dorsal raphe nucleusDR37–38
dorsal raphe nucleus, caudal partDRC43–44
dorsal raphe nucleus, dorsal partDRD39–42
dorsal raphe nucleus, lateral partDRL39–41
dorsal raphe nucleus, ventral partDRV39–42
dorsal spinocerebellar tractdsc52–62
dorsal subiculumDS33–36
dorsal tegmental decussationdtgx36–37
dorsal tegmental nucleusDTg44
dorsal tegmental nucleus, central partDTgC43
dorsal tegmental nucleus, pericentral partDTgP43
dorsal tenia tectaDTT11–18
dorsal transition zoneDtr12–15
dorsolateral orbital cortexDLO9–12
dorsolateral periaqueductal grayDLPAG36–42
dorsolateral periolivary nucleusDLPO44–47
dorsomedial hypothalamic nucleusDM29–32
dorsomedial hypothalamic nucleus, compact partDMC31
dorsomedial hypothalamic nucleus, dorsal partDMD31
dorsomedial hypothalamic nucleus, ventral partDMV31
dorsomedial nucleus of the inferior colliculusDMIC41–43
dorsomedial periaqueductal grayDMPAG35–42
dorsomedial spinal trigeminal nucleusDMSp548–54
dorsomedial tegmental areaDMTg43–45
dysgranular insular cortexDI13–27
E
ectorhinal cortexEct28–42
Edinger–Westphal nucleusEW36–38
entopeduncular nucleusEP27–28
entorhinal cortexEnt42
ependyma and subependymal layerE1–23
ethmoid thalamic nucleusEth32
external capsuleec19–30
external cortex of the inferior colliculusECIC38–44
external cuneate nucleusECu52–56
external medullary laminaeml28–30
external plexiform layer of the accessory olfactory bulbEPlA5–9
external plexiform layer of the olfactory bulbEPl1–9
F
F cell group of the vestibular complexFVe52
facial nerve7n45–47
facial nucleus, dorsal intermediate subnucleus7DI48–50
facial nucleus, dorsolateral subnucleus7DL48–50
facial nucleus, dorsomedial subnucleus7DM48–50
facial nucleus, lateral subnucleus7L49–51
facial nucleus, ventral intermediate subnucleus7VI48–50
facial nucleus, ventromedial subnucleus7VM48–50
fasciculus retroflexusfr27–36
fasciola cinereumFC29–33
field CA1 of the hippocampusCA128–36
field CA2 of the hippocampusCA228–32
field CA3 of the hippocampusCA327–34
fimbria of the hippocampusfi22–30
flocculusFl43–48
forceps major of the corpus callosumfmj34–39
forceps minor of the corpus callosumfmi13–18
fornixf23–32
frontal association cortexFrA7–9
frontal cortex, area 3Fr311–17
G
gelatinous layer of the caudal spinal trigeminal nucleusGe557–62
genu of the corpus callosumgcc19
genu of the facial nerveg746–48
gigantocellular reticular nucleusGi47–54
gigantocellular reticular nucleus, alpha partGiA48–51
gigantocellular reticular nucleus, ventral partGiV51–52
globular cell area, ventral cochlear nucleusGca46–49
globus pallidusGP24–29
glomerular layer of the accessory olfactory bulbGlA5–10
glomerular layer of the olfactory bulbGl1–11
glossopharyngeal nerve nucleus9N62
gracile fasciculusgr54–62
gracile nucleusGr54–62
granular cell layer of the olfactory bulbGrO1–10
granular insular cortexGI13–27
granular layer of the dentate gyrusGrDG27–36
granule cell layer of cochlear nucleiGrC43–50
granule cell layer of the accessory olfactory bulbGrA3–10
H
habenular commissurehbc31–32
hippocampal fissurehif30–34
hypoglossal nerve12n53–58
hypoglossal nucleus12N51–58
hypoglossal nucleus, geniohyoid part12GH57–58
I
indusium griseumIG18–33
inferior cerebellar peduncle (restiform body)icp46–53
inferior olive, beta subnucleusIOBe56–58
inferior olive, cap of Kooy of the medial nucleusIOK56–57
inferior olive, dorsal nucleusIOD52–56
inferior olive, dorsomedial cell groupIODM52–55
inferior olive, medial nucleusIOM52–55
inferior olive, principal nucleusIOPr52–56
inferior olive, subnucleus A of medial nucleusIOA57–58
inferior olive, subnucleus B of medial nucleusIOB56–58
inferior olive, subnucleus C of medial nucleusIOC56–58
infralimbic cortexIL14–18
interanterodorsal thalamic nucleusIAD26–27
interanteromedial thalamic nucleusIAM27
intercalated amygdaloid nucleus, main partIM26
intercalated nuclei of the amygdalaI23–29
intercrural fissureicf49–54
interfascicular nucleusIF35–38
intermediate endopiriform nucleusIEn12–24
intermediate gray layer of the superior colliculusInG33–41
intermediate nucleus of the lateral lemniscusINLL40–42
intermediate reticular nucleusIRt46–62
intermediate white layer of the superior colliculusInWh33–41
intermediodorsal thalamic nucleusIMD28–30
intermedioventral thalamic commissureimvc29–30
internal capsuleic23–30
internal medullary laminaiml26
internal plexiform layer of the olfactory bulbIPl1–10
interpeduncular fossaIPF36
interpeduncular nucleus, caudal subnucleusIPC37–40
interpeduncular nucleus, dorsal subnucleusIPD38
interpeduncular nucleus, intermediate subnucleusIPI38–39
interpeduncular nucleus, lateral subnucleusIPL37–39
interpeduncular nucleus, rostral subnucleusIPR37–38
interposed cerebellar nucleus, anterior partIntA47–49
interposed cerebellar nucleus, dorsolateral humpIntDL47–50
interposed cerebellar nucleus, dorsomedial crestIntDM48–50
interposed cerebellar nucleus, posterior partIntP49–50
interposed cerebellar nucleus, posterior parvicellular partIntPPC49–50
interstitial nucleus of CajalInC33–38
interstitial nucleus of the medullaIB57–62
interstitial nucleus of the posterior limb of the anterior commissureIPAC22–25
interventricular foramenIVF25–
islands of CallejaICj16–22
islands of Calleja, major islandICjM20–21
isthmic reticular formationisRt39–42
K
Kölliker–Fuse nucleusKF43–44
L
lacunosum moleculare layer of the hippocampusLMol29–36
lambdoid septal zoneLd19–21
lateral accumbens shellLAcbSh19–21
lateral amygdaloid nucleusLa26–31
lateral amygdaloid nucleus, dorsal partLaD27–30
lateral amygdaloid nucleus, ventral partLaV27–30
lateral (dentate) cerebellar nucleusLat46–49
lateral cerebellar nucleus, parvicellular partLatPC46–48
lateral entorhinal cortexLEnt29–41
lateral habenular nucleusLHb28–31
lateral habenular nucleus, lateral partLHbL29–30
lateral habenular nucleus, medial partLHbM29–30
lateral lemniscusll39–43
lateral mammillary nucleusLM33–35
lateral nucleus of the trapezoid bodyLNTB44–47
lateral olfactory tractlo5–25
lateral orbital cortexLO8–16
lateral parabrachial nucleusLPB45
lateral parabrachial nucleus, central partLPBC43–44
lateral parabrachial nucleus, crescent partLPBCr44
lateral parabrachial nucleus, internal partLPBI43–45
lateral paragigantocellular nucleusLPGi51–53
lateral paragigantocellular nucleus, alpha partLPGiA48–50
lateral paragigantocellular nucleus, external partLPGiE48–50
lateral parietal association cortexLPtA28–30
lateral periaqueductal grayLPAG35–42
lateral posterior thalamic nucleus, laterocaudal partLPLC32–33
lateral posterior thalamic nucleus, laterorostral partLPLR29–31
lateral posterior thalamic nucleus, mediocaudal partLPMC32–34
lateral posterior thalamic nucleus, mediorostral partLPMR29–32
lateral preoptic areaLPO22–25
lateral recess of the 4th ventricleLR4V45–51
lateral reticular nucleusLRt54–59
lateral reticular nucleus, parvicellular partLRtPC56–58
lateral reticular nucleus, subtrigeminal partLRtS555–56
lateral septal nucleus, dorsal partLSD19–25
lateral septal nucleus, intermediate partLSI18–23
lateral septal nucleus, ventral partLSV19–23
lateral stripe of the striatumLSS21–23
lateral superior oliveLSO45–47
lateral terminal nucleus of the accessory optic tractLT33
lateral ventricleLV17–32
lateral vestibular nucleusLVe47–49
lateroanterior hypothalamic nucleusLA25–26
laterodorsal tegmental nucleusLDTg42–44
laterodorsal tegmental nucleus, ventral partLDTgV43
laterodorsal thalamic nucleus, dorsomedial partLDDM27–28
