家兔皮质脊髓束投射神经元的分布

将辣根过氧化物酶（ＨＲＰ）分别注入家兔脊髓单侧颈、胸、腰等不同节段，以显示皮质脊髓束投射神经元的分布。结果表明，大脑皮质的ＨＲＰ标记神经元仅见于颈段注入例，而胸段和腰段注入例未见到皮质标记神经元。标记的皮质脊髓束投射神经元主要分布于注入侧对侧的额叶无颗粒型皮质和顶叶颗粒型皮质，并呈现为３个分隔的标记细胞密集区，分别位于额叶皮质吻侧端的内侧部、邻近前囟的额顶叶皮质、顶叶皮质的外侧部。标记神经元呈柱状     

The origin of corticospinal projection neurons in rat

Summary The distribution of corticospinal projection neurons in adult rats was determined using a retrograde tracing technique. Horseradish peroxidase (HRP) and an emulsifier (Nonidet) were injected into the 5th and 6th segments of the cervical spinal cord. The greatest concentrations of HRP-positive neurons were distributed in area 4 and rostral area 6/8 (motor cortices) and medial area 3 and caudal area 2 (somatosensory cortices). The largest labeled neurons were in areas 4 and 3. HRP-positive neurons were absent or few in regions of motor and somatosensory fields which contained the face representation. Less dense concentrations of retrogradely labeled neurons were also in posterior parietal and association areas 14, 39 and 40, rostral occipital visual areas 18a and 18b, and anterior cingulate and prefrontal areas 24a, 24b, and 32. The topography of the corticospinal pathway was determined by injecting HRP without Nonidet into the cervical, upper thoracic, lower thoracic, or lumbar spinal cord. Although the distribution of labeled neurons decreased with distance down the spinal cord, the size of the corticospinal neurons in each cytoarchitectonic area was not significantly different regardless of where the injection was placed. For example, upper thoracic cord injections retrogradely labeled neurons in each of the regions containing neurons filled by cervical cord injections, however, lumbar injections retrogradely labeled neurons only in caudal areas 4 and 3 and in area 18b. The distribution of corticospinal neurons in rats is similar to the organization of the corticospinal system in higher animals. The origin of corticospinal neurons in occipital and cingulate cortices may be related to visuomotor and visceromotor control.     

Somatotopic organization of corticospinal and corticotrigeminal neurons in the rat

The method of retrograde axonal transport of horseradish peroxidase was employed to examine the topographic organization of corticospinal and corticotrigeminal neurons in the rat. In both the first somatic sensory (SI) area and the motor (MI) area of the cortex these labeled corticofugal neurons, all of which are found in layer V, are grouped in a well organized, somatotopic pattern. Corticospinal projections which extend to lumbar levels of the spinal cord originate only from neuronal somata located in the hindlimb representation of SI and MI. Those neurons projecting to the cervical enlargement have somata mainly in the forelimb representation of SI and MI and the ventrolateral part of the trunk representation within SI. Cortical projections to the rostral cervical spinal segments appear to originate mainly from the neck and posterior head representations of SI and MI, though this conclusion is clearest for SI. Finally, neurons located exclusively within the head, muzzle, and vibrissal representation of SI project to the spinal trigeminal complex. Corticofugal neurons near the frontal pole and in an area of cortex ventrolateral to SI also project to the spinal cord. The areas involved are probably homologous to the supplementary motor (MII) and second somatic sensory (SII) areas respectively. The corticospinal and corticotrigeminal projections from these areas also appear to be organized in a somatotopic manner.It is concluded that in the rat, as in other species, the corticospinal and corticotrigeminal neurons in the sensorimotor cortex are arranged somatotopically. The somatotopic pattern found correlates remarkably well with that determined by single unit, evoked potential and cortical stimulation techniques.     

