摘要:

AbstractAutoradiographic, axonal degeneration, and horseradish peroxidase fiber tracing methods were employed to investigate the organization, development and potential plasticity of the thalamocortical projection to the somatic sensory cortex of the rat. In the adult animal, thalamocortical terminals are concentrated primarily in layers I and IV and in the upper part of layer VI. Fibers terminating in layers IV and VI arise from a different thalamic region than those terminating in layer I. Discrete clusters of fibers and terminals 250–450 μm wide are distributed only to the parts of the SI cortex containing dense aggregates of layer IV granule cells and not to the intervening, less granular and commissurally connected zones.At birth, thalamocortical fibers have invaded the deep part of the developing SI cortex and are concentrated in the upper part of layer VI. Between the age of two and three days, an additional concentration of fibers appears in the part of the cortical plate which will become layer IV. Layer IV is clearly recognizable by three days of age and the dense granule cell aggregates appear in it no more than one day later. The ingrowth of commissural fibers (Wise and Jones, '76) lags behind that of thalamic fibers. The mature commissural fiber pattern is not established until the age of seven days.After removal of the developing thalamocortical system by thalamotomy in newborn rats, subsequent investigation of the commissural system in the adult showed that no commissural fibers or terminals had invaded either laminae or zones of the cortex deprived of thalamic input. Similarly, commissurotomy at birth was not followed by sprouting of thalamic fibers into zones or laminae deprived of commissural connections. The connectional specificity observed in these neocortical fiber systems contrasts markedly with the plasticity of connections reported in allocortical systems.Removal of thalamocortical afferents before they attain their definitive distribution does not radically effect the overall development of the dense granule cell aggregates in layer IV. Within the aggregates, however, subsidiary features such as the “barrels” fail to appear. This finding suggests that certain elements of cortical architecture such as the dense granule cell aggregates are independent of thalamic afferents while others, such as the barrels, result from the interaction of the developing thalamocortical fibers and/or terminals with maturing n

ISSN:0092-7317    

DOI:10.1002/cne.901780202

出版商:Wiley Subscription Services, Inc., A Wiley Company    

年代:1978

数据来源: WILEY

摘要:

AbstractSmall amounts of3H‐leucine were injected into discrete regions in the rostral medulla of the cat. Descending projections from these sites were studied with autoradiographic methods. On the basis of differential projections to the medulla and spinal cord, three distinct regions were delineated. Nucleus reticularis gigantocellularis (Rgc), located dorsally in the medullary reticular formation, projects primarily to “motor” related sites, including cranial motor nuclei VI, VII, XII, nucleus intercalatus, and a part of the ipsilateral medial accessory olive. The projection to the spinal cord is primarily via the ipsilateral ventrolateral and contralateral ventral funiculi. The Rgc terminal field is in lamina VII and VIII ipsilateral and lamina VIII contralateral to the injection site. In contrast, nucleus raphe magnus, (NRM) located ventrally, in the midline of the rostral medulla projects primarily to structures with known nociceptive and/or visceral afferent input. These sites include the solitary nucleus, the dorsal motor nucleus (X) and the marginal and gelatinous layers of the spinal trigeminal nucleus caudalis. The projection to the spinal cord is bilateral, via the dorsolateral funiculus. Terminal fields are found in the marginal zone and the substantia gelatinosa of the dorsal horn, and more deeply in lamina V, medial VI and VII. Nucleus reticularis magnocellularis (Rmc), located lateral to NRM and ventral to Rgc, has an overlapping projection with NRM, but the projection is ipsilateral. This difference between Rmc and Rgc is correlated with cytoarchitectural features of the two regions. The possibility that the raphe‐spinal pathway in the DLF mediates opiate and brain stimulation‐produced analgesia is

ISSN:0092-7317    

DOI:10.1002/cne.901780203

出版商:Wiley Subscription Services, Inc., A Wiley Company    

年代:1978

数据来源: WILEY

摘要:

