Callosal neurons: monosynaptic connection between them and their descending projections

Antidromic and monosynaptic unit responses to the stimulation of the corpus callosum and the symmetrical cortical area as well as antidromic responses to pyramidal tract and thalamic nuclei stimulation were recorded in the sensorimotor cortex of unanaesthetized rabbits. Out of 182 callosal neurones 13 exhibited transcallosal monosynaptic responses. 8 out of 56 callosal units responded antidromically to pyramidal tract or thalamic stimulation. Thus callosal neurones may be monosynaptically excited by callosal units via the corpus callosum and by the pyramidal tract units. It was also found that a pyramidal tract neurone may send a collateral through the corpus callosum and at the same time have a transcallosal monosynaptic input. The role of monosynaptic transcallosal excitation of callosal neurones is discussed.     

Properties of monosynaptic connections between callosal neurons and specific thalamic nuclei

A comparative analysis of monosynaptic afferent and efferent connections of callosal neurons and target neurons of transcallosal fibers with neurons of the specific ipsilateral thalamic nuclei (ventral posterolateral, ventral posteromedial, ventral lateral, and anteroventral) was undertaken on the sensomotor cortex of unanesthetized rabbits, using an electrophysiological method. Differences were demonstrated between callosal neurons and target neurons of transcallosal fibers with respect to monosynaptic inputs from the thalamic nuclei and pathways proceeding toward these structures and (or) entering the pyramidal tract. Among target neurons, compared with callosal neurons, more cells had descending projections (54 and 14%, respectively). Monosynaptic action potentials arose in 22% of target neurons in response to stimulation of specific thalamic nuclei, whereas no such responses occurred in callosal neurons. Projections of target neurons into thalamic nuclei were shown to be formed both by independent fibers and by axon collaterals of the pyramidal tract. It is postulated that the distinctive properties thus discovered indicate significantly greater convergence of influence of thalamic relay neurons on the target neurons; this determines differences known to exist in characteristics of receptive fields and spontaneous and evoked activity of callosal neurons, on the one hand, and of neurons excited synaptically by transcallosal stimulation, on the other hand.Institute of Higher Nervous Activity and Neurophysiology, Academy of Sciences of the USSR, Moscow. Translated from Neirofiziologiya, Vol. 17, No. 3, pp. 305–314, May–June, 1985.     

A function of the corpus callosum in the Siamese cat

Recordings were made from 180 single cells, or cell clusters, in the Clare-Bishop area of two Siamese cats. In one cat, the corpus callosum had been sectioned prior to recording and all cells were driven by the contralateral eye exclusively. In the other recordings were made before and after callosal section. Before callosal section, most cells were binocularly driven but dominated by the contralateral eye. There were striking examples of binocular interaction and some cells could only be activated by simultaneous binocular stimulation. After callosal section, cells were driven by the contralateral eye only. The same experiment performed in a normal cat revealed no change in binocularity following section of the corpus callosum. We conclude that one of the functions of the corpus callosum in the Siamese cat is to generate binocular neurons.     

Neuronal typology of the thalamic area triangularis of Gallotia galloti (reptilia,sauria)

In a Golgi study of the area triangularis (AT), a rostral nucleus of the ventral thalamus of Gallotia galloti, we have identified four major neuronal types on the basis of their morphological characteristics: medium-sized fusiforms with two processes, medium-sized fusiforms with three or four processes, small bipolars, and small and medium-sized multipolars. These neurons are characterized by a simple morphology and radial arrangement. Cell size varies from small to medium, and all axons project laterally. These characteristics distinguish AT neurons from those of neighboring nuclei. In addition, we found some evidence of differential topographic distribution of each neuronal type within the nucleus. Medium-sized fusiform neurons with two processes are located in the most ventral part, where they constitute the ventral nuclear limit. Small multipolar neurons prevail in the dorsal and ventromedial parts, and in the rest of the nucleus medium-sized neurons, including both fusiform with three or four processes and multipolar types, are normally found. Finally, we discuss a putative homology of the reptilian AT with a part of the mammalian zona incerta.     