Distribution of corticospinal neurons with collaterals to the lower brain stem reticular formation in monkey (Macaca fascicularis)

Summary An earlier retrograde double-labeling study in cat showed that up to 30% of the corticospinal neurons in the medial and anterior parts of the precruciate motor area represent branching neurons which project to both the spinal cord and the reticular formation of the lower brain stem. These neurons were found to be concentrated in the rostral portion of the motor cortex, from where axial and proximal limb movements can be elicited. In the present study the findings in the macaque monkey are reported. The fluorescent retrograde tracer DY was injected unilaterally in the spinal cord at C2 and the fluorescent tracer FB was injected ipsilaterally in the medial tegmentum of the medulla oblongata. In the contralateral hemisphere large numbers of single DY-labeled corticospinal neurons and single FBlabeled corticobulbar neurons were present. A substantial number of DY-FB double-labeled corticospinal neurons were also found, which must represent branching neurons projecting to both the spinal cord and the bulbar reticular formation. These neurons were present in: 1. The anterior portion of the cingulate corticospinal area in the lower bank of the cingulate sulcus; 2. The supplementary motor area (SMA); 3. The rostral part of precentral corticospinal area; 4. The upper portion of the precentral face representation area; 5. The caudal bank of the inferior limb of the arcuate sulcus; 6. The posterior part of the insula. In these areas 10% to 30% of the labeled neurons were double-labeled. The functional implications of the presence of branching corticospinal neurons in these areas is discussed.Abbreviations A nucleus ambiguus - AS arcuate sulcus - C cuneate nucleus - Cing. S. cingulate sulcus - corp. call. corpus callosum - CS central sulcus - Cx external cuneate nucleus - DCN dorsal column nuclei - dl dorsolateral intermediate zone - IO inferior olive - IP intraparietal sulcus - Lat. Fis. lateral fissure - LR lateral reticular nucleus - LS lunate sulcus - ML medial lemniscus - MLF medial longitudinal fascicle - mn motoneuronal pool - MRF medial reticular formation - Occ. occipital pole - P pyramid - PG pontine grey - PS principle sulcus - RB restiforme body - RF reticular formation - S solitary nucleus - SPV spinal trigeminal complex - STS superior temporal sulcus - Sup. Col. superior colliculus - TB trapezoid body - VC vestibular complex - vm ventromedial intermediate zone - III nucleus oculomotorius - VI nucleus abducens - VII nucleus, n. facialis - X motor nucleus n. vagus - XII nucleus hypoglossus Supported in part by grant 13-46-96 of FUNGO/ZWO (Dutch organisation for fundamental research in medicine)     

Prefrontal cortex of the cat: Paucity of afferent projections from the parietal cortex

Summary Twenty-one cat brains with cortical injections of horseradish peroxidase resulting in labelled cells in the thalamic mediodorsal nucleus (MD) were screened for afferent projections from the parietal cortex. Contrary to expectation, nearly the whole prefrontal cortex (PFC) situated around the frontal pole was free of parietal afferents, while a small area in the anterior sylvian gyrus (orbito-insular subregion of PFC) consistently received afferents from the parietal cortex. The few afferents projecting to the cortex around the frontal pole originated exclusively from the convexity of the suprasylvian gyrus, while the great majority of the parietal neurons projecting to the anterior sylvian gyrus was situated within the fundus of the suprasylvian sulcus. While the main regions of the prefrontal cortex of the rhesus monkey receive a substantial projection from the parietal lobe, whereas the main regions of the cat's prefrontal cortex are free of afferents from the parietal cortex, possible differences in the parieto-prefrontal organization of both species are discussed. Furthermore, differences between the orbito-insular subregion and the rest of the PFC are emphasized.This study was carried out mainly at the University of Konstanz.Dr. B. Petrovi-Mini was a visiting scientist at the University of Konstanz. Research was supported in part by grant Ma 795 from the Deutsche Forschungsgemeinschaft (DFG)     

The efferent projections of neurons in the white matter of different cortical areas of the adult rat