AbstractThe efferent fiber connections of the nuclei of the amygdaloid complex with subcortical structures in the basal telencephalon, hypothalamus, midbrain, and pons have been studied in the rat and cat, using the autoradiographic method for tracing axonal connections. The cortical and thalamic projections of these nuclei have been described in previous papers (Krettek and Price, ′77b,c). Although the subcortical connections of the amygdaloid nuclei are widespread within the basal forebrain and brain stem, the projections of each nucleus have been found to be well defined, and distinct from those of the other amygdaloid nuclei.The basolateral amygdaloid nucleus projects heavily to the lateral division of the bed nucleus of the stria terminalis (BNST), to the caudal part of the substantia innominata, and to the ventral part of the corpus striatum (nucleus accumbens and ventral putamen) and the olfactory tubercle; it projects more lightly to the lateral hypothalamus. The central nucleus also projects to the lateral division of the BNST and the lateral hypothalamus, but in addition it sends fibers to the lateral part of the substantia nigra and the marginal nucleus of the brachium conjunctivum. The basomedial nucleus has projections to the ventral striatum and olfactory tubercle which are similar to those of the basolateral nucleus, but it also projects to the core of the ventromedial hypothalamic nucleus and the premammillary nucleus, and to a central zone of the BNST which overlaps the medial and lateral divisions. The medial nucleus also projects to the core of the ventromedial nucleus and the premammillary nucleus, but sends fibers to the medial division of the BNST and does not project to the ventral striatum. The posterior cortical nucleus projects to the premammillary nucleus and to the medial division of the BNST, but a projection from this nucleus to the ventromedial nucleus has not been demonstrated. Projections to the “shell” of the ventromedial nucleus have been found only from the ventral part of the subiculum and from a structure at the junction of the amygdala and the hippocampal formation, which has been termed the amygdalo‐hippocampal area (AHA). The AHA also sends fibers to the medial part of the BNST and the premammillary nucleus.Virtually no subcortical projections outside the amygdala itself have been demonstrated from the lateral nucleus, or from the olfactory cortical areas around the amygdala (the anterior cortical nucleus, the periamygdaloid cortex, and the posterior prepiriform cortex). However, portions of the endopiriform nucleus deep to the prepiriform cortex project to the ventral putamen, and to the lateral hypot

ISSN:0092-7317    

DOI:10.1002/cne.901780204

出版商:Wiley Subscription Services, Inc., A Wiley Company    

年代:1978

数据来源: WILEY

摘要:

AbstractThe cytoarchitectonic structure and divisions of the amygdaloid complex are described in the rat and cat, with special reference to the axonal connections of each of the amygdaloid nuclei, and to interspecies variations and similarities. Several intra‐amygdaloid connections are also described, based on autoradiographic experiments with small injections of3H‐amino acids into the individual nuclei. Although it has probably not been possible to determine all of the intra‐amygdaloid projections from these experiments, the connections which have been shown are very specific. The lateral nucleus projects to the basomedial nucleus, the lateral part of the central nucleus, and the periamygdaloid cortex, while the basolateral nucleus projects only to itself, the medial part of the central nucleus, and the nucleus of the lateral olfactory tract. The basomedial nucleus projects to the cellular layer of the medial nucleus and the amygdalo‐hippocampal area, while the molecular layer of these structures and of the posterior cortical nucleus, receives projections from the periamygdaloid cortex or from the endopiriform cortex. There are also interconnections between the medial and posterior cortical nuclei, and commissural connections between the posterior cortical nuclei of the tw

ISSN:0092-7317    

DOI:10.1002/cne.901780205

出版商:Wiley Subscription Services, Inc., A Wiley Company    

年代:1978

数据来源: WILEY

摘要:

