The limbic zone of the rabbit and rat claustrum: a study of the claustrocingulate connections based on the retrograde axonal transport of fluorescent tracers

The claustrum is a subcortical structure lying under the insular and piriform cortices, whose function is still not clear. Although data exist on connections of the claustrum and the limbic cortex, the topography of the limbic zone in the rabbit and rat claustrum has not been studied extensively. The study was performed on 17 adult Wistar rats and 12 New Zealand rabbits. Two percent water solutions of fluorescent retrograde tracers fast blue and nuclear yellow were injected into the various regions of the limbic cortex. The limbic zone is localized throughout the whole rostrocaudal extent of the claustrum, mainly in its ventromedial portion lying close to the external capsule. Although this zone of the claustrum is localized similarly in both rat and rabbit, some differences between these two species exist. In the rat, neurons projecting to all limbic areas are localized mainly in the anterior and central parts of the claustrum, whereas in the rabbit, the majority of the neurons projecting to the cingulate cortex are present in the anterior and central parts of this structure, while neurons sending axons to the retrosplenial cortex are localized in the central and posterior parts. In both species, double-labeling study showed that neurons projecting to various limbic regions are intermingled and that neurons sending axons into two different limbic regions are seen only occasionally. Our findings give support to the role of the claustrum in integrating information between different areas of the cerebral cortex and the limbic system. Accepted: 11 June 1999     

Rat posterior parietal cortex: topography of corticocortical and thalamic connections

Anatomical and functional findings support the contention that there is a distinct posterior parietal cortical area (PPC) in the rat, situated between the rostrally adjacent hindlimb sensorimotor area and the caudally adjacent secondary visual areas. The PPC is distinguished from these areas by receiving thalamic afferents from the lateral dorsal (LD), lateral posterior (LP), and posterior (Po) nuclei, in the absence of input from the ventrobasal complex (VB) or dorsal lateral geniculate (DLG) nuclei. Behavioral studies have demonstrated that PPC is involved in spatial orientation and directed attention. In the present study we used fluorescent retrograde axonal tracers primarily to investigate the cortical connections of PPC, in order to determine the organization of the circuitry by which PPC is likely to participate in these functions, and also to determine how the topography of its thalamic connections differs from that of neighboring cortical areas. The cortical connections of PPC involve the ventrolateral (VLO) and medial (MO) orbital areas, medial agranular cortex (area Fr2), portions of somatic sensory areas Par1 and Par2, secondary visual areas Oc2M and Oc2L, auditory area Tel, and retrosplenial cortex. The secondary visual areas Oc2L and Oc2M have cortical connections which are similar to those of PPC, but are restricted within orbital cortex to area VLO, and within area Fr2 to its caudal portion, and do not involve auditory area Te1. The cortical connections of hindlimb cortex are largely restricted to somatic sensory and motor areas. Retrosplenial cortex, which is medially adjacent to PPC, has cortical connections that are prominent with visual cortex, do not involve somatic sensory or auditory cortex, and include the presubiculum. We conclude that PPC is distinguished by its pattern of cortical connections with the somatic sensory, auditory and visual areas, and with areas Fr2, and VLO/MO, in addition to its exclusive thalamic connectivity with LD, LP and Po. Because recent behavioral studies indicate that PPC, Fr2 and VLO are involved in directed attention and spatial learning, we suggest that the interconnections among these three cortical areas represent a major component of the circuitry for these functions in rats.     

Neuronal connections of orbital cortex in rats: topography of cortical and thalamic afferents