Summary Injection of Fast Blue into different cortical areas (frontal, parietal, anterior and posterior cingulate cortex) revealed that neurons in the white matter (interstitial neurons) give rise to association fibers which project mostly to the gray matter of the overlying cytoarchitectonic area, but which may extend also over different cytoarchitectonic areas. The rostrocaudal extent of the projecting axons was up to 1 mm in the frontal and parietal cortex, and up to 3.5 mm in the cingulate cortex. Concurrent processing for dihydronicotinamide adenine dinucleotide phosphate diaphorase (NADPH-d) histochemistry showed that 70% of cortically projecting interstitial neurons were NADPH-d-positive. An analysis of neuronal morphology suggests that the Fast-Blue-labeled, NADPH-d-negative neurons may represent displaced pyramidal neurons of layer VIb; the Fast-Bluelabeled and NADPH-d-positive neurons have bipolar or multipolar dendritic trees, constituting a population of nonpyramidal interstitial neurons that project into the cortical gray matter.     

Alpha calcium/calmodulin-dependent protein kinase II immunoreactivity in corticospinal neurons: combination of axonal transport method and immunofluorescence

A combination of either retrograde or anterograde fluorescent tracer and immunofluorescence histochemistry using the monoclonal antibody specific for the alpha isoform of calcium/calmodulin-dependent protein kinase II (CaM kinase II) was employed to test whether CaM kinase II is expressed in somata of corticospinal neurons and their axons over their whole course. After the injection of carbocyanine dye DiI into the hindlimb area of the primary motor cortex of the rat, corticospinal axons and their terminal arbors were anterogradely labeled: DiI-labeled corticospinal fibers proceeded caudally in the ipsilateral internal capsule, cerebral peduncle and medullary pyramid, crossed at the pyramidal decussation and descended in the ventralmost area of the contralateral dorsal funiculus of the spinal cord. These DiI-labeled corticospinal axons expressed strong CaM kinase II immunoreactivity along their course. However, their terminal arbors within the gray matter of the lumbar cord were very weakly immunostained. With the injection of Fast Blue into the lumbar enlargement of the rat, somata of corticospinal neurons in layer V of the motor cortex were retrogradely labeled. The subsequent immunofluorescent histochemistry revealed that more than 80% of Fast Blue-labeled corticospinal neurons were immunostained with CaM kinase II antibody. The present immunohistochemical study demonstrated that CaM kinase II is strongly expressed in both somata and axons of a majority of corticospinal neurons, although we could not detect this enzyme in the corticospinal terminals in the spinal target areas.     

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     

Cortical neurons projecting to the pontine nuclei in the cat. An experimental study with the horseradish peroxidase technique

Summary Horseradish peroxidase (HRP) injections in various portions of the cat pontine nuclei resulted in retrograde labeling of neurons in layer V of the ipsilateral cerebral cortex.Corticopontine neurons, pyramidal in type, have been found to be labeled in the entire cortex, confirming the previous findings of anterograde degeneration studies. Most (91%) of the labeled cells were 14–26 m in diameter (mean 19.4±4.5 m SD). Small (10–20 m) and medium (20–40 m) cells represent 51.5% and 47.7%, respectively, of the total number of the labeled neurons. The populations of the neurons of various sizes were almost identical in different cortical areas, and were different from the populations of corticoreticular and corticospinal cells.Corticopontine cells were well labeled in experimental cases of 3-days' survival time, confirming the topographical organization established previously by degeneration studies for this projection system. However, in cases of shorter survival time (20–27 h), the number of labeled neurons was very small.The relative paucity of labeled Corticopontine neurons in the sigmoid and lateral gyri is discussed with reference to other cortical descending neurons (e.g., the corticotectal, corticoreticular and corticospinal) which have hitherto been identified morphologically as well as physiologically.Abbreviations AL gyrus lateralis anterior - ASigm gyrus sigmoideus anterior - ASup gyrus suprasylvius anterior - Br.p. brachium pontis - Cor gyrus coronalis - L left - L.m. lemniscus medialis - MEct gyrus ectosylvius medius - MSup gyrus suprasylvius medius - N.dl. nucleus dorsolateralis - N.l. nucleus lateralis - N.m. nucleus medianus - N.p. nucleus peduncularis - N.pm. nucleus paramedianus - N.r.t. nucleus reticularis tegmenti pontis - N.v. nucleus ventralis - Ped corticospinal and corticopontine fibers in cerebral peduncle - PSigm gyrus sigmoideus posterior - R right     