Early components of transcallosal responses in acute ischaemia of the corpus callosum

In 8 baboons maintained under propofol anaesthesia, transcallosal evoked responses were recorded from the primary motor cortex following electrical stimulation of the contralateral homotopic cortical surface. The corpus callosum was made ischaemic by transorbital occlusion of the common anterior cerebral artery; blood flow (measured by the hydrogen clearance method) in the stimulating and recording regions was not significantly affected by this procedure. The transcallosal responses from the normally perfused brain contained early positive (P1) and negative (N1) components. As stepwise ischaemia was produced in the corpus callosum, the amplitude of P1 initially increased up to 150% of control and the peak latency of P1 was significantly prolonged. At flows below 8 ml/100/g/min the amplitude rapidly decreased. Wave form changes and flow threshold of N1 were similar to those of P1. These results suggest that measurement of early transcallosal responses could be useful clinically as monitors of the ischaemic level in anterior cerebral artery territory.     

Tractography of the Spider Monkey (Ateles geoffroyi) Corpus Callosum Using Diffusion Tensor Magnetic Resonance Imaging

The objective of this research was to describe the organization, connectivity and microstructure of the corpus callosum of the spider monkey (Ateles geoffroyi). Non-invasive magnetic resonance imaging and diffusion-tensor imaging were obtained from three subjects using a 3T Philips scanner. We hypothesized that the arrangement of fibers in spider monkeys would be similar to that observed in other non-human primates. A repeated measure (n = 3) of fractional anisotropy values was obtained of each subject and for each callosal subdivision. Measurements of the diffusion properties of corpus callosum fibers exhibited a similar pattern to those reported in the literature for humans and chimpanzees. No statistical difference was reached when comparing this parameter between the different CC regions (p = 0.066). The highest fractional anisotropy values corresponded to regions projecting from the corpus callosum to the posterior cortical association areas, premotor and supplementary motor cortices. The lowest fractional anisotropy corresponded to projections to motor and sensory cortical areas. Analyses indicated that approximately 57% of the fibers projects to the frontal cortex and 43% to the post-central cortex. While this study had a small sample size, the results provided important information concerning the organization of the corpus callosum in spider monkeys.     

White Matter Changes in Patients with Amnestic Mild Cognitive Impairment Detected by Diffusion Tensor Imaging

Compared to normal aging adults, individuals with amnestic mild cognitive impairment (aMCI) have significantly increased risk for progressing into Alzheimer’s disease (AD). Autopsy studies found that most of the brains of aMCI cases showed anatomical features associated with AD pathology. The recent development of non-invasive neuroimaging technique, such as diffusion tensor imaging (DTI), makes it possible to investigate the microstructures of the cerebral white matter in vivo. We hypothesized that disrupted white matter (WM) integrity existed in aMCI. So we used DTI technique, by measuring fractional anisotropy (FA) and mean diffusivity (MD), to test the brain structures involved in patients with aMCI. DTI scans were collected from 40 patients with aMCI, and 28 normal controls (NC). Tract-based spatial statistics (TBSS) analyses of whole-brain FA and MD images in each individual and group comparisons were carried out. Compared to NC, aMCI patients showed significant FA reduction bilaterally, in the association and projection fibers of frontal, parietal, and temporal lobes, corpus callosum, bilateral corona radiation, right posterior thalamic radiation and right sagittal stratum. aMCI patients also showed significantly increased MD widespreadly in the association and projection fibers of frontal, parietal and temporal lobes, and corpus callosum. Assessment of the WM integrity of the frontal, parietal, temporal lobes, and corpus callosum by using DTI measures may aid early diagnosis of aMCI.     

Corpus callosum section for patients with intractable epilepsy

Microsurgical techniques of callosotomy were effective in relieving medically intractable epilepsy in 14 of 16 patients. Intra-arterial digital angiography has been used preoperatively to assess drainage of the veins of the frontal lobe. MRI is useful in verifying the postoperative extent of corpus callosum section. Patients with bilateral frontal lesions and unilateral destructive lesions responded to callosotomy. None of the patients had an increase in seizures after the procedure.     