The cortical and thalamic afferent connections of rat orbital cortex were investigated using fluorescent retrograde axonal tracers. Each of the four orbital areas has a distinct pattern of connections. Corticocortical connections involving the ventral and ventrolateral orbital areas are more extensive than those of the medial and lateral orbital areas. The medial orbital area has cortical connections with the cingulate, medial agranular (Fr2) and posterior parietal (PPC) cortices. The ventral orbital area has connections with the cingulate area, area Fr2, secondary somatic sensory area Par2, PPC, and visual areas Oc2M and Oc2L. The ventrolateral orbital area (VLO) receives cortical input from insular cortex, area Fr2, somatic sensory areas Par1 and Par2, PPC and Oc2L. The lateral orbital area has cortical connections limited to the agranular and granular insular areas, and Par2. Thalamic afferents to the four orbital fields are also topographically organized, and are focused in the submedial and mediodorsal nuclei. The ventrolateral orbital area receives input from the entirety of the submedial nucleus, whereas the other orbital areas receive input from its periphery only. Each orbital area is connected with a particular segment of the mediodorsal nucleus. The medial orbital area receives its principal thalamic afferents from the parataenial nucleus, the dorsocentral portion of the mediodorsal nucleus, and the ventromedial portion of the submedial nucleus. The ventral orbital area receives input from the lateral segment of the mediodorsal nucleus, the rostromedial portion of the submedial nucleus and the central lateral nucleus. Thalamic afferents to the ventrolateral orbital area arise from the entirety of the submedial nucleus and from the lateral segment of the mediodorsal nucleus. The lateral orbital area receives thalamic afferents from the central segment of the mediodorsal nucleus, the ventral portion of the submedial nucleus and the ventromedial nucleus. The paraventricular, ventromedial, rhomboid and reuniens nuclei also provide additional input to the four orbital areas. The connections of the ventrolateral orbital area are interpreted in the context of its role in directed attention and allocentric spatial localization. The present findings provide anatomical support for the view that areas Fr2, PPC and VLO comprise a cortical network mediating such functions.     

Identification of the projection from the visual cortex to the claustrum by anterograde axonal transport in the cat

Summary Visual cortex, including areas 17, 18, and sometimes 19, was injected with tritiated leucine. Terminal labelling could be detected by autoradiography in the dorsocaudal part of the ipsilateral claustrum in all cases.     

Forebrain connections of medial agranular cortex in the prairie vole, Microtus ochrogaster

 Fluorescent axonal tracers were used to investigate the connections of medial agranular cortex (frontal area 2, Fr2) in male prairie voles. The rostral and caudal portions of Fr2 (rFr2 and cFr2) have distinct but partially overlapping patterns of connections. Thalamic labeling after cFr2 injections was present in anteromedial nucleus (AM), ventrolateral nucleus (VL), lateral segment, mediodorsal nucleus (MDl), centrolateral nucleus (CL), ventromedial nucleus (VM), posterior nucleus (Po) and lateral posterior nucleus (LP). A band of labeled cells involving CL, central medial nucleus (CM) and rhomboid nucleus (Rh) formed a halo around the periphery of submedial (gelatinosus) nucleus (Sm). Within cFr2 there is a rostrocaudal gradient whereby projections from VL and MDl become progressively sparser caudally, whereas those from LP and Po become denser. Rostral Fr2 receives afferents from a similar group of thalamic nuclei, but has denser innervation from VL and MDl, lacks afferents from LP, and receives less input from nuclei around the periphery of Sm. Caudal Fr2 has extensive cortical connections including orbital cortex, rostral Fr2, Fr1, caudal parietal area 1 (Par1), parietal area 2 (Par2), and posterior parietal, retrosplenial and visual areas. Rostral Fr2 has similar connections with areas Fr1, Par1 and Par2; orbital connections focused in ventrolateral orbital cortex (VLO); connections with caudal Fr2; greatly reduced connections with posterior parietal cortex and the visual areas; and no connections with retrosplenial cortex. The axons linking rFr2 and cFr2 with each other and with other cortical areas travel predominately in the deep gray matter of layers VI and VII rather than in the white matter. Projections to the dorsal striatum from rFr2 are widespread in the head of the caudate, become progressively restricted to a dorsocentral focus more caudally, and disappear by the level of the anterior commissure. The projections from cFr2 are largely restricted to a focal dorsocentral region of the striatum and to the dorsolateral margin of the caudatoputamen. In comparison to area Fr2, the laterally adjacent area Fr1 has thalamic and cortical connections which are markedly restricted. Area Fr1 receives thalamic input from nuclei VL, anteroventral nucleus (AV), CL and Po, but none from mediodorsal nucleus (MD) or LP, and its input from VM is reduced. Cortical afferents to Fr1 originate from areas Fr2, caudal Par1 and Par2. Medial agranular cortex of prairie voles has a pattern of connections largely similar to that seen in rats, suggesting that area Fr2 in prairie voles is part of a cortical network that may mediate complex behaviors involving spatial orientation. Received: 20 May 1998 / Accepted: 14 October 1998     

A stereological approach to human cortical architecture: identification and delineation of cortical areas