Thalamic connections of the dorsal and ventral premotor areas in New World owl monkeys

Thalamic connections of two premotor cortex areas, dorsal (PMD) and ventral (PMV), were revealed in New World owl monkeys by injections of fluorescent dyes or wheat-germ agglutinin conjugated to horseradish peroxidase (WGA-HRP). The injections were placed in the forelimb and eye-movement representations of PMD and in the forelimb representation of PMV as determined by microstimulation mapping. For comparison, injections were also placed in the forelimb representation of primary motor cortex (M1) of two owl monkeys. The results indicate that both PMD and PMV receive dense projections from the ventral lateral (VL) and ventral anterior (VA) thalamus, and sparser projections from the ventromedial (VM), mediodorsal (MD) and intralaminar (IL) nuclei. Labeled neurons in VL were concentrated in the anterior (VLa) and the medial (VLx) nuclei, with only a few labeled cells in the dorsal (VLd) and posterior (VLp) nuclei. In VA, labeled neurons were concentrated in the parvocellular division (VApc) dorsomedial to VLa. Labeled neurons in MD were concentrated in the most lateral and posterior parts of the nucleus. VApc projected more densely to PMD than PMV, especially to rostral PMD, whereas caudal PMD received stronger projections from neurons in VLx and VLa. VLd projected exclusively to PMD, and not to PMV. In addition, neurons labeled by PMD injections tended to be more dorsal in VL, IL, and MD than those labeled by PMV injections. The results indicate that both premotor areas receive indirect inputs from the cerebellum (via VLx, VLd and IL) and globus pallidus (via VLa, VApc, and MD). Comparisons of thalamic projections to premotor and M1 indicate that both regions receive strong projections from VLx and VLa, with the populations of cells projecting to M1 located more laterally in these nuclei. VApc, VLd, and MD project mainly to premotor areas, while VLp projects mainly to M1. Overall, the thalamic connectivity patterns of premotor cortex in New World owl monkeys are similar to those reported for Old World monkeys.     

大鼠脊髓内囊泡膜谷氨酸转运体1和囊泡膜谷氨酸转运体2阳性纤维和终末在生后发育中的分布和表达变化

目的 探讨囊泡膜谷氨酸转运体1（VGLUT1）和VGLUT2阳性纤维和终末在生后第0天（P0）至第22天（P22）大鼠脊髓内的分布情况和表达变化。 方法 对生后发育P0～P22大鼠的颈膨大和腰膨大部位,进行VGLUT1和VGLUT2免疫组织化学染色。 结果 P0～P22大鼠颈膨大和腰膨大脊髓内均可观察到VGLUT1和VGLUT2阳性纤维和终末,但未观察到胞体样结构。VGLUT1和VGLUT2阳性纤维和终末的分布呈现明显的互补分布,尤其是以脊髓后角更加明显。其中,VGLUT1阳性纤维和终末在P0主要见于颈膨大和腰膨大脊髓后角Ⅲ～Ⅴ层,中间部和前角很微弱。脊髓发育至P3,不仅Ⅲ~Ⅴ层VGLUT1的表达进一步增强,且向外侧部扩展,并在后角基底部Ⅵ层和前角的外侧部（Ⅸ层）也可观察到较强的VGLUT1阳性纤维,呈现一条明显由背内向腹外的带状分布趋势。P7时此带状分布更加明显,并随着发育逐渐向内、外扩展,至P22时已广泛分布于除Ⅱ层之外的整个脊髓。而VGLUT2阳性纤维和终末在P0时即密集出现于脊髓后角Ⅰ～Ⅱ层以及前角的外侧边缘区域;之后随着发育,VGLUT2阳性纤维和终末的分布模式并未发生明显改变,但其密度逐渐有所增加,特别是Ⅰ～Ⅱ层内VGLUT2阳性产物的表达尤为明显。另外,在脊髓白质后索内可见VGLUT1阳性皮质脊髓后束纤维由颈髓（P3）逐渐下降至腰髓（P7）的发育过程。 结论 VGLUT1和VGLUT2阳性纤维和终末在脊髓发育过程中呈现明显不同,且表现出互补分布的特点,这对于进一步理解VGLUT1和VGLUT2在脊髓生后发育过程中不同功能特点可能有意义。     