laterodorsal thalamic nucleus, ventrolateral partLDVL27–29
lateroventral periolivary nucleusLVPO44–47
layer 1 of cortex111–33
layer 2 of cortex211–33
layer 3 of cortex311–33
layer 4 of cortex414–16
lemina terminalisLTer24
linear nucleus of the medullaLi51–53
lithoid nucleusLth33
locus coeruleusLC44–45
longitudinal fasciculus of the ponslfp40–43
M
magnocellular nucleus of the lateral hypothalamusMCLH29
magnocellular nucleus of the posterior commissureMCPC33–34
magnocellular preoptic nucleusMCPO23–25
mammillary pedunclemp35–36
mammillary recess of the 3rd ventricleMRe34
mammillotegmental tractmtg33
mammillothalamic tractmt27–33
marginal zone of the medial geniculateMZMG33–35
matrix region of the medullaMx50–59
medial (fastigial) cerebellar nucleusMed47–50
medial accessory oculomotor nucleusMA334–35
medial amygdaloid nucleus, anterodorsal partMeAD26–27
medial amygdaloid nucleus, anteroventral partMeAV27
medial amygdaloid nucleus, posterodorsal partMePD27–29
medial amygdaloid nucleus, posteroventral partMePV28–29
medial cerebellar nucleus, dorsolateral protuberanceMedDL49–50
medial cerebellar nucleus, lateral partMedL49–50
medial corticohypothalamic tractmch25
medial entorhinal cortexMEnt34–41
medial forebrain bundlemfb19–32
medial geniculate nucleus, dorsal partMGD33–36
medial geniculate nucleus, medial partMGM33–36
medial geniculate nucleus, ventral partMGV33–36
medial habenular nucleusMHb27–31
medial lemniscusml28–54
medial lemniscal decussationmlx56
medial longitudinal fasciculusmlf37–62
medial mammillary nucleus, lateral partML34–36
medial mammillary nucleus, medial partMM34–35
medial mammillary nucleus, median partMnM34–
medial nucleus of the trapezoid bodyMNTB43–47
medial orbital cortexMO8–14
medial parabrachial nucleusMPB43–45
medial parabrachial nucleus, external partMPBE44
medial parietal association cortexMPtA28–30
medial preoptic areaMPA22–25
medial preoptic nucleusMPO24–25
medial pretectal nucleusMPT32
medial septal nucleusMS19–23
medial superior oliveMSO44–47
medial terminal nucleus of the accessory optic tractMT35
medial tuberal nucleusMTu29–31
medial vestibular nucleusMVe53
medial vestibular nucleus, magnocellular partMVeMC46–52
medial vestibular nucleus, parvicellular partMVePC46–52
median accessory nucleus of the medullaMnA59–62
median eminenceME30–32
median preoptic nucleusMnPO22–24
median raphe nucleusMnR39–43
mediodorsal thalamic nucleusMD27
mediodorsal thalamic nucleus, central partMDC28–30
mediodorsal thalamic nucleus, lateral partMDL28–30
mediodorsal thalamic nucleus, medial partMDM28–30
medioventral periolivary nucleusMVPO44–47
medullary reticular nucleus, dorsal partMdD55–62
medullary reticular nucleus, ventral partMdV55–62
mesencehalic reticular formationmRt36–38
mesencephalic trigeminal nucleusMe538–45
mesencephalic trigeminal tractme543–45
microcellular tegmental nucleusMiTg38–39
middle cerebellar pedunclemcp40–46
middle cerebral arterymcer23
mitral cell layer of the accessory olfactory bulbMiA5–9
mitral cell layer of the olfactory bulbMi1–10
molecular layer of the dentate gyrusMoDG27–37
molecular layer of the subiculumMoS37
motor root of the trigeminal nervem543–45
motor trigeminal nucleus5N44–45
motor trigeminal nucleus, anterior digastric part5ADi45–46
motor trigeminal nucleus, tensor tympani part5TT43–44
N
navicular nucleus of the basal forebrainNv17–18
nigrostriatal bundlens27–33
nucleus of DarkschewitschDk33–35
nucleus of origin of efferents of the vestibular nerveEVe47
nucleus of RollerRo52–56
nucleus of the brachium of the inferior colliculusBIC36–37
nucleus of the central acoustic tractCAT43–
nucleus of the fields of ForelF32–34
nucleus of the horizontal limb of the diagonal bandHDB20–25
nucleus of the lateral olfactory tractLOT25–26
nucleus of the optic tractOT32–35
nucleus of the posterior commissurePCom33–34
nucleus of the solitary tractSol49–50
nucleus of the solitary tract, commissural partSolC55–62
nucleus of the solitary tract, medial partSolM55–59
nucleus of the solitary tract, ventrolateral partSolVL55–57
nucleus of the vertical limb of the diagonal bandVDB19–21
nucleus XX48–52
nucleus YY48
O
obexObex57
octopus cell area, ventral cochlear nucleusOca47–49
oculomotor nerve3n36–37
oculomotor nucleus3N37–38
oculomotor nucleus, parvicellular part3PC36
olfactory nerve layerON1–8
olfactory tubercleTu16–23
olfactory ventricle (olfactory part of lateral ventricle)OV1–16
olivary pretectal nucleusOPT32–33
olivocerebellar tractoc50–54
olivocochlear bundleocb46–47
optic chiasmoch21–25
optic nerve layer of the superior colliculusOp33–40
optic tractopt26–33
oriens layer of the hippocampusOr27–36
oval paracentral thalamic nucleusOPC29–31
P
p1 periaqueductal grayp1PAG32–34
p1 reticular formationp1Rt32–35
paraabducens nucleusPa646–47
parabigeminal nucleusPBG38–40
parabrachial pigmented nucleus of the ventral tegmental areaPBP33–37
paracentral thalamic nucleusPC27–30
paracochlear glial substancePCGS46
parafascicular thalamic nucleusPF31–32
parafloccular sulcuspfs44–50
paraflocculusPFl43–50
parainterfascicular nucleus of the ventral tegmental areaPIF36–37
paralemniscal nucleusPL40–42
paralemniscal nucleus, medial partMPL41–42
paramedian lobulePM49–56
paramedian raphe nucleusPMnR39–42
paramedian sulcuspms50–55
paranigral nucleus of the ventral tegmental areaPN36–37
parapyramidal nucleusPPy49–50
pararubral nucleusPaR35–38
parasolitary nucleusPSol54–55
parastrial nucleusPS23–24
parasubiculumPaS35–42
parasubthalamic nucleusPSTh32
paratenial thalamic nucleusPT25–27
paraterete nucleusPTe29–30
paratrigeminal nucleusPa554–57
paratrochlear nucleusPa440–41
paraventricular hypothalamic nucleus, anterior parvicellular partPaAP25–26
paraventricular hypothalamic nucleus, medial magnocellular partPaMM27–28
paraventricular hypothalamic nucleus, medial parvicellular partPaMP27
paraventricular hypothalamic nucleus, posterior partPaPo28
paraventricular hypothalamic nucleus, ventral partPaV27
paraventricular thalamic nucleusPV27–28
paraventricular thalamic nucleus, anterior partPVA25–26
paraventricular thalamic nucleus, posterior partPVP29–31
paraxiphoid nucleus of thalamusPaXi27–29
parietal cortex, posterior areaPtP28–31
parvicellular reticular nucleusPCRt46–54
peduncular part of lateral hypothalamusPLH26–33
pedunculopontine tegmental nucleusPTg38–42
pericollicular tegmental areaPta39–43
perifacial zoneP748–51
perifornical nucleusPeF29–30
perifornical part of lateral hypothalamusPeFLH29–32
perilemniscal nucleus, ventral partPLV41–43
peripeduncular nucleusPP33–35
perirhinal cortexPRh28–42
peritrigeminal zoneP543–46
periventricular hypothalamic nucleusPe23–30
piriform cortexPir11–33
polymorph layer of the dentate gyrusPoDG28–35
pontine nucleiPn39–42
pontine raphe nucleusPnR43
pontine reticular nucleus, caudal partPnC44–47
pontine reticular nucleus, oral partPnO39–43
pontine reticular nucleus, ventral partPnV45–47
posterior commissurepc32–34
posterior hypothalamic areaPHA33
posterior hypothalamic area, dorsal partPHD30–31
posterior hypothalamic nucleusPH31–32
posterior intralaminar thalamic nucleusPIL33–35
posterior limitans thalamic nucleusPLi33–35
posterior pretectal nucleusPPT33–35
posterior superior fissurepsf43–54
posterior thalamic nuclear groupPo28–33
posterior thalamic nuclear group, triangular partPoT33–35
posterodorsal raphe nucleusPDR39–42
posterodorsal tegmental nucleusPDTg45
posterolateral cortical amygdaloid nucleusPLCo27–29