AbstractIn order to test the hypothesis that thalamic efferents of trigeminal nucleus caudalis (NC) are the cranial analogue of the spinothalamic system, lesion and autoradiographic studies were carried out in the squirrel monkey, and the terminal projection fields in thalamus were noted. Results showed that NC, including lateral reticular formation (LRF), projects to contralateral VPM, the VPM‐VPL border and medial VPL, and a region dorsal to ventroposterior nucleus (VP) proper which contains cells larger than those in VPM yet which stain as darkly as VPL neurons; this latter zone of termination may be homologous with VPLo(Vim) in other species, which is that area receiving lemniscal and cerebellar afferents (Mehler, '71; Walsh and Ebner, '73; Boivie, '74). In addition, a small projection is noted in an area intercalated between dorsomedial MG, limitans nucleus and posterior VP which closely agrees with the medial division of Posterior nucleus (Po) described in rhesus and squirrel monkey (Burton and Jones, '76). No terminations were observed in the gustatory nucleus medial to VPM.Bilateral, terminal projection fields were observed in posterior mediodorsal nucleus (MD), and a paralaminar area (PL) which lies in the ventrolateral strip of MD and is particularly prominent in primates; other bilateral fields were noted in CL, particularly the more medial segment of the nucleus. A sparse projection was noted in contralateral CM. Ipsilateral, intratrigeminal connections between NC and main sensory nucleus (MSV) also were observed.We conclude that, in the squirrel monkey, NC efferents, probably including LRF, may be considered analagous to the spinothalamic system by virtue of terminations in older medial and newer ventroposterior thalamus. Terminations in posterior MD may be specific toPrimates. Moreover, projections to an area just dorsal to VP proper in squirrel monkey may be included within the broader definition of a neo‐spinothalamic area as reflected in spinothalamic tract projections to the ventrolateral complex in cat (Boivie, '71b; Jones and Burton, '74). The small NC projection to a part of Po is consistent with spinothalamic terminations to a “posterior” thalamic area in other primates (Mehler, '69), and with the suggestion that medial Po transmits pain information (Burton and Jone

ISSN:0092-7317    

DOI:10.1002/cne.901780206

出版商:Wiley Subscription Services, Inc., A Wiley Company    

年代:1978

数据来源: WILEY

摘要:

AbstractWe reported previously that the effects of monocular deprivation on cat striate cortex cells can be partially reversed after the critical period by enucleation of the experienced eye (Kratz et al., '76). The enucleation resulted in a rapid (less than 12 hours) increase in the percent of cells which responded to the deprived eye; however, the receptive field properties of the responsive cells were abnormal. There was no change in this result if the animals were allowed to survive 3 to 16 months after the enucleation, during which the deprived eye remained closed. The present study investigated whether enucleation of the experienced eye extends the period of sensitivity during which connections from the deprived eye can be modified by visual experience. That is, we asked whether opening the deprived eye and allowing it normal visual experience after enucleation of the experienced eye would lead to a further increase in the percentage of responsive cells or produce a modification of receptive field properties.Using single‐cell recording in striate cortex, comparisons were made between monocularly deprived control kittens (MD), kittens which had the experienced eye enucleated at four months of age while the deprived eye remained closed (MD‐DE) or was opened (MD‐DE‐O) for an additional three to four months, and kittens which received reverse‐suture at the same age and for the same duration (MD‐RS). Kittens in both the MD‐DE and MD‐DE‐O groups showed an increase in the percent of cells responsive to the deprived eye compared to MD control kittens, replicating our previous findings. However, there were no differences between the MD‐DE and MD‐DE‐O groups either in terms of percent responsive cells or in the receptive field properties of those which responded. Reverse‐suture also produced a significant, although variable, increase in the percent of cells responding to the initially deprived eye. However, this increase was significantly less than that produced by enucleation of the experienced eye in MD‐DE and MD‐DE‐O animals. Among the cells responsive to the initially deprived eye in the reverse‐suture animals, the receptive field properties remained abnormal.These results suggest that binocular interactions continue to play an active role in the effects of monocular deprivation after the previously defined critical period. However, reversal procedures such as suture or enucleation of the experienced eye do not extend the period in development during which cells in striate cortex can be modified by visual experience. Rather, they may simply release those cells already receiving anatomical connections from the deprived eye from a tonic inhibitio