Corticospinal projections from areas 4 and 6 in the raccoon

Summary The corticospinal projections from areas 4 and 6 were investigated in the raccoon using the horseradish peroxidase (HRP) retrograde tracing technique. Multiple injections of lectin bound HRP and HRP were made into either the cervical or lumbar cord in 7 anesthetized raccoons. Retrogradely labeled neurons were observed throughout a wide extent of areas 4 and 6a. The HRP positive cells were most numerous within the dorsal bank of the cruciate sulcus within area 4 and continued around the fundus to occupy the lateral two-thirds of the ventral bank of the cruciate sulcus within area 6a. No labeled cells were observed in the more medially located area 6a. Although the HRP positive cells observed following the lumbar cord injections were situated slightly more medial and caudal to those observed following the cervical cord injections, considerable overlap between the two projections was noted. The corticospinal projections arising from areas 4 and 6a in the raccoon largely correspond in location to the regions functionally defined as the primary motor cortex and the supplementary motor area, respectively.     

Localization of lateral hypothalamic neurons projecting to the medial part of the parabrachial area of the rat.

We recently showed that electrical self-stimulation registered in the medial part of the parabrachial area, as well as the preference-aversion threshold to saccharin solutions were both significantly altered following ibotenic acid lesion of the lateral hypothalamic neurons. In order to identify the location of the neurons in the lateral hypothalamus directly projecting to the parabrachial area, we injected in the medial part of this area the retrograde tracer wheat germ agglutinin-inactive horseradish peroxidase coupled to colloidal gold. In the lateral hypothalamus a large number of labeled cells was constantly observed. This cluster of cells was located in the middle and posterior parts of the lateral hypothalamic area between the frontal plane corresponding to the posterior third of the ventromedial hypothalamic nucleus and the plane corresponding to the premammillary nuclei. In contrast, the anterior part of the lateral hypothalamus was unlabeled. Since the labeled neurons are located in the same region as those destroyed by our ibotenic acid lesions, the present results strongly suggest that these descending projections, originating in the posterior lateral hypothalamus, are implicated in reward mechanisms elicited from the parabrachial area.     

The prefrontral cortex of the cat: Anatomical subdivisions based on retrograde labeling of cells in the mediodorsal thalamic nucleus

Different areas of the frontal cortex of the cat were injected with small amounts of horseradish peroxidase. The region of labeled cells in the mediodorsal nucleus of the thalamus (MD) were related to the injected areas. Distinct relations between subdivisions of MD and of the prefrontal cortex were established: a rather large central sector of MD projects to the gyrus proreus and the anterior parts of the gyri sigmoideus, rectus, and frontalis. A narrow lateral band of anterior MD neurons projects predominantly to an area on both sides of the sulcus praesylvius, whereas a postero-lateral band sends fibers to a region on the ventral anterior sylvian gyrus. The area between the presylvian sulcus and the sylvian gyrus is apparently free of MD afferents, but not of other thalamic afferents. A fourth sector of MD, situated dorsomedially, projects to the middle parts of the gyri rectus and frontalis. And a fifth sector, located ventrally to the dorsomedial MD sector, projects to the ventral part of the gyrus rectus. The established subfields of MD and of the prefrontal cortex are discussed with respect to previous anatomical research in the cat.     