posterolateral fissureplf43–55
posteromedial cortical amygdaloid nucleusPMCo29–33
posteromedian thalamic nucleusPoMn31
postsubiculumPost35–40
pre-Edinger–Westphal nucleusPrEW34–35
precentral fissurepcn43–46
precommissural nucleusPrC31–33
preculminate fissurepcuf43–47
precuneiform areaPrCnF38–41
prelimbic cortexPrL9–18
premammillary nucleus, dorsal partPMD33
premammillary nucleus, ventral partPMV32–33
prepositus nucleusPr47–53
prepyramidal fissureppf51–56
prerubral fieldPR31–34
presubiculumPrS35–38
primary auditory cortexAu128–33
primary auditory fieldA129–33
primary fissureprf43–50
primary motor cortexM111–28
primary somatosensory cortexS124–30
primary somatosensory cortex, barrel fieldS1BF20–28
primary somatosensory cortex, dysgranular zoneS1DZ16–28
primary somatosensory cortex, forelimb regionS1FL15–24
primary somatosensory cortex, hindlimb regionS1HL20–26
primary somatosensory cortex, jaw regionS1J13–20
primary somatosensory cortex, oral dysgranular zoneS1DZO18–19
primary somatosensory cortex, shoulder regionS1Sh25–26
primary somatosensory cortex, trunk regionS1Tr27–28
primary somatosensory cortex, upper lip regionS1ULp18–28
primary visual cortexV131–42
primary visual cortex, binocular areaV1B32–39
primary visual cortex, monocular areaV1M32–39
principal mammillary tractpm33–34
principal sensory trigeminal nucleus, dorsomedial partPr5DM44–47
principal sensory trigeminal nucleus, ventrolateral partPr5VL43–47
pyramidal cell layer of the hippocampusPy27–36
pyramidal decussationpyx57–62
pyramidal tractpy43–58
R
radiatum layer of the hippocampusRad28–36
raphe interpositus nucleusRIP46–48
raphe magnus nucleusRMg44–51
raphe obscurus nucleusROb50–58
raphe pallidus nucleusRPa43–58
red nucleus, magnocellular partRMC35–38
red nucleus, parvicellular partRPC35–36
reticluostrial nucleusRtSt26
reticular thalamic nucleusRt26–30
reticulotegmental nucleus of the ponsRtTg41–45
reticulotegmental nucleus of the pons, pericentral partRtTgP41–42
retroambiguus nucleusRAmb56–58
retrochiasmatic areaRCh27–28
retrochiasmatic area, lateral partRChL27
retroethmoid nucleusREth33
retrorubral fieldRRF37–39
retrorubral nucleusRR39–40
retrosplenial dysgranular cortexRSD27–42
retrosplenial granular cortexRSG40
retrosplenial granular cortex, a regionRSGa35–39
retrosplenial granular cortex, b regionRSGb32–39
retrosplenial granular cortex, c regionRSGc27–36
retrouniens areaRRe31
reuniens thalamic nucleusRe26–30
rhabdoid nucleusRbd39
rhinal fissurerf7–41
rhinal incisureri7–12
rhomboid thalamic nucleusRh27–30
rostral amygdalopiriform areaRAPir28–30
rostral interstitial nucleus of medial longitudinal fasciculusRI32–33
rostral linear nucleus of the rapheRLi35–35
rostral periolivary nucleusRPO44
rostral ventral respiratory groupRVRG53
rubrospinal tractrs41–62
S
sagulum nucleusSag41–43
scaphoid thalamic nucleusSc32
secondary auditory cortex, dorsal areaAuD28–36
secondary auditory cortex, ventral areaAuV28–36
secondary fissuresf53–58
secondary motor cortexM210–28
secondary somatosensory cortexS218–28
secondary visual cortex, lateral areaV2L31–41
secondary visual cortex, medial areaV2M31–40
sensory root of the trigeminal nerves542–47
septofimbrial nucleusSFi22–25
septohippocampal nucleusSHi18–25
simple lobuleSim43–49
simplex fissuresimf47–49
solitary nucleus, dorsolateral partSolDL55–57
solitary nucleus, ventral partSolV55–57
solitary tractsol50–57
spherical cell area, ventral cochlear nucleusSca43–46
spinal trigeminal nucleus, caudal partSp5C55–62
spinal trigeminal nucleus, interpolar partSp5I49–56
spinal trigeminal nucleus, oral partSp5O48–51
spinal trigeminal tractsp548–62
spinal vestibular nucleusSpVe48–53
splenium of the corpus callosumscc31–33
stratum lucidum of the hippocampusSLu28–33
stria medullaris of the thalamussm25–30
stria terminalisst23–31
strial part of the preoptic areaStA23
subbrachial nucleusSubB36–38
subcoeruleus nucleus, alpha partSubCA44
subcoeruleus nucleus, dorsal partSubCD43–45
subcoeruleus nucleus, ventral partSubCV43–45
subcommissural organSCO32–34
subfornical organSFO25
subgeniculate nucleusSubG31–32
subiculum, transition areaSTr37–38
subincertal nucleusSubI29–30
sublenticular extended amygdalaEA26
sublenticular extended amygdala, central partEAC25
submedius thalamic nucleusSub30
submedius thalamic nucleus, dorsal partSubD28–29
submedius thalamic nucleus, ventral partSubV28–29
subparafascicular thalamic nucleusSPF31
subparafascicular thalamic nucleus, parvicellular partSPFPC31–32
subparaventricular zone of the hypothalamusSPa27–28
subpeduncular tegmental nucleusSPTg40–42
substantia innominata, basal partSIB21–24
substantia nigra, compact partSNC33–38
substantia nigra, reticular partSNR33–38
subthalamic nucleusSTh30–32
superficial gray layer of the superior colliculusSuG33–41
superior cerebellar pedunclescp41–49
superior medullary velumSMV45–47
superior periolivary nucleusSPN44–47
superior thalamic radiationstr31–32
superior vestibular nucleusSuVe46–47
suprachiasmatic nucleusSCh25
suprachiasmatic nucleus, dorsolateral partSChDL26
suprachiasmatic nucleus, ventromedial partSChVM26
suprageniculate thalamic nucleusSG33–36
supragenual nucleusSGe46
supramammillary decussationsumx34
supramammillary nucleus, lateral partSuML33–34
supramammillary nucleus, medial partSuMM33–34
supraoculomotor capSu3C36–36
supraoculomotor periaqueductal graySu336–39
supraoptic decussationsox26–32
supraoptic nucleusSO23–27
supratrigeminal nucleusSu543–45
T
tectal grayTG33–35
tectospinal tractts39–62
temporal association cortexTeA37–39
terete hypothalamic nucleusTe31
transverse fibers of the ponstfp39
trapezoid bodytz43–49
triangular septal nucleusTS24–25
trigeminal transition zone5Tr44–46
trigeminal-solitary transition zone5Sol48–55
trigeminothalamic tracttth43–45
trochlear nerve4n41–44
trochlear nucleus4N39–40
trochlear nuclues shell region4Sh39–40
tuberal region of lateral hypothalamusTuLH27–31
U
uvular fissureuf56–59
V
vagus nerve10n52
ventral anterior thalamic nucleusVA27
ventral cochlear nucleus, anterior partVCA43–47
ventral cochlear nucleus, posterior partVCP47–49
ventral endopiriform nucleusVEn24–29
ventral geniculate nucleusVG29–34
ventral geniculate nucleus, magnocellular partVGMC31–32
ventral geniculate nucleus, parvicellular partVGPC31–32
ventral hippocampal commissurevhc25–27
ventral linear nucleus of the thalamusVLi33
ventral nucleus of the lateral lemniscusVNLL40
ventral nucleus of the lateral lemniscus, dorsal partdVNLL41–42
ventral nucleus of the lateral lemniscus, ventral partvVNLL41–43
ventral nucleus of the trapezoid bodyVNTB43–47
ventral orbital cortexVO9–16
ventral pallidumVP16–25
ventral part of claustrumVCl16–26
ventral posterior nucleus of the thalamus, parvicellular partVPPC31
ventral posterolateral thalamic nucleusVPL28–31
ventral posteromedial thalamic nucleusVPM28–32
ventral reuniens thalamic nucleusVRe27–30
ventral spinocerebellar tractvsc43–62
ventral subiculumVS31–36
ventral tegmental areaVTA37–38
ventral tegmental area, rostral partVTAR34–35
ventral tegmental decussationvtgx35–37
ventral tegmental nucleusVTg42
ventral tenia tectaVTT11–16
ventral tuberomammillary nucleusVTM33–34
ventrolateral hypothalamic nucleusVLH27
ventrolateral hypothalamic tractvlh27
ventrolateral periaqueductal grayVLPAG37–42
ventrolateral preoptic nucleusVLPO23–24
ventrolateral thalamic nucleusVL27–30
ventromedial hypothalamic nucleusVMH28–31
ventromedial hypothalamic nucleus, central partVMHC29–30