The cortical EEG in the acallosal mouse

The congenital absence of the corpus callosum has recently been found to occur among some mice of the ddN strain in our laboratory. Morphologically, the absence of corpus callosum was classified into two types. One was complete agenesis of corpus callosum, and the other revealed partial agenesis (genu or splenium, or both). In this experiment, the differences of cortical EEG spectral characteristics were studied on the normal, hypogenesis and acallosal mice. A total of 75 male and female adult mice were used. Under light ether anesthesia, five stainless steel electrodes (0.29 mm) were implanted stereotaxically in the bilateral cerebral cortex and cerebellum at a depth of 1.0 mm. After one week recovery period, the correlations of EEG of five combinations, such as homotopic anterior vs. posterior, left vs. right hemispheres, crossed contralateral, and homotopic anterior and posterior to the reference electrode, were analysed with a signal processor. In the complete acallosal mice (n = 11), the correlation coefficients were significantly lower (p less than 0.05), in the crossed contralateral, left vs. right hemispheres, and homotopic posterior to reference. In the hypogenesis of corpus callosum (n = 7), however, they were no significant differences in the correlation compared with normal mice (n = 57). At the end of experiment, the brain was removed and fixed with 10% formalin, then it was cut in half along the midsagittal plane. The midsagittal section was used to examine an outline of the corpus callosum.     

Regional differences in the stratified transitional field and the honeycomb matrix of the developing human cerebral cortex

The neurons of the cerebral cortex originate in the proliferative neuroepithelium and settle in the cortical plate during embryonic development. Interposed between these two sites is a large transitional field. We have earlier demonstrated experimentally in rats with ³H-thymidine autoradiography that this transitional field is a stratified structure composed of discrete layers of migrating and sojourning cells, and fiber bands. Here we show that the different layers of the stratified transitional field are identifiable without experimental procedures in the developing human cerebral cortex and that there are conspicuous regional differences in its stratification. At the peak of its development, the stratified transitional field contains three fibrous bands in an inside-out order: the commissural fibers of the corpus callosum, the thalamocortical and corticofugal projection fibers, and the expanding white matter. There are regional differences in the thickness of these fibrous layers as well as in the number and configuration of the perikaryal layers. This preview focuses on laminar differences of the transitional fields of the agranular frontal lobe and the granular parietal and occipital lobes. At the latter sites, but not in the frontal lobe, there is a distinctive multi-layered band, the honeycomb matrix, where radially oriented fiber columns are sandwiched between two perikaryal sublayers and are separated from one another by radially oriented cells. We postulate that the radial fiber columns of the honeycomb matrix are composed of topographically organized thalamocortical fibers and that the unspecified young neurons acquire their enduring topographic identity by making selective contacts with tagged fibers here before they resume their radial or tangential migration to the cortical plate.     

Neuronal organization of the periaqueductal gray matter in the cat midbrain

It is shown by the use of Golgi's method in Antonova's modification that the neuronal structure of the periaqueductal gray matter (PGM) in the frontal plane is characterized by the presence of small and medium-sized cells of "reticular type," which can be subdivided into three types: fusiform, triangular, and multipolar. On the basis of the visual distribution of these types of neurons and also of statistical analysis of 800 identified neurons, two regions can be distinguished: medial, directly surrounding the aqueduct of Sylvius, containing small neurons, among which the fusiform kind predominate significantly (P<0.001), and a lateral region with larger neurons, with significantly (P<0.001) more triangular cells. Neurons in the medial region show a characteristic and strong (P<0.001) tendency for their dendrites to be oriented toward the lumen of the aqueduct, and through them the physiologically active substances of the CSF may influence the functional activity of neurons of PGM.Central Research Institute of Reflex Therapy, Moscow City Council Main Health Board, Moscow. Translated from Neirofiziologiya, Vol. 16, No. 6, pp. 773–777, November–December, 1984.     