ISSN:0092-7317    

DOI:10.1002/cne.901780207

出版商:Wiley Subscription Services, Inc., A Wiley Company    

年代:1978

数据来源: WILEY

摘要:

AbstractNeurons descending from the midbrain to the spinal cord in the monkey were identified with the retrograde horseradish peroxidase technique. Beginning in the caudal midbrain and extending anteriorly beneath the superior colliculus, large numbers of neurons of the nucleus cuneiformis and lateral central gray were found to project ipsilaterally to the spinal cord. In the posterolateral superior colliculus, neurons of the intermediate and deep layers, stratum griseum intermediale and stratum griseum profundum, were found to give rise to contralateral projections to the upper cervical spinal segments. An ipsilateral tectospinal projection from the anteromedial part of the collicus may also exist. In the red nucleus, neurons of the magnocellular division were shown to give rise to a somatotopically organized projection to the upper cervical cord and spinal enlargements. No neurons of the parvocellular red nucleus were labeled from the spinal cord. In the anterior midbrain, neurons of the interstitial nucleus of Cajal, nucleus of Darkschewitsch, and the adjacent dorsomedial and ventromedial midbrain tegmentum were found to give rise to an extensive ipsilateral descending spinal projection. Neurons located in various midline nuclei including the supratrochlear nucleus, oculomotor nucleus, Edinger‐Westphal nucleus, and the ventral part of the central gray were also labeled from the spinal cord. These findings indicate that the primate midbrain is the origin of an extensive system of descending spinal pathways, some of which are likely to be involved in mediating descending influences involved in complex motor and sensory behavio

ISSN:0092-7317    

DOI:10.1002/cne.901780208

出版商:Wiley Subscription Services, Inc., A Wiley Company    

年代:1978

数据来源: WILEY

摘要:

AbstractThe population and density of the bipolar ganglion cells and sensory hair cells were determined from serial sections and graphic reconstructions of the cochlea and spiral ganglion of four little brown bats. The spiral ganglion lacks a bony canal and is a one and one‐half turn spiral of almost uniform thickness which ends in a broad flat nodule at its apex. The average length of the nerve cell body is 7.4 μ (range: 5–15 μ) and it is 6.4 μ wide (5–10 μ). The average number of ganglion cells enumerated was 63.2 × 103(range: 60.6 × 103–65.2 × 103) and following correction for “split cell error,” the total number was 55.3 × 103ganglioncells. The ganglion cell density curve increases gradually to a maximum value of 11.7 × 103cells/mm2at 2.4–3.2 mm from the basal end. The two and one‐half turn cochlea is 6.9 mm long (6.8–7.1 mm) with an estimated total of 700 inner and 2,800 outer sensory hair cells. The densities of outer and inner hair cells increase from the base to the apex by 21% and 32%, respectively. However, the density of sensory cells per unit of sensory epithelium decreases from base to apex. The ratio increases to a maximum value of 22:1 at 2.4 mm and then declines toward the apex. The significance of these findings is discussed and compared to similar studies on other high

ISSN:0092-7317    

DOI:10.1002/cne.901780209

出版商:Wiley Subscription Services, Inc., A Wiley Company    

年代:1978

数据来源: WILEY

摘要:

AbstractThe ventral nerve cord ofBranchiobdella pentodontaconsists of paired ganglia containing three different types of neurons, a central neuropil showing characteristic synapses and of an intersegmental apparatus made up of two large lateral connectives and a smaller ventral one. Some remarkable differences exist between the ventral nerve cord and that found in other oligochaetes; these include the presence of a large dorsal blood vessel, two dorsal muscular cells per metamere, and supportive glial cells ventral to the neuropil which have long transverse processes coming into contact with the segmental nerves.

ISSN:0092-7317    

DOI:10.1002/cne.901780210

出版商:Wiley Subscription Services, Inc., A Wiley Company    

年代:1978

数据来源: WILEY

ISSN:0092-7317    

DOI:10.1002/cne.901780211

出版商:Wiley Subscription Services, Inc., A Wiley Company    

年代:1978

数据来源: WILEY