Stereology offers a variety of procedures to analyze quantitatively the regional and laminar organization in cytoarchitectonically defined areas of the human cerebral cortex. Conventional anatomical atlases are of little help in localizing specific cortical areas, since most of them are based on a single brain and use highly observer-dependent criteria for the delineation of cortical areas. In consequence, numerous cortical maps exist which greatly differ with respect to number, position, size and extent of cortical areas. We describe a novel algorithm-based procedure for the delineation of cortical areas, which exploits the automated estimation of volume densities of cortical cell bodies. Spatial sampling of the laminar pattern is performed with density profiles, followed by multivariate analysis of the profiles' shape, which locates the cytoarchitectonic borders between neighboring cortical areas at sites where the laminar pattern changes significantly. The borders are then mapped to a human brain atlas system comprising tools for three dimensional reconstruction, visualization and morphometric analysis. A sample of brains with labeled cortical areas is warped into the reference brain of the atlas system in order to generate a population map of the cortical areas, which describes the intersubject variability in spatial conformation of cortical areas. These population maps provide a novel tool for the interpretation of images obtained with functional imaging techniques.     

Layer VII and the gray matter trajectories of corticocortical axons in rats

The trajectory of long distance intrahemispheric corticocortical axons has been investigated using the anterograde fluorescent axonal tracer fluororuby. Most axons of this kind were found to travel through the gray matter of layers VI and VII rather than in the white matter. The cell-sparse zone immediately superficial to layer VII contains a dense aggregate of longitudinally directed axons. Corticocortical axons traveling in the mediolateral plane also utilize the deep gray matter predominately. Layer VII neurons are persistent remnants of the subplate in rats. Based on our retrograde labeling results, they are involved in long distance as well as local corticocortical connections. Layer VII neurons are often labeled in a more continuous pattern after cortical injections of retrograde tracers than neurons of layers II, III and V, which are labeled in a patchy manner.     

大鼠屏状核的传入联系

采用WGA－HRP和CB－HRP法，追踪了16只大鼠屏状核的传入纤维联系，结果表明大脑皮质的躯体感觉区，视皮质及扣带皮质有细胞发出纤维投射到屏状核，后脑腹侧核，未定带，中缝背核及脑脚周核投射到屏状核，下后脑外侧核，视前大细胞核，斜角带核水平支和蓝斑青少量纤维投射到屏状核。     

A revised cytoarchitectonic map of the neocortex of the rabbit (Oryctolagus cuniculus)

Summary The cytoarchitectonic parcellation of the rabbit's neocortex has been investigated in 6 hemispheres which had been fixed by perfusion, embedded in paraffin and sectioned at either 9 m or 20 m in various planes. In addition to the classical method of microscopic observation, and automatic scanning procedure using an image analyser for measuring grey level indices was employed. By printing computer plots of various ranges of grey level indices, this method permits visualization of structural differences between various cytoarchitectonic fields. By evaluating the plots, cytoarchitectonic maps can be constructed which are based on objective data and therefore less influenced by subjective judgment than the maps obtained with the classical method. — In some regions the results based on the quantitative method are in agreement with the commonly used maps of Rose (1931), and in other regions widely at variance. It is shown, for instance, that the area striata as defined by Rose (1931) is composed of two distinct fields, viz. areas Oc 1 and 2, which are separated from each other in the rostro-caudal direction. These and other findings are described in detail, compared with the observations of Rose (1931), and related to the literature on functional localization in the rabbit's neocortex. Attention is drawn to the fact that the results obtained in 6 hemispheres leave no doubt that individual variations in size and shape of the entire hemisphere as well as of the various cytoarchitectonic fields do occur, and will have to be taken into account if cytoarchitectonic maps such as those published in the present paper are to be used in the context of experimental work.     

Commissural and intrinsic connections of the vestibular nuclei in the rabbit: a retrograde labeling study