Connections of the dorsomedial hypothalamic nucleus from the forebrain structures in the rat

The dorsomedial hypothalamic nucleus (DMH) has been implicated as an area controlling autonomic activity. The aim of this study was to demonstrate connections of the anterior and posterior DMH to the forebrain structures, using a horseradish peroxidase (HRP) retrograde axonal transport technique in rats. The results of HRP labelling show that the anterior and posterior DMH indicate a number of differences in their connections. The posterior DMH has intense connections with the cortex (cingulate, frontal, parietal and insular), amygdala (lateral and basolateral) and hippocampus (CA1 and CA2), whereas the anterior DMH has faint connections with the cortex (cingulate, frontal and parietal) and prominent connections with the septal and bed nucleus of stria terminalis. These differences in connections of the DMH may provide sites for the specific autonomic function integrated by the DMH.     

Interconnections of the auditory cortical fields of the cat with the cingulate and parahippocampal cortices

Summary The interconnections of the auditory cortex with the parahippocampal and cingulate cortices were studied in the cat. Injections of the anterograde and retrograde tracer WGA-HRP were performed, in different cats (n = 9), in electrophysiologically identified auditory cortical fields. Injections in the posterior zone of the auditory cortex (PAF or at the PAF/AI border) labeled neurons and axonal terminal fields in the cingulate gyrus, mainly in the ventral bank of the splenial sulcus (a region that can be considered as an extension of the cytoarchitectonic area Cg), and posteriorly in the retrosplenial area. Labeling was also present in area 35 of the perirhinal cortex, but it was sparser than in the cingulate gyrus. Following WGA-HRP injection in All, no labeling was found in the cingulate gyrus, but a few neurons and terminals were labeled in area 35. In contrast, no or very sparse labeling was observed in the cingulate and perirhinal cortices after WGA-HRP injections in the anterior zone of the auditory cortex (AI or AAF). A WGA-HRP injection in the cingulate gyrus labeled neurons in the posterior zone of the auditory cortex, between the posterior ectosylvian and the posterior suprasylvian sulci, but none was found more anteriorly in regions corresponding to AI, AAF and AII. The present data indicate the existence of preferential interconnections between the posterior auditory cortex and the limbic system (cingulate and parahippocampal cortices). This specialization of posterior auditory cortical areas can be related to previous observations indicating that the anterior and posterior regions of the auditory cortex differ from each other by their response properties to sounds and their pattern of connectivity with the auditory thalamus and the claustrum.Abbreviations AAF anterior auditory cortical field - aes anterior ectosylvian sulcus - AI primary auditory cortical field - AII secondary auditory cortical field - ALLS anterior-lateral lateral suprasylvian visual area - BF best frequency - C cerebral cortex - CC corpus callosum - CIN cingulate cortex - CL claustrum - DLS dorsal lateral suprasylvian visual area - DP dorsoposterior auditory area - E entorhinal cortex - IC inferior colliculus - LGN lateral geniculate nucleus - LV pars lateralis of the ventral division of the MGB - LVe lateral ventricule - MGB medial geniculate body - OT optic tract - OV pars ovoidea of the ventral division of the MGB - PAF posterior auditory cortical field - pes posterior ectosylvian sulcus - PLLS posterior-lateral lateral suprasylvian visual area - PS posterior suprasylvian visual area - PU putamen - RE reticular complex of thalamus - rs rhinal sulcus - SC superior colliculus - SS suprasylvian sulcus - T temporal auditory cortical field - TMB tetramethylbenzidine - VBX ventrobasal complex of thalamus, external nucleus - VL pars ventrolateralis of the ventral division of the MGB - VLS ventrolateral suprasylvian visual area - VPAF ventroposterior auditory cortical field - WGA-HRP wheat germ agglutinin labeled with horseradish peroxidase - wm white matter     

Distribution of corticospinal neurons with collaterals to lower brain stem reticular formation in cat