ventromedial hypothalamic nucleus, dorsomedial partVMHDM29–30
venalamic nucleus, ventrolateral partVMHVL29–30
ventromedial nucleus of the hypothalamus shellVMHSh28–31
ventromedial preoptic nucleusVMPO23–24
ventromedial thalamic nucleusVM27–30
vestibulocerebellar nucleusVeCb46–49
vestibulocochlear nerve8n46–48
vestibulomesencephalic tractveme46–48
vestibulospinal tractvesp49
X
xiphoid thalamic nucleusXi27–28
Z
zona incertaZI28–29
zona incerta, caudal partZIC34–34
zona incerta, dorsal partZID30–33
zona incerta, rostral partZIR26–27
zona incerta, ventral partZIV30–33
zonal layer of the superior colliculusZo33–41
1layer 1 of cortex11–33
2layer 2 of cortex11–33
3layer 3 of cortex11–33
4layer 4 of cortex14–16
1Cb1st cerebellar lobule (lingula)46–48
2Cb2nd cerebellar lobule43–46
3Cb3rd cerebellar lobule43–49
3noculomotor nerve36–37
3Noculomotor nucleus37–38
3PCoculomotor nucleus, parvicellular part36
3V3rd ventricle23–34
4Cb4th cerebellar lobule41–49
4ntrochlear nerve41–44
4Ntrochlear nucleus39–40
4Shtrochlear nuclues shell region39–40
4V4th ventricle43–54
5ADimotor trigeminal nucleus, anterior digastric part45–46
5Cb5th cerebellar lobule42–50
5Nmotor trigeminal nucleus44–45
5Soltrigeminal-solitary transition zone48–55
5Trtrigeminal transition zone44–46
5TTmotor trigeminal nucleus, tensor tympani part43–44
6Cb6th cerebellar lobule46–54
6nabducens nerve46–47
6Nabducens nucleus47
7Cb7th cerebellar lobule51–56
7DIfacial nucleus, dorsal intermediate subnucleus48–50
7DLfacial nucleus, dorsolateral subnucleus48–50
7DMfacial nucleus, dorsomedial subnucleus48–50
7Lfacial nucleus, lateral subnucleus49–51
7nfacial nerve45–47
7VIfacial nucleus, ventral intermediate subnucleus48–50
7VMfacial nucleus, ventromedial subnucleus48–50
8Cb8th cerebellar lobule51–58
8nvestibulocochlear nerve46–48
9aCb9th cerebellar lobule, a52–59
9bCb9th cerebellar lobule, b52–59
9Cb9th cerebellar lobule50–51
9cCb9th cerebellar lobule, c52–59
9Nglossopharyngeal nerve nucleus62
10Cb10th cerebellar lobule (nodule)50–55
10Ndorsal motor nucleus of vagus53–58
10nvagus nerve52
11Naccessory nerve nucleus60–62
12GHhypoglossal nucleus, geniohyoid part57–58
12nhypoglossal nerve53–58
12Nhypoglossal nucleus51–58
A
A1primary auditory field29–33
A11A11 dopamine cells30–31
A13A13 dopamine cells28–29
A5A5 noradrenaline cells44–47
AAanterior amygdaloid area24–26
AAFanterior auditory field28–29
acaanterior commissure, anterior part11–24
AcbCaccumbens nucleus, core16–21
AcbShaccumbens nucleus, shell16–21
aceranterior cerebral artery23
acianterior commissure, intrabulbar part1–10
ACoanterior cortical amygdaloid nucleus24–28
acpanterior commissure, posterior part23–25
ADanterodorsal thalamic nucleus26–27
afamygdaloid fissure31–32
AHAanterior hypothalamic area, anterior part25–26
AHCanterior hypothalamic area, central part27–28
AHiamygdalohippocampal area29–33
AHPanterior hypothalamic area, posterior part28
AIagranular insular cortex11–27
ALPOanterolateral periolivary nucleus44
alvalveus of the hippocampus27–38
AManteromedial thalamic nucleus25–28
AmbCambiguus nucleus, compact part52
AmbLambiguus nucleus, loose part55
AmbSCambiguus nucleus, subcompact part53–54
AMVanteromedial thalamic nucleus, ventral part27
AngTangular thalamic nucleus28–28
ANSaccessory neurosecretory nuclei27–28
AODanterior olfactory nucleus, dorsal part8–12
AOEanterior olfactory nucleus, external part6–10
AOLanterior olfactory nucleus, lateral part6–12
AOManterior olfactory nucleus, medial part9–13
AOPanterior olfactory nucleus, posterior part14–16
AOVanterior olfactory nucleus, ventral part8–11
AOVPanterior olfactory nucleus, ventroposterior part11–15
AParea postrema55–56
APiramygdalopiriform transition area30–35
apmfansoparamedian fissure52–55
APTanterior pretectal nucleus35
APTDanterior pretectal nucleus, dorsal part31–34
APTVanterior pretectal nucleus, ventral part32–34
Aqaqueduct35–42
Arcarcuate hypothalamic nucleus27–33
asc7ascending fibers of the facial nerve48
AStamygdalostriatal transition area26–30
ATganterior tegmental nucleus40–41
Au1primary auditory cortex28–33
AuDsecondary auditory cortex, dorsal area28–36
AuVsecondary auditory cortex, ventral area28–36
AVanteroventral thalamic nucleus25
AVDManterovent thalamic nucleus, dorsomedial part26–28
AVPeanteroventral periventricular nucleus23
AVVLanteroventral thalamic nucleus, ventrolateral part26–27
B
Bbasal nucleus (Meynert)24–29
BACbed nucleus of the anterior commissure24
BAOTbed nucleus of the accessory olfactory tract27
BarBarrington’s nucleus43–44
bicbrachium of the inferior colliculus36–40
BICnucleus of the brachium of the inferior colliculus36–37
BLAbasolateral amygdaloid nucleus, anterior part25–29
BLPbasolateral amygdaloid nucleus, posterior part27–32
BLVbasolateral amygdaloid nucleus, ventral part25–27
BMAbasomedial amygdaloid nucleus, anterior part25–27
BMPbasomedial amygdaloid nucleus, posterior part28–31
BoBötzinger complex52
bscbrachium of the superior colliculus33–35
BVblood vessel21
C
CA1field CA1 of the hippocampus28–36
CA2field CA2 of the hippocampus28–32
CA3field CA3 of the hippocampus27–34
CATnucleus of the central acoustic tract43
CBcell bridges of the ventral striatum20–22
cbwcerebellar white matter43–57
CCcentral canal55–62
cccorpus callosum20–30
CeCcentral amygdaloid nucleus, capsular part26–29
CeCvcentral cervical nucleus of the spinal cord56–62
CeLcentral amygdaloid nucleus, lateral division27–28
CeMcentral amygdaloid nucleus, medial division25–29
CEntcaudomedial entothinal cortex35–41
CGcentral gray43
cgcingulum17–34
Cg1cingulate cortex, area 110–27
Cg2cingulate cortex, area 219–27
CGAcentral gray, alpha part44–46
CGBcentral gray, beta part44–45
CGGcentral gray, gamma part46
CGOcentral gray, nucleus O44–45
CGPncentral gray of the pons45
chpchoroid plexus24–54
CICcentral nucleus of the inferior colliculus39–42
ciccommissure of the inferior colliculus42–43
CLcentrolateral thalamic nucleus28–31
Clclaustrum12–27
CLicaudal linear nucleus of the raphe37–39
cllcommissure of the lateral lemniscus41–42
CMcentral medial thalamic nucleus26–31
CnFcuneiform nucleus41–43
Copcopula of the pyramis49–57
cpcerebral peduncle28–39
CPOcaudal periolivary nucleus48
CPucaudate putamen (striatum)17–30
Crus1crus 1 of the ansiform lobule43–54
Crus2crus 2 of the ansiform lobule49–55
csccommissure of the superior colliculus34–36
cstcommissural stria terminalis26–27
cucuneate fasciculus53–62
Cucuneate nucleus52–62
CuRcuneate nucleus, rotundus part55–56
CVLcaudoventrolateral reticular nucleus52–53
CxAcortex-amygdala transition zone24–26
D
DAdorsal hypothalamic area29–30
dasdorsal acoustic stria49–50
DCDpdorsal cochlear nucleus, deep core49–50
DCFudorsal cochlear nucleus, fusiform layer48–50
DCICdorsal cortex of the inferior colliculus40–43
DCldorsal part of claustrum16–26
DCModorsal cochlear nucleus, molecular layer48–50
dcsdorsal corticospinal tract60–62
dcwdeep cerebral white matter29–39
DEndorsal endopiriform nucleus12–32
dfdorsal fornix26–27
DGdentate gyrus30
dhcdorsal hippocampal commissure28–38
DIdysgranular insular cortex13–27
Dknucleus of Darkschewitsch33–35
DLGdorsal lateral geniculate nucleus29–33
dlodorsal lateral olfactory tract5–12
DLOdorsolateral orbital cortex9–12
DLPAGdorsolateral periaqueductal gray36–42
DLPOdorsolateral periolivary nucleus44–47
DMdorsomedial hypothalamic nucleus29–32
DMCdorsomedial hypothalamic nucleus, compact part31
DMDdorsomedial hypothalamic nucleus, dorsal part31