Summary The intrinsic and commissural projection of the vestibular nuclei were investigated by means of retrograde transport of normal (HRP) and wheatgerm-agglutinated horseradish peroxidase (WGA-HRP). It was found that within each vestibular complex, the superior (SV), medial (MV) and descending (DV) vestibular nuclei are reciprocally connected. A rostrocaudally oriented column of medium-sized and large neurons, comprising the central SV and the magnocellular MV (MVmc) receives input from the surrounding neurons and does not reciprocate this projection. Efferents from group y terminate in the SV, MV and DV. The infracerebellar nucleus (INF) as well as the interstitial nucleus of the VIII the nerve (IN) supply fibers to the MV and DV. The neurons that participate in the commissural projection are distributed throughout the vestibular complex with the exception of the lateral vestibular nucleus (LV) and group x. The largest number of cells was found in the MV. The HRP labeled cells show a tendency to cluster into rostrocaudally oriented groups. Each nucleus projects to more than one contralateral nucleus. Group y shows a more extensive contralateral projection than the bordering INF. It was concluded that quantitative differences in connectivity were present between a core region in the vestibular complex and peripheral parts. This core region comprises the central SV, the LV, the MVmc and extends into the rostral DV. It receives predominantly intrinsic input from the surrounding vestibular neurons and is in contrast to these latter neurons only minimally involved in the commissural projection.Abbreviations AChE acetylcholinesterase - bc brachium conjunctivum - bp brachium pontis - CE nucleus cuneatus externus - CO nuclei cochlearis - cr corpus restiforme - DV nucleus vestibularis descendens - DX nucleus dorsalis vagi - F nucleus fastigii - flm fasciculus longitudinalis medialis - gVII genu of the nervus facialis - group x, y, f groups x, y and f of Brodal - HRP horseradish peroxidase - IA nucleus interpositus anterior - IN nucleus interstitialis of nVIII - INF nucleus infracerebellaris - L nucleus lateralis - LV nucleus vestibularis lateralis - flm fasciculus longitudinalis medialis - MV nucleus vestibularis medialis - MVc caudal MV - MVmc magnocellular MV - MVpc parvocellular MV - nV nervus trigeminus - nVI nervus abducens - nVII nervus facialis - NV par nucleus vestibularis parabrachialis - PH nucleus prepositus hypoglossi - rV ramus descendens of nV - S nucleus and tractus solitarius - sad stria acustica dorsalis - SV nucleus vestibularis superior - tu tractus uncinatus - VI nucleus abducens - VM nucleus masticatorius - VOR vestibulo-ocular reflex - VP nucleus princeps trigemini - WGA-HRP wheatgerm-agglutinated HRP - XII nucleus hypoglossus     

The cerebellar projection from the raphe nuclei in the cat as studied with the method of retrograde transport of horseradish peroxidase

Summary Following injections of horseradish peroxidase (HRP) in the cerebellar cortex and nuclei of the cat, the distribution of labeled cells in the raphe nuclei was mapped. The findings confirm those made previously in studies of retrograde cell degeneration following cerebellar ablations (Brodal et al., 1960a), and in addition reveal new details in the projection of the raphe nuclei onto the cerebellar cortex and nuclei.All the raphe nuclei except nucleus linearis intermedius and nucleus linearis rostralis project onto the cerebellar cortex. The nuclei raphe obscurus and pontis contribute the greatest number of afferents to the cerebellum.With the exception of lobule VI which probably is the recipient of a weak projection, all parts of the cerebellar cortex receive afferents from the raphe nuclei. The heaviest projection is to the vermis of lobules VIIA and X, and to crus II. The afferents to the cerebellar nuclei are few in number (Tables 2–6).The observations indicate that each raphe neuron probably projects to more than one terminal site in the cerebellum.The findings are discussed with reference to other efferent and afferent studies of the raphe nuclei. All these studies indicate that the raphe nuclei have widespread efferent and afferent connections, making them capable to participate in a variety of regulatory functions.List of abbreviations f.apm. Ansoparamedian fissure - f.icul. Intraculminate fissure - f.in.cr. Intercrural fissure - fl. Flocculus - f.pc. Preculminate fissure - f.pfl. parafloccular fissure - f.ppd. Prepyramidal fissure - f.pr. Fissura prima - f.prc. Precentral fissure - f.prc.a Precentral fissure a - f.p.l. Posterolateral fissure - f.p.s. Posterior superior fissure - f.sec. Fissura secunda - HII–HX Hemispheral lobules II–X - HVIIA cr.I, cr. II Crus I and II of lobule HVIIA - HVIIIA,B Sublobules A and B of lobule HVIII - Li Nucleus linearis intermedius - Lr Nucleus linearis rostralis - l.ans. Ansiform lobule - N.f. Nucleus fastigii - N.i.a. Nucleus interpositus anterior - N.i.p. Nucleus interpositus posterior - N.l. Nucleus lateralis - pfl.d. Dorsal paraflocculus - pfl.v. Ventral paraflocculus - Rd Nucleus raphe dorsalis - Rm Nucleus raphe magnus - Rob Nucleus raphe obscurus - Rpa Nucleus raphe pallidus - Rpo Nucleus raphe pontis - Sc Nucleus raphe centralis superior - s.int.cr.1 Intracrural sulcus 1 - s.int.cr.2 Intracrural sulcus 2 - I–VI Vermian lobules I–VI - VIIA,B Anterior and posterior sublobule of lobule VII - VIIIA,B Anterior and posterior sublobule of lobule VIII     