Summary The fluorescent retrograde double-labeling technique has been used to determine whether corticospinal neurons in the cat sensorimotor cortex distribute collaterals to the lower brain stem reticular formation. In this study the fluorescent tracers Nuclear Yellow and Diamidino Yellow 2HCl were used in combination with Fast Blue. One tracer was injected unilaterally in the spinal cord and the other was injected ipsilaterally in the bulbar medial reticular formation. The distribution of the retrogradely labeled neurons was studied in the contralateral hemisphere. In the sensorimotor cortex a large population of neurons was found which were labeled from the spinal cord and were double-labeled from the brain stem. These branching neurons were concentrated in the rostromedial part of area 4 and the adjoining lateral part of area 6. In this region the percentages of corticospinal neurons which were double-labeled from the brain stem ranged from 5% laterally to 30% medially. In two cats it was demonstrated by means of the anterograde transport of HRP that the corticobulbar fibers from this region which must include the corticospinal collaterals are distributed to the reticular formation of the lower brain stem. In view of the fact that the double-labeled neurons are concentrated in the anterior part of the motor cortex, those branching neurons are in all likelihood involved in the control of neck, back and shoulder movements. This control is probably exerted by way of two routes i.e. by way of the direct corticospinal connections to spinal interneurons, and by way of the indirect cortico-reticulospinal connections established by the cortical fibers to the bulbar reticular formation. The present findings suggest that this dual control may be exerted by one and the same cell.Supported in part by Grant 13-46-91 of FUNGO/ZWO (Dutch Organization for Fundamental Research in Medicine)     

Tyrosine hydroxylase-immunoreactive intrinsic neurons in the rat cerebral cortex

Summary Using specific antisera against the catecholamine synthesizing enzyme, tyrosine hydroxylase (TH), in combination with the peroxidase-antiperoxidase method and/or the avidin-biotin complex method, we have found a new group of TH immunoreactive (TH-I) neurons in the rat cerebral cortex. Numerous TH-I cells were observed all over the isocortex, that is, frontal, temporal, parietal and occipital regions, and in some parts of the allocortex such as the anterior cingulate cortex, the retrosplenial cortex and anterior part of the insular cortex. In contrast, they were rare in the perirhinal cortex, posterior part of the insular cortex, piriform cortex, entorhinal cortex and hippocampal formation. TH-I cells were situated throughout all cortical layers, but were most concentrated in layer II/III. Although TH-I cells were heterogeneous in shape, the majority were bipolar. All TH-I cells so far examined appeared to be of the nonpyramidal type. The majority of these intrinsic TH-I neurons also contained the GABA-like immunoreactivity and thus could be regarded as a subpopulation of cortical GABAergic neurons.     

大白鼠扣带回3区向杏仁体及其他核群的纤维投射——菜豆白细胞凝集素顺行示踪研究

本文用菜豆自细胞凝集素免疫组织化学顺行示踪技术,观察大白鼠扣带回3区(Cg3)向皮质下核团的纤维投射。其投射区自前向后主要有:伏核、尾壳核内侧1/3、终纹床核、外侧视前区、带旁核、丘脑前内侧核、背内侧核、前室旁核、网状核、外侧缰核、后室旁核、束旁核及丘脑筛状核等。在丘脑下方,标记纤维密集于未定带、内囊的内侧边缘区和乳头丘脑束的周围。自这些区域,有纤维投射至下丘脑外侧区。本文着重分析了标记纤维在杏仁体的分布情况,标记纤维密集于基底外侧前核和外侧核的腹内侧亚核。从而证实Cg3皮质的纤维投射参与基底外侧核一边缘系环路,即所谓记忆环路。而杏仁体中央核仅偶见极稀疏的标记纤维。所以我们认为,Cg3皮质未参与“内脏环路”。标记纤维自注射侧经胼胝体膝至对侧半球,其投射区与注射侧的投射区一致,但标记纤维比较稀疏。