DMICdorsomedial nucleus of the inferior colliculus41–43
DMPAGdorsomedial periaqueductal gray35–42
DMSp5dorsomedial spinal trigeminal nucleus48–54
DMTgdorsomedial tegmental area43–45
DMVdorsomedial hypothalamic nucleus, ventral part31
DNLLdorsal nucleus of the lateral lemniscus41–42
DPdorsal peduncular cortex12–18
DpGdeep gray layer of the superior colliculus33–41
DPGidorsal paragigantocellular nucleus48–51
DPOdorsal periolivary nucleus45–47
DpWhdeep white layer of the superior colliculus34–41
DRdorsal raphe nucleus37–38
DRCdorsal raphe nucleus, caudal part43–44
DRDdorsal raphe nucleus, dorsal part39–42
DRLdorsal raphe nucleus, lateral part39–41
DRVdorsal raphe nucleus, ventral part39–42
DSdorsal subiculum33–36
dscdorsal spinocerebellar tract52–62
DTgdorsal tegmental nucleus44
DTgCdorsal tegmental nucleus, central part43
DTgPdorsal tegmental nucleus, pericentral part43
dtgxdorsal tegmental decussation36–37
Dtrdorsal transition zone12–15
DTTdorsal tenia tecta11–18
dVNLLventral nucleus of the lateral lemniscus, dorsal part41–42
E
Eependyma and subependymal layer1–23
EAsublenticular extended amygdala26
EACsublenticular extended amygdala, central part25
ecexternal capsule19–30
ECICexternal cortex of the inferior colliculus38–44
Ectectorhinal cortex28–42
ECuexternal cuneate nucleus52–56
emlexternal medullary lamina28–30
Ententorhinal cortex42
EPentopeduncular nucleus27–28
EPlexternal plexiform layer of the olfactory bulb1–9
EPlAexternal plexiform layer of the accessory olfactory bulb5–9
Ethethmoid thalamic nucleus32
EVenucleus of origin of efferents of the vestibular nerve47
EWEdinger–Westphal nucleus36–38
F
ffornix23–32
Fnucleus of the fields of Forel32–34
FCfasciola cinereum29–33
fifimbria of the hippocampus22–30
Flflocculus43–48
fmiforceps minor of the corpus callosum13–18
fmjforceps major of the corpus callosum34–39
frfasciculus retroflexus27–36
Fr3frontal cortex, area 311–17
FrAfrontal association cortex7–9
Fubed nucleus of stria terminalis, fusiform part23
FVeF cell group of the vestibular complex52
G
g7genu of the facial nerve46–48
Gcaglobular cell area, ventral cochlear nucleus46–49
gccgenu of the corpus callosum19
Ge5gelatinous layer of the caudal spinal trigeminal nucleus57–62
Gigigantocellular reticular nucleus47–54
GIgranular insular cortex13–27
GiAgigantocellular reticular nucleus, alpha part48–51
GiVgigantocellular reticular nucleus, ventral part51–52
Glglomerular layer of the olfactory bulb1–11
GlAglomerular layer of the accessory olfactory bulb5–10
GPglobus pallidus24–29
grgracile fasciculus54–62
Grgracile nucleus54–62
GrAgranule cell layer of the accessory olfactory bulb3–10
GrCgranule cell layer of cochlear nuclei43–50
GrDGgranular layer of the dentate gyrus27–36
GrOgranular cell layer of the olfactory bulb1–10
H
hbchabenular commissure31–32
HDBnucleus of the horizontal limb of the diagonal band20–25
hifhippocampal fissure30–34
I
Iintercalated nuclei of the amygdala23–29
IADinteranterodorsal thalamic nucleus26–27
IAMinteranteromedial thalamic nucleus27
IBinterstitial nucleus of the medulla57–62
icinternal capsule23–30
icfintercrural fissure49–54
ICjislands of Calleja16–22
ICjMislands of Calleja, major island20–21
icpinferior cerebellar peduncle (restiform body)46–53
IEnintermediate endopiriform nucleus12–24
IFinterfascicular nucleus35–38
IGindusium griseum18–33
ILinfralimbic cortex14–18
IMintercalated amygdaloid nucleus, main part26
IMDintermediodorsal thalamic nucleus28–30
IMGamygdaloid intramedullary gray27–28
imlinternal medullary lamina26
imvcintermedioventral thalamic commissure29–30
InCinterstitial nucleus of Cajal33–38
InGintermediate gray layer of the superior colliculus33–41
INLLintermediate nucleus of the lateral lemniscus40–42
IntAinterposed cerebellar nucleus, anterior part47–49
IntDLinterposed cerebellar nucleus, dorsolateral hump47–50
IntDMinterposed cerebellar nucleus, dorsomedial crest48–50
IntPinterposed cerebellar nucleus, posterior part49–50
IntPPCinterposed cerebellar nucleus, posterior parvicellular part49–50
InWhintermediate white layer of the superior colliculus33–41
IOAinferior olive, subnucleus A of medial nucleus57–58
IOBinferior olive, subnucleus B of medial nucleus56–58
IOBeinferior olive, beta subnucleus56–58
IOCinferior olive, subnucleus C of medial nucleus56–58
IODinferior olive, dorsal nucleus52–56
IODMinferior olive, dorsomedial cell group52–55
IOKinferior olive, cap of Kooy of the medial nucleus56–57
IOMinferior olive, medial nucleus52–55
IOPrinferior olive, principal nucleus52–56
IPACinterstitial nucleus of the posterior limb of the anterior commissure22–25
IPCinterpeduncular nucleus, caudal subnucleus37–40
IPDinterpeduncular nucleus, dorsal subnucleus38
IPFinterpeduncular fossa36
IPIinterpeduncular nucleus, intermediate subnucleus38–39
IPlinternal plexiform layer of the olfactory bulb1–10
IPLinterpeduncular nucleus, lateral subnucleus37–39
IPRinterpeduncular nucleus, rostral subnucleus37–38
IRtintermediate reticular nucleus46–62
isRtisthmic reticular formation39–42
IVFinterventricular foramen25
K
KFKölliker–Fuse nucleus43–44
L
Lalateral amygdaloid nucleus26–31
LAlateroanterior hypothalamic nucleus25–26
LAcbShlateral accumbens shell19–21
LaDlateral amygdaloid nucleus, dorsal part27–30
Latlateral (dentate) cerebellar nucleus46–49
LatPClateral cerebellar nucleus, parvicellular part46–48
LaVlateral amygdaloid nucleus, ventral part27–30
LClocus coeruleus44–45
Ldlambdoid septal zone19–21
LDDMlaterodorsal thalamic nucleus, dorsomedial part27–28
LDTglaterodorsal tegmental nucleus42–44
LDTgVlaterodorsal tegmental nucleus, ventral part43
LDVLlaterodorsal thalamic nucleus, ventrolateral part27–29
LEntlateral entorhinal cortex29–41
lfplongitudinal fasciculus of the pons40–43
LHblateral habenular nucleus28–31
LHbLlateral habenular nucleus, lateral part29–30
LHbMlateral habenular nucleus, medial part29–30
Lilinear nucleus of the medulla51–53
lllateral lemniscus39–43
LMlateral mammillary nucleus33–35
LMollacunosum moleculare layer of the hippocampus29–36
LNTBlateral nucleus of the trapezoid body44–47
lolateral olfactory tract5–25
LOlateral orbital cortex8–16
LOTnucleus of the lateral olfactory tract25–26
LPAGlateral periaqueductal gray35–42
LPBlateral parabrachial nucleus45
LPBClateral parabrachial nucleus, central part43–44
LPBCrlateral parabrachial nucleus, crescent part44
LPBIlateral parabrachial nucleus, internal part43–45
LPGilateral paragigantocellular nucleus51–53
LPGiAlateral paragigantocellular nucleus, alpha part48–50
LPGiElateral paragigantocellular nucleus, external part48–50
LPLClateral posterior thalamic nucleus, laterocaudal part32–33
LPLRlateral posterior thalamic nucleus, laterorostral part29–31
LPMClateral posterior thalamic nucleus, mediocaudal part32–34
LPMRlateral posterior thalamic nucleus, mediorostral part29–32
LPOlateral preoptic area22–25
LPtAlateral parietal association cortex28–30
LR4Vlateral recess of the 4th ventricle45–51
LRtlateral reticular nucleus54–59
LRtPClateral reticular nucleus, parvicellular part56–58
LRtS5lateral reticular nucleus, subtrigeminal part55–56
LSDlateral septal nucleus, dorsal part19–25
LSIlateral septal nucleus, intermediate part18–23
LSOlateral superior olive45–47
LSSlateral stripe of the striatum21–23
LSVlateral septal nucleus, ventral part19–23
LTlateral terminal nucleus of the accessory optic tract33
LTerlemina terminalis24