The limbic zone of the rabbit and rat claustrum: a study of the claustrocingulate connections based on the retrograde axonal transport of fluorescent tracers

The claustrum is a subcortical structure lying under the insular and piriform cortices, whose function is still not clear. Although data exist on connections of the claustrum and the limbic cortex, the topography of the limbic zone in the rabbit and rat claustrum has not been studied extensively. The study was performed on 17 adult Wistar rats and 12 New Zealand rabbits. Two percent water solutions of fluorescent retrograde tracers fast blue and nuclear yellow were injected into the various regions of the limbic cortex. The limbic zone is localized throughout the whole rostrocaudal extent of the claustrum, mainly in its ventromedial portion lying close to the external capsule. Although this zone of the claustrum is localized similarly in both rat and rabbit, some differences between these two species exist. In the rat, neurons projecting to all limbic areas are localized mainly in the anterior and central parts of the claustrum, whereas in the rabbit, the majority of the neurons projecting to the cingulate cortex are present in the anterior and central parts of this structure, while neurons sending axons to the retrosplenial cortex are localized in the central and posterior parts. In both species, double-labeling study showed that neurons projecting to various limbic regions are intermingled and that neurons sending axons into two different limbic regions are seen only occasionally. Our findings give support to the role of the claustrum in integrating information between different areas of the cerebral cortex and the limbic system.     

Various types of corticotectal neurons of cats as demonstrated by means of retrograde axonal transport of horseradish peroxidase

Summary The retrograde labeling of cortical neurons with horseradish peroxidase (HRP) was used to investigate the morphological features of neurons in various cortical areas projecting to the superior colliculus in the cat.Corticotectal cells were found to be labeled in layer V of the entire cerebral cortex. The number of labeled cells and their locations varied according to the sites of injections of HRP in the colliculus. Most of the Corticotectal cells identified in the present study were small (9–20 m in diameter, 66%) and medium (20–40 urn, 30%) pyramidal neurons and only 4% of them were large (more than 40 m). The labeled cells, 261 in total number, had somal diameters of 20.8±8.0 m (mean and SD). The range of sizes of the labeled neurons was different in different cortical areas. For example, the labeled neurons in the Clare-Bishop area had a greater proportion of large diameter cells than in other areas.The present findings are largely in agreement with the previous data of anterograde degeneration methods with respect to the topographical correlation of the Corticotectal projections. However, in some cortical areas, e.g., the sensorimotor and the first visual (area 17) cortex of the lateral surface of the hemisphere, relatively small numbers of Corticotectal neurons appear to have been labeled by retrogradely transported HRP. The sparsity of the labeled neurons in certain cortical areas may reflect the existence of Corticotectal neurons with axon collaterals supplying brain structures other than the superior colliculus.Abbreviations A.c. Aqueductus cerebri - AEct Gyrus ectosylvius anterior - AEs Sulcus ectosylvius anterior - AI Stratum album intermediale - AL Gyrus lateralis anterior - AP Stratum album profundum - AS Gyrus sylvius anterior - Cd Nucleus caudatus - F.l.m. Fasciculus longitudinalis medialis - GI Stratum griseum intermediale - GP Stratum griseum profundum - GS Stratum griseum superficiale - Ic Inferior colliculus - L Left - MEct Gyrus ectosylvius medius - MS Gyrus sylvius medius - MSup Gyrus suprasylvius medius - N.r. Nucleus ruber - O Stratum opticum - P Pontine nuclei - P.c. Pedunculus cerebri - PEct Gyrus ectosylvius posterior - P.g. Periaqueductal gray matter - PSigm Gyrus sigmoideus posterior - PSup Gyrus suprasylvius posterior - R Right - Sc Superior colliculus - S.n. Substantia nigra - Z Statum zonale - II Optic nerve - III and IV Motor nuclei of cranial nerves     