Lthlithoid nucleus33
LVlateral ventricle17–32
LVelateral vestibular nucleus47–49
LVPOlateroventral periolivary nucleus44–47
M
M1primary motor cortex11–28
M2secondary motor cortex10–28
m5motor root of the trigeminal nerve43–45
MA3medial accessory oculomotor nucleus34–35
mcermiddle cerebral artery23
mchmedial corticohypothalamic tract25
MCLHmagnocellular nucleus of the lateral hypothalamus29
mcpmiddle cerebellar peduncle40–46
MCPCmagnocellular nucleus of the posterior commissure33–34
MCPOmagnocellular preoptic nucleus23–25
MDmediodorsal thalamic nucleus27
MDCmediodorsal thalamic nucleus, central part28–30
MdDmedullary reticular nucleus, dorsal part55–62
MDLmediodorsal thalamic nucleus, lateral part28–30
MDMmediodorsal thalamic nucleus, medial part28–30
MdVmedullary reticular nucleus, ventral part55–62
MEmedian eminence30–32
Me5mesencephalic trigeminal nucleus38–45
me5mesencephalic trigeminal tract43–45
MeADmedial amygdaloid nucleus, anterodorsal part26–27
MeAVmedial amygdaloid nucleus, anteroventral part27
Medmedial (fastigial) cerebellar nucleus47–50
MedDLmedial cerebellar nucleus, dorsolateral protuberance49–50
MedLmedial cerebellar nucleus, lateral part49–50
MEntmedial entorhinal cortex34–41
MePDmedial amygdaloid nucleus, posterodorsal part27–29
MePVmedial amygdaloid nucleus, posteroventral part28–29
mfbmedial forebrain bundle19–32
MGDmedial geniculate nucleus, dorsal part33–36
MGMmedial geniculate nucleus, medial part33–36
MGVmedial geniculate nucleus, ventral part33–36
MHbmedial habenular nucleus27–31
Mimitral cell layer of the olfactory bulb1–10
MiAmitral cell layer of the accessory olfactory bulb5–9
MiTgmicrocellular tegmental nucleus38–39
mlmedial lemniscus28–54
MLmedial mammillary nucleus, lateral part34–36
mlfmedial longitudinal fasciculus37–62
mlxmedial lemniscal decussation56
MMmedial mammillary nucleus, medial part34–35
MnAmedian accessory nucleus of the medulla59–62
MnMmedial mammillary nucleus, median part34
MnPOmedian preoptic nucleus22–24
MnRmedian raphe nucleus39–43
MNTBmedial nucleus of the trapezoid body43–47
MOmedial orbital cortex8–14
MoDGmolecular layer of the dentate gyrus27–37
MoSmolecular layer of the subiculum37
mpmammillary peduncle35–36
MPAmedial preoptic area22–25
MPBmedial parabrachial nucleus43–45
MPBEmedial parabrachial nucleus, external part44
MPLparalemniscal nucleus, medial part41–42
MPOmedial preoptic nucleus24–25
MPTmedial pretectal nucleus32
MPtAmedial parietal association cortex28–30
MRemammillary recess of the 3rd ventricle34
mRtmesencehalic reticular formation36–38
MSmedial septal nucleus19–23
MSOmedial superior olive44–47
mtmammillothalamic tract27–33
MTmedial terminal nucleus of the accessory optic tract35
mtgmammillotegmental tract33
MTumedial tuberal nucleus29–31
MVemedial vestibular nucleus53
MVeMCmedial vestibular nucleus, magnocellular part46–52
MVePCmedial vestibular nucleus, parvicellular part46–52
MVPOmedioventral periolivary nucleus44–47
Mxmatrix region of the medulla50–59
MZMGmarginal zone of the medial geniculate33–35
N
nsnigrostriatal bundle27–33
Nvnavicular nucleus of the basal forebrain17–18
O
Obexobex57
ocolivocerebellar tract50–54
Ocaoctopus cell area, ventral cochlear nucleus47–49
ocbolivocochlear bundle46–47
ochoptic chiasm21–25
ONolfactory nerve layer1–8
Opoptic nerve layer of the superior colliculus33–40
OPCoval paracentral thalamic nucleus29–31
OPTolivary pretectal nucleus32–33
optoptic tract26–33
Ororiens layer of the hippocampus27–36
OTnucleus of the optic tract32–35
OVolfactory ventricle (olfactory part of lateral ventricle)1–16
P
p1PAGp1 periaqueductal gray32–34
p1Rtp1 reticular formation32–35
P5peritrigeminal zone43–46
P7perifacial zone48–51
Pa4paratrochlear nucleus40–41
Pa5paratrigeminal nucleus54–57
Pa6paraabducens nucleus46–47
PaAPparaventricular hypothalamic nucleus, anterior parvicellular part25–26
PaMMparaventricular hypothalamic nucleus, medial magnocellular part27–28
PaMPparaventricular hypothalamic nucleus, medial parvicellular part27
PaPoparaventricular hypothalamic nucleus, posterior part28
PaRpararubral nucleus35–38
PaSparasubiculum35–42
PaVparaventricular hypothalamic nucleus, ventral part27
PaXiparaxiphoid nucleus of thalamus27–29
PBGparabigeminal nucleus38–40
PBPparabrachial pigmented nucleus of the ventral tegmental area33–37
PCparacentral thalamic nucleus27–30
pcposterior commissure32–34
PCGSparacochlear glial substance46
pcnprecentral fissure43–46
PComnucleus of the posterior commissure33–34
PCRtparvicellular reticular nucleus46–54
pcufpreculminate fissure43–47
PDRposterodorsal raphe nucleus39–42
PDTgposterodorsal tegmental nucleus45
Peperiventricular hypothalamic nucleus23–30
PeFperifornical nucleus29–30
PeFLHperifornical part of lateral hypothalamus29–32
PFparafascicular thalamic nucleus31–32
PFlparaflocculus43–50
pfsparafloccular sulcus44–50
PHposterior hypothalamic nucleus31–32
PHAposterior hypothalamic area33
PHDposterior hypothalamic area, dorsal part30–31
PIFparainterfascicular nucleus of the ventral tegmental area36–37
PILposterior intralaminar thalamic nucleus33–35
Pirpiriform cortex11–33
PLparalemniscal nucleus40–42
PLCoposterolateral cortical amygdaloid nucleus27–29
plfposterolateral fissure43–55
PLHpeduncular part of lateral hypothalamus26–33
PLiposterior limitans thalamic nucleus33–35
PLVperilemniscal nucleus, ventral part41–43
PMparamedian lobule49–56
pmprincipal mammillary tract33–34
PMCoposteromedial cortical amygdaloid nucleus29–33
PMDpremammillary nucleus, dorsal part33
PMnRparamedian raphe nucleus39–42
pmsparamedian sulcus50–55
PMVpremammillary nucleus, ventral part32–33
PNparanigral nucleus of the ventral tegmental area36–37
Pnpontine nuclei39–42
PnCpontine reticular nucleus, caudal part44–47
PnOpontine reticular nucleus, oral part39–43
PnRpontine raphe nucleus43
PnVpontine reticular nucleus, ventral part45–47
Poposterior thalamic nuclear group28–33
PoDGpolymorph layer of the dentate gyrus28–35
PoMnposteromedian thalamic nucleus31
Postpostsubiculum35–40
PoTposterior thalamic nuclear group, triangular part33–35
PPperipeduncular nucleus33–35
ppfprepyramidal fissure51–56
PPTposterior pretectal nucleus33–35
PPyparapyramidal nucleus49–50
Prprepositus nucleus47–53
PRprerubral field31–34
Pr5DMprincipal sensory trigeminal nucleus, dorsomedial part44–47
Pr5VLprincipal sensory trigeminal nucleus, ventrolateral part43–47
PrCprecommissural nucleus31–33
PrCnFprecuneiform area38–41
PrEWpre-Edinger–Westphal nucleus34–35
prfprimary fissure43–50
PRhperirhinal cortex28–42
PrLprelimbic cortex9–18
PrSpresubiculum35–38
PSparastrial nucleus23–24
psfposterior superior fissure43–54
PSolparasolitary nucleus54–55
PSThparasubthalamic nucleus32
PTparatenial thalamic nucleus25–27
Ptapericollicular tegmental area39–43
PTeparaterete nucleus29–30
PTgpedunculopontine tegmental nucleus38–42
PtPparietal cortex, posterior area28–31
PVparaventricular thalamic nucleus27–28
PVAparaventricular thalamic nucleus, anterior part25–26
PVPparaventricular thalamic nucleus, posterior part29–31
Pypyramidal cell layer of the hippocampus27–36
pypyramidal tract43–58
pyxpyramidal decussation57–62
R
Radradiatum layer of the hippocampus28–36
RAmbretroambiguus nucleus56–58
RAPirrostral amygdalopiriform area28–30
Rbdrhabdoid nucleus39
RChretrochiasmatic area27–28
RChLretrochiasmatic area, lateral part27
Rereuniens thalamic nucleus26–30
REthretroethmoid nucleus33
rfrhinal fissure7–41
Rhrhomboid thalamic nucleus27–30