Afferents to the seizure-sensitive neurons in layer III of the medial entorhinal area: a tracing study in the rat

Neurons in layer III of the medial entorhinal area (MEA) in the rat are extremely vulnerable to local injections of amino-oxyacetic acid and to exprimentally induced limbic seizures. A comparable specific pathology has been noted in surgical specimens from patients with temporal lobe epilepsy. Efforts to understand this preferential neuronal vulnerability led us to study the neural input to this layer in the rat. Iontophoretic injection of the retrograde tracer fast blue, aimed at layer III of the MEA, resulted in retrogradely labeled neurons in the presubiculum in all the injected hemispheres. The nucleus reuniens thalami, the anteromedial thalamic nucleus, the ventral portion of the claustrum (endopiriform nucleus), the dorsomedial parts of the anteroventral thalamic nucleus, and the septum-diagonal band complex were labeled less frequently. In only one experiment, retrogradely labeled neurons were observed in the ventrolateral hypothalamus and in the brainstem nucleus raphe dorsalis. Since projections from claustrum to the entorhinal cortex has not been studied in the rat with modern sensitive anterograde tracing techniques, iontophoretic injections of the anterograde tracer Phaseolus vulgaris-leucoagglutinin were placed into the ventral portion of the claustrum. Anterogradely labeled fibers in the entorhinal area proved not to be confined to the MEA, since a prominent projection distributed to the lateral entorhinal area as well. In both areas, the densest terminal labeling was present in layers IV–VI, whereas layer III appeared to be only sparsely labeled. The present data indicate that of all potential afferents only those from the presubiculum distribute preferentially to layer III of the MEA. This, in turn, suggests a potentially important role of the presubiculum in the seizure-related degeneration of neurons in layer III of the MEA.     

Efferent connections of the medial prefrontal cortex in the rabbit

The different cytoarchitectonic regions of the medial prefrontal cortex (mPFC) have recently been shown to play divergent roles in associative learning in rabbits. To determine if these subareas of the mPFC, including areas 24 (anterior cingulate cortex), 25 (infralimbic cortex), and 32 (prelimbic cortex) have differential efferent connections with other cortical and subcortical areas in the rabbit, anterograde and retrograde tracing experiments were performed using thePhaseolus vulgaris leukoagglutinin (PHA-L), and horseradish peroxidase (HRP) techniques. All three areas showed local dorsal-ventral projections into each of the other areas, and a contralateral projection to the homologous area on the other side of the brain. All three also revealed a trajectory through the striatum, resulting in heavy innervation of the caudate nucleus, the claustrum, and a lighter projection to the agranular insular cortex. The thalamic projections of areas 24 and 32 were similar, but not identical, with projections to the mediodorsal nucleus (MD) and all of the midline nuclei. However, the primary thalamic projections from area 25 were to the intralaminar and midline nuclei. All three areas also projected to the ventromedial and to a lesser extent to the ventral posterior thalamic nuclei. Projections were also observed in the lateral hypothalamus, in an area just lateral to the descending limb of the fornix. Amygdala projections from areas 32 and 24 were primarily to the lateral, basolateral and basomedial nuclei, but area 25 also projected to the central nucleus. All three areas also showed projections to the midbrain periaqueductal central gray, median raphe nucleus, ventral tegmental area, substantia nigra, locus coeruleus and pontine nuclei. However, only areas 24 and the more dorsal portions of area 32 projected to the superior colliculus. Area 25 and the ventral portions of area 32 also showed a bilateral projection to the parabrachial nuclei and dorsal and ventral medulla. The dorsal portions of area 32, and all of area 24 were, however, devoid of these projections. It is suggested that these differential projections are responsible for the diverse roles that the cytoarchitectonic subfields of the mPFC have been demonstrated to play in associative learning.     

The character and influence of the claustral pathway to the striate cortex of the cat

Summary 1. In paralyzed and anaesthetized cats, the pathway running from the claustrum to the striate cortex was characterized from the transynaptic latencies of responses that were initiated by electrical stimulation in the claustrum (CL) and recorded extra-cellularly in single striate neurons. A second stimulating electrode (OR₁) in the primary visual pathway provided information on the input coming to the recorded cell from the lateral geniculate nucleus. 2. An analysis of the classified striate neurons receiving a claustral drive revealed that 68% were C cells and 26% were S cells. For the C cells, 81% had CL latencies of less than 2.5 ms (mean = 1.8 ms) and the potential to receive a direct drive from a fast conducting input; the remaining 19% had latencies around 3.0 ms (mean = 3.0 ms), a value consistent with a disynaptic input from the same type of input. 3. From their CL latencies, the S cells also could be subdivided into two subgroups; one, made up of 36% of the sample had CL latencies of less than 2.5 ms (mean = 1.9 ms) and the capacity, like the majority of C cells, to receive a direct, fast-conducting input; the second subgroup, consisting of 74% of the S cells, had CL latencies longer than 3.0 ms (mean = 5.4 ms). 4. The majority of cells with a claustral-drive (85%) were encountered either in laminae 4 or 6. Claustral-driven cells belonging to both S and C catagories were found in the two laminae (4 and 6) and there was no observed predisposition for a particular cell type to cluster in either of these lamina. 5. From a comparison of CL and OR₁ latencies, justified on the grounds of independent stimulation, a strict correlation was found for signal conduction properties in the claustral and LGN pathways running to a given striate neuron. 6. From a quantitative evaluation of receptive field properties the claustral-driven striate neurons were found to resemble cells in the general population. As a group, however, they were distinctive in that both end-zone inhibition and direction selectivity were either weak or absent from the cell's response. This finding held for cells in both the C and the S categories. 7. It is concluded from the high incidence of claustral-driven C cells, that the claustral loop from the striate cortex is involved in an aspect of motion detection.     

Efferent connections of the medial prefrontal cortex in the rabbit

The different cytoarchitectonic regions of the medial prefrontal cortex (mPFC) have recently been shown to play divergent roles in associative learning in rabbits. To determine if these subareas of the mPFC, including areas 24 (anterior cingulate cortex), 25 (infralimbic cortex), and 32 (prelimbic cortex) have differential efferent connections with other cortical and subcortical areas in the rabbit, anterograde and retrograde tracing experiments were performed using the Phaseolus vulgaris leukoagglutinin (PHA-L), and horseradish peroxidase (HRP) techniques. All three areas showed local dorsal-ventral projections into each of the other areas, and a contralateral projection to the homologous area on the other side of the brain. All three also revealed a trajectory through the striatum, resulting in heavy innervation of the caudate nucleus, the claustrum, and a lighter projection to the agranular insular cortex. The thalamic projections of areas 24 and 32 were similar, but not identical, with projections to the mediodorsal nucleus (MD) and all of the midline nuclei. However, the primary thalamic projections from area 25 were to the intralaminar and midline nuclei. All three areas also projected to the ventromedial and to a lesser extent to the ventral posterior thalamic nuclei. Projections were also observed in the lateral hypothalamus, in an area just lateral to the descending limb of the fornix. Amygdala projections from areas 32 and 24 were primarily to the lateral, basolateral and basomedial nuclei, but area 25 also projected to the central nucleus. All three areas also showed projections to the midbrain periaqueductal central gray, median raphe nucleus, ventral tegmental area, substantia nigra, locus coeruleus and pontine nuclei. However, only areas 24 and the more dorsal portions of area 32 projected to the superior colliculus. Area 25 and the ventral portions of area 32 also showed a bilateral projection to the parabrachial nuclei and dorsal and ventral medulla. The dorsal portions of area 32, and all of area 24 were, however, devoid of these projections. It is suggested that these differential projections are responsible for the diverse roles that the cytoarchitectonic subfields of the mPFC have been demonstrated to play in associative learning.Abbreviations ACC anterior cingullate cortex - ACN amygdaloid central nucleus - AD anterodorsal nucleus of thalamus - AIC, Iag agranular insular cortex - AM anteromedial nucleus of thalamus - AMG amygdala - AV anteroventral nucleus of thalamus - BL basolateral nucleus of amygdala - BM basomedial nucleus of amygdala - CdN, CD caudate nucleus - CL claustrum - CN centromedian nucleus of thalamus - D MV, DVM dorsal motor nucleus of vagus - IC internal capsule - L lateral nucleus of amygdala - LC locus coeruleus - LH lateral hypothalamus - MB mammillary bodies - MDN mediodorsal nucleus of thalamus - mPFC medial prefrontal cortex - MRN, R median raphe nucleus - MV medioventral nucleus of thalamus - NA nucleus ambiguus - NTS nucleus of solitary tract - PAG periaqueductal central gray - PAV, PV para ventricular nucleus of thalamus - PC paracentral nucleus of thalamus - PF parafascicular nucleus of thalamus - PN,LP pontine nuclei - PS posterior subiculum - PS CG posterior cingulate cortex - PT paratenial nucleus of thalamus - Put putamen - ReN nucleus reuniens of thalamus - RF reticular formation - RN reticular nucleus of thalamus - RhN rhomboid nucleus of thalamus - RS CX retrosplenial cortex - S septum - SC superior colliculus - SN substantia nigra - tt tenia tecta - VL ventrolateral nucleus of thalamus - VM ventromedial nucleus of thalamus - VP ventroposterior nucleus of thalamus - VTA ventral tegmental area     