rirhinal incisure7–12
RIrostral interstitial nucleus of medial longitudinal fasciculus32–33
RIPraphe interpositus nucleus46–48
RLirostral linear nucleus of the raphe35–35
RMCred nucleus, magnocellular part35–38
RMgraphe magnus nucleus44–51
Ronucleus of Roller52–56
RObraphe obscurus nucleus50–58
RParaphe pallidus nucleus43–58
RPCred nucleus, parvicellular part35–36
RPOrostral periolivary nucleus44
RRretrorubral nucleus39–40
RReretrouniens area31
RRFretrorubral field37–39
rsrubrospinal tract41–62
RSDretrosplenial dysgranular cortex27–42
RSGretrosplenial granular cortex40
RSGaretrosplenial granular cortex, a region35–39
RSGbretrosplenial granular cortex, b region32–39
RSGcretrosplenial granular cortex, c region27–36
Rtreticular thalamic nucleus26–30
RtStreticluostrial nucleus26
RtTgreticulotegmental nucleus of the pons41–45
RtTgPreticulotegmental nucleus of the pons, pericentral part41–42
RVRGrostral ventral respiratory group53
S
S1primary somatosensory cortex24–30
S1BFprimary somatosensory cortex, barrel field20–28
S1DZprimary somatosensory cortex, dysgranular zone16–28
S1DZOprimary somatosensory cortex, oral dysgranular zone18–19
S1FLprimary somatosensory cortex, forelimb region15–24
S1HLprimary somatosensory cortex, hindlimb region20–26
S1Jprimary somatosensory cortex, jaw region13–20
S1Shprimary somatosensory cortex, shoulder region25–26
S1Trprimary somatosensory cortex, trunk region27–28
S1ULpprimary somatosensory cortex, upper lip region18–28
S2secondary somatosensory cortex18–28
s5sensory root of the trigeminal nerve42–47
Sagsagulum nucleus41–43
Scscaphoid thalamic nucleus32
Scaspherical cell area, ventral cochlear nucleus43–46
sccsplenium of the corpus callosum31–33
SChsuprachiasmatic nucleus25
SChDLsuprachiasmatic nucleus, dorsolateral part26
SChVMsuprachiasmatic nucleus, ventromedial part26
SCOsubcommissural organ32–34
scpsuperior cerebellar peduncle41–49
sfsecondary fissure53–58
SFiseptofimbrial nucleus22–25
SFOsubfornical organ25
SGsuprageniculate thalamic nucleus33–36
SGesupragenual nucleus46
SHiseptohippocampal nucleus18–25
SIBsubstantia innominata, basal part21–24
Simsimple lobule43–49
simfsimplex fissure47–49
SLustratum lucidum of the hippocampus28–33
smstria medullaris of the thalamus25–30
SMVsuperior medullary velum45–47
SNCsubstantia nigra, compact part33–38
SNRsubstantia nigra, reticular part33–38
SOsupraoptic nucleus23–27
Solnucleus of the solitary tract49–50
solsolitary tract50–57
SolCnucleus of the solitary tract, commissural part55–62
SolDLsolitary nucleus, dorsolateral part55–57
SolMnucleus of the solitary tract, medial part55–59
SolVsolitary nucleus, ventral part55–57
SolVLnucleus of the solitary tract, ventrolateral part55–57
soxsupraoptic decussation26–32
sp5spinal trigeminal tract48–62
Sp5Cspinal trigeminal nucleus, caudal part55–62
Sp5Ispinal trigeminal nucleus, interpolar part49–56
Sp5Ospinal trigeminal nucleus, oral part48–51
SPasubparaventricular zone of the hypothalamus27–28
SPFsubparafascicular thalamic nucleus31
SPFPCsubparafascicular thalamic nucleus, parvicellular part31–32
SPNsuperior periolivary nucleus44–47
SPTgsubpeduncular tegmental nucleus40–42
SpVespinal vestibular nucleus48–53
STbed nucleus of the stria terminalis22
ststria terminalis23–31
StAstrial part of the preoptic area23
SThsubthalamic nucleus30–32
STIAbed nucleus of the stria terminalis, intraamygdaloid division28–29
STLIbed nucleus of the stria terminalis, lateral division, intermediate part24
STLPbed nucleus of the stria terminalis, lateral division, posterior part23–24
STLVbed nucleus of the stria terminalis, lateral division, ventral part23–24
STMAbed nucleus of the stria terminalis, medial division, anterior part23–24
STMPbed nucleus of the stria terminalis, medial division, posterior part25–26
STMVbed nucleus of the stria terminalis, medial division, ventral part23–24
STrsubiculum, transition area37–38
strsuperior thalamic radiation31–32
Su3supraoculomotor periaqueductal gray36–39
Su3Csupraoculomotor cap36–36
Su5supratrigeminal nucleus43–45
Subsubmedius thalamic nucleus30
SubBsubbrachial nucleus36–38
SubCAsubcoeruleus nucleus, alpha part44
SubCDsubcoeruleus nucleus, dorsal part43–45
SubCVsubcoeruleus nucleus, ventral part43–45
SubDsubmedius thalamic nucleus, dorsal part28–29
SubGsubgeniculate nucleus31–32
SubIsubincertal nucleus29–30
SubVsubmedius thalamic nucleus, ventral part28–29
SuGsuperficial gray layer of the superior colliculus33–41
SuMLsupramammillary nucleus, lateral part33–34
SuMMsupramammillary nucleus, medial part33–34
sumxsupramammillary decussation34
SuVesuperior vestibular nucleus46–47
T
Teterete hypothalamic nucleus31
TeAtemporal association cortex37–39
tfptransverse fibers of the pons39
TGtectal gray33–35
tstectospinal tract39–62
TStriangular septal nucleus24–25
tthtrigeminothalamic tract43–45
Tuolfactory tubercle16–23
TuLHtuberal region of lateral hypothalamus27–31
tztrapezoid body43–49
tzxdecussation of the trapezoid body44–47
U
ufuvular fissure56–59
V
V1primary visual cortex31–42
V1Bprimary visual cortex, binocular area32–39
V1Mprimary visual cortex, monocular area32–39
V2Lsecondary visual cortex, lateral area31–41
V2Msecondary visual cortex, medial area31–40
VAventral anterior thalamic nucleus27
VCAventral cochlear nucleus, anterior part43–47
VClventral part of claustrum16–26
VCPventral cochlear nucleus, posterior part47–49
VDBnucleus of the vertical limb of the diagonal band19–21
VeCbvestibulocerebellar nucleus46–49
vemevestibulomesencephalic tract46–48
VEnventral endopiriform nucleus24–29
vespvestibulospinal tract49
VGventral geniculate nucleus29–34
VGMCventral geniculate nucleus, magnocellular part31–32
VGPCventral geniculate nucleus, parvicellular part31–32
vhcventral hippocampal commissure25–27
VLventrolateral thalamic nucleus27–30
VLHventrolateral hypothalamic nucleus27
vlhventrolateral hypothalamic tract27
VLiventral linear nucleus of the thalamus33
VLPAGventrolateral periaqueductal gray37–42
VLPOventrolateral preoptic nucleus23–24
VMventromedial thalamic nucleus27–30
VMHventromedial hypothalamic nucleus28–31
VMHCventromedial hypothalamic nucleus, central part29–30
VMHDMventromedial hypothalamic nucleus, dorsomedial part29–30
VMHShventromedial nucleus of the hypothalamus shell28–31
VMHVLventromedial hypothalamic nucleus, ventrolateral part29–30
VMPOventromedial preoptic nucleus23–24
VNLLventral nucleus of the lateral lemniscus40
VNTBventral nucleus of the trapezoid body43–47
VOventral orbital cortex9–16
VPventral pallidum16–25
VPLventral posterolateral thalamic nucleus28–31
VPMventral posteromedial thalamic nucleus28–32
VPPCventral posterior nucleus of the thalamus, parvicellular part31
VReventral reuniens thalamic nucleus27–30
VSventral subiculum31–36
vscventral spinocerebellar tract43–62
VTAventral tegmental area37–38
VTARventral tegmental area, rostral part34–35
VTgventral tegmental nucleus42
vtgxventral tegmental decussation35–37
VTMventral tuberomammillary nucleus33–34
VTTventral tenia tecta11–16
vVNLLventral nucleus of the lateral lemniscus, ventral part41–43
X
Xnucleus X48–52
Xixiphoid thalamic nucleus27–28
xscpdecussation of the superior cerebellar peduncle39–41
Y
Ynucleus Y48
Z
ZIzona incerta28–29
ZICzona incerta, caudal part34–34
ZIDzona incerta, dorsal part30–33
ZIRzona incerta, rostral part26–27
ZIVzona incerta, ventral part30–33
Zozonal layer of the superior colliculus33–41
  8 in total

1.  Brain Maps Online: Toward Open Access Atlases and a Pan-mammalian Nomenclature.

Authors:  Larry W Swanson
Journal:  J Comp Neurol       Date:  2015-05-12       Impact factor: 3.215

2.  The subcortical auditory structures in the Mongolian gerbil: II. Frequency-related topography of the connections with cortical field AI.

Authors:  Eike Budinger; Michael Brosch; Henning Scheich; Judith Mylius
Journal:  J Comp Neurol       Date:  2013-08-15       Impact factor: 3.215

3.  A stereotaxic method for small animals using experimentally determined reference profiles.

Authors:  G Schuller; S Radtke-Schuller; M Betz
Journal:  J Neurosci Methods       Date:  1986-12       Impact factor: 2.390

4.  Silver staining of myelin by means of physical development.

Authors:  F Gallyas
Journal:  Neurol Res       Date:  1979       Impact factor: 2.448

5.  Functional organization of auditory cortex in the Mongolian gerbil (Meriones unguiculatus). IV. Connections with anatomically characterized subcortical structures.

Authors:  E Budinger; P Heil; H Scheich
Journal:  Eur J Neurosci       Date:  2000-07       Impact factor: 3.386

6.  Subcortical auditory structures in the Mongolian gerbil: I. Golgi architecture.

Authors:  Judith Mylius; Michael Brosch; Henning Scheich; Eike Budinger
Journal:  J Comp Neurol       Date:  2013-04-15       Impact factor: 3.215

7.  Stereotaxic atlas of the hypothalamus of the Mongolian gerbil (Meriones unguiculatus).

Authors:  D D Thiessen; S Goar
Journal:  J Comp Neurol       Date:  1970-09       Impact factor: 3.215

8.  Restricted loss of olivocochlear but not vestibular efferent neurons in the senescent gerbil (Meriones unguiculatus).

Authors:  Susanne Radtke-Schuller; Sabine Seeler; Benedikt Grothe
Journal:  Front Aging Neurosci       Date:  2015-02-13       Impact factor: 5.750
  8 in total
  44 in total

1.  Neural Variability Limits Adolescent Skill Learning.

Authors:  Melissa L Caras; Dan H Sanes
Journal:  J Neurosci       Date:  2019-02-12       Impact factor: 6.167

Review 2.  On the Usage of Brain Atlases in Neuroimaging Research.

Authors:  Andreas Hess; Rukun Hinz; Georgios A Keliris; Philipp Boehm-Sturm
Journal:  Mol Imaging Biol       Date:  2018-10       Impact factor: 3.488

3.  Evolution of Brain Connections: Integrating Diffusion MR Tractography With Gene Expression Highlights Increased Corticocortical Projections in Primates.

Authors:  Christine J Charvet; Arthi Palani; Priya Kabaria; Emi Takahashi
Journal:  Cereb Cortex       Date:  2019-12-17       Impact factor: 5.357

4.  GABAA Receptors in the Mongolian Gerbil: a PET Study Using [18F]Flumazenil to Determine Receptor Binding in Young and Old Animals.

Authors:  M Kessler; M Mamach; R Beutelmann; M Lukacevic; S Eilert; P Bascuñana; A Fasel; F M Bengel; J P Bankstahl; T L Ross; G M Klump; G Berding
Journal:  Mol Imaging Biol       Date:  2020-04       Impact factor: 3.488

5.  Early sensory experience influences the development of multisensory thalamocortical and intracortical connections of primary sensory cortices.

Authors:  Julia U Henschke; Anja M Oelschlegel; Frank Angenstein; Frank W Ohl; Jürgen Goldschmidt; Patrick O Kanold; Eike Budinger
Journal:  Brain Struct Funct       Date:  2017-11-01       Impact factor: 3.270

6.  Fluoro-Jade B histofluorescence staining detects dentate granule cell death after repeated five-minute transient global cerebral ischemia.

Authors:  Ji Hyeon Ahn; Taek Geun Ohk; Dae Won Kim; Hyunjung Kim; Minah Song; Tae-Kyeong Lee; Jae-Chul Lee; Go Eun Yang; Myoung Cheol Shin; Jun Hwi Cho; Soo Young Choi; Moo-Ho Won; Joon Ha Park
Journal:  Metab Brain Dis       Date:  2019-03-04       Impact factor: 3.584

7.  Parietal Cortex Is Required for the Integration of Acoustic Evidence.

Authors:  Justin D Yao; Justin Gimoto; Christine M Constantinople; Dan H Sanes
Journal:  Curr Biol       Date:  2020-07-02       Impact factor: 10.834

8.  GABAergic inhibition gates excitatory LTP in perirhinal cortex.

Authors:  Vibhakar C Kotak; Ana Mirallave; Todd M Mowery; Dan H Sanes
Journal:  Hippocampus       Date:  2017-09-26       Impact factor: 3.899

9.  A three-dimensional digital neurological atlas of the mustached bat (Pteronotus parnellii).

Authors:  Stuart D Washington; Julie Hamaide; Ben Jeurissen; Gwendolyn van Steenkiste; Toon Huysmans; Jan Sijbers; Steven Deleye; Jagmeet S Kanwal; Geert De Groof; Sayuan Liang; Johan Van Audekerke; Jeffrey J Wenstrup; Annemie Van der Linden; Susanne Radtke-Schuller; Marleen Verhoye
Journal:  Neuroimage       Date:  2018-08-10       Impact factor: 6.556

10.  Tonotopic distribution and inferior colliculus projection pattern of inhibitory and excitatory cell types in the lateral superior olive of Mongolian gerbils.

Authors:  Jeffrey G Mellott; Matasha Dhar; Amir Mafi; Nick Tokar; Bradley D Winters
Journal:  J Comp Neurol       Date:  2021-08-11       Impact factor: 3.215
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