The afferent connections of the inferior olivary complex in rats: A study using the retrograde transport of horseradish peroxidase

Retrograde transport of horseradish peroxidase (HRP) was used to define the origin of afferents to the inferior olivary complex (IOC) in rats. Using both ventral and dorsal surgical approaches to the brainstem, HRP was injected into the IOC through a micropipette affixed to the tip of a 1-μl Hamilton syringe. After a 2-day postoperative survival, animals were sacrificed by transcardiac perfusion with a 1% paraformaldehyde-1.25% gluteraldehyde solution, and brains were processed according to the DeOlmos protocol (1977), using o-dianisidine as the chromogen. Labeled cells were found at many levels of the nervous system extending from lumbar spinal cord to cerebral cortex. This wide-ranging input from numerous regions clearly underscores the complexity of the IOC and its apparent involvement in several functions. Within the spinal cord, labeled neurons were identified from cervical to lumbar but not at sacral levels. These neurons were found contralaterally in the neck region of the dorsal horn and in the medial portions of the intermediate gray. In the caudal brainstem, reactive cells in the dorsal column nuclei, the spinal trigeminal nucleus, and the subnucleus y of the vestibular complex were observed primarily contralateral to the injection sites. Labeling within the gigantocellular, magnocellular, ventral, and lateral reticular nuclei and the nucleus prepositus hypoglossi was primarily ipsilateral. Reactive neurons in the medial and inferior vestibular nuclei were predominantly ipsilateral or contralateral to HRP injections into the caudal or rostral IOC, respectively. The dentate and interposed nuclei of the cerebellum contained small, lightly labeled neurons primarily contralateral to the injection site, while the fastigial nuclei contained a few relatively large, heavily labeled cells bilateral to caudal olivary injections. Ipsilaterally labeled mesencephalic regions included the periaqueductal gray, interstitial nucleus of Cajal, rostromedial red nucleus, ventral tegmental area, medial terminal nucleus of the accessory optic tract, nucleus of the optic tract, and the lateral deep mesencephalic nucleus. The caudal part of the pretectum and small cells of the stratum profundum of the superior colliculus were labeled predominantly contralateral to the injection. In the caudal diencephalon labeled neurons were most numerous within the nucleus of Darkschewitsch and the subparafascicular nucleus, primarily ipsilateral to olivary injections. Scattered reactive neurons were also found within the ipsilateral zone incerta. With the exception of the zona incerta, all labeled mesencephalic and diencephalic nuclei had some bilateral representation of labeled cells. No labeled neurons were identified within the basal ganglia, while numerous reactive cells were found bilaterally within layer V of the frontal and parietal cerebral cortex.     

The ontogenetic development of serotonin (5-HT1) receptors in various cortical regions of the rat brain

Summary The distribution of serotonin (5-HT₁) receptors in various cortical regions of the rat brain has been examined during ontogenesis by quantitative autoradiography.An increase in binding site density between the first postnatal day and adult age was observed and could be approximated by a sigmoid shaped (logistic) growth curve. A marked heterochrony in the increase of binding site density is found in the 13 analyzed cortical regions. Binding sites develop earlier in neocortex than in allocortical areas. Fifty pereent of the binding site density of adult age is reached in the motor cortex at the 9th postnatal day, followed by the primary somatosensory cortex one day later, by the medial prefrontal cortex on the 12th day, by the fascia dentata on the 14th day and by the CA1-region on the 20th day. A detailed analysis of the frontal, medial prefrontal and hippocampal regions also shows a heterochrony within these regions. Adult values of binding site densities are also reached at different ages in the various cortical regions. The highest receptor densities were observed in the dorsal subiculum, the lowest in the primary somatosensory cortex.