Preliminary evidence of abnormal white matter related to the fusiform gyrus in Williams syndrome: a diffusion tensor imaging tractography study

Williams syndrome (WS) is a genetic condition caused by a hemizygous microdeletion on chromosome 7q11.23. WS is characterized by a distinctive social phenotype composed of increased drive toward social engagement and attention toward faces. In addition, individuals with WS exhibit abnormal structure and function of brain regions important for the processing of faces such as the fusiform gyrus. This study was designed to investigate if white matter tracts related to the fusiform gyrus in WS exhibit abnormal structural integrity as compared to typically developing (TD; age matched) and developmentally delayed (DD; intelligence quotient matched) controls. Using diffusion tensor imaging data collected from 40 (20 WS, 10 TD and 10 DD) participants, white matter fibers were reconstructed that project through the fusiform gyrus and two control regions (caudate and the genu of the corpus callosum). Macro-structural integrity was assessed by calculating the total volume of reconstructed fibers and micro-structural integrity was assessed by calculating fractional anisotropy (FA) and fiber density index (FDi) of reconstructed fibers. WS participants, as compared to controls, exhibited an increase in the volume of reconstructed fibers and an increase in FA and FDi for fibers projecting through the fusiform gyrus. No between-group differences were observed in the fibers that project through the control regions. Although preliminary, these results provide further evidence that the brain anatomy important for processing faces is abnormal in WS.     

Relationship of ACTH1-39-immunostained fibers and magnocellular neurons in the paraventricular nucleus of rat hypothalamus

Dual antigen immunocytochemical staining procedures were used in the same tissue section to determine the distribution of ACTH immunostained fibers and varicosities within the magnocellular and parvocellular divisions in the paraventricular nucleus (PVN) of rat hypothalamus and elucidate its anatomical relationship to vasopressin (VP) and oxytocin (OXY)-containing neurons. Double immunostained preparations using glucose oxidase-antiglucose oxidase complex combined with PAP complex to visualize two antigens with contrasting colors in the same tissue section were employed. ACTH-immunoreactive (ir) fibers were distributed throughout the periventricular stratum and the parvocellular component of the PVN; in the latter area fibers were particularly dense in the ventral medial portion of the medial parvocellular division. Dual immunostained sections revealed a close anatomical association between opiocortin fibers and oxytocin and vasopressin parvocellular neurons. ACTH immunostained fibers were present in the anterior and medial magnocellular component of PVN and in the ventral medial portion of the posterior magnocellular division; these immunoreactive fibers were in intimate proximity to oxytocin-ir perikarya. The very close approximation between the ACTH-ir fibers and oxytocin-containing cell bodies suggests potential cell to cell communication between the two peptidergic systems in PVN. Few ACTH immunostained fibers were seen in the dorsal lateral portion of the posterior magnocellular division in which vasopressinergic neurons predominate. The present anatomical study supports pharmacological and physiological studies which indicate that opioids can influence the activity of magnocellular PV neurons. This study also elucidates an anatomical relationship between opiocortins (ACTH1-39) and parvocellular PV neurons which suggests that the opiocortin system may play a role in the regulation of both the neuroendocrine and autonomic activities of specific PV neurons.     

Transient cellular structures in developing corpus callosum of the human brain

The corpus callosum connects two cerebral hemispheres as the most voluminous fiber system in the human brain. The developing callosal fibers originate from immature pyramidal neurons, grow through complex pathways and cross the midline using different substrates in transient fetal structures. We analyzed cellular structures in the human corpus callosum on postmortem brains from the age of 18 weeks post conception to adult, using glial fibrillary acidic protein, neuron-specific nuclear protein, and chondroitin sulphate immunocytochemistry. We found the presence of transient cellular structures, callosal septa, which divide major fiber bundles and ventrally merge with subcallosal zone forming grooves for callosal axons. The callosal septa are composed of glial fibrillary acidic protein reactive meshwork, neurones and the chondroitin sulphate immunoreactive extracellular matrix. The developmental window of prominence of the callosal septa is between 18-34 weeks post conception which corresponds to the period of most intensive growth of callosal axons in human. During the early postnatal period the callosal septa become thinner and shorter, lose their neuronal and chondroitin sulphate content. In conclusion, transient expression of neuronal, glial and extracellular, growing substrate in the callosal septa, as septa itself, indicates their role in guidance during intensive growth of callosal fibers in the human brain. These findings shed some light on the complex morphogenetic events during the growth of the corpus callosum and represent normative parameters necessary for studies of structural plasticity after perinatal lesions.     

DEVELOPMENTAL CHANGES IN THE VASCULAR CAMBIUM OF POLYGONUM LAPATHIFOLIUM

Developmental changes in the vascular cambium of Polygonum lapathifolium were determined primarily by an analysis of the secondary xylem. The cambium and xylem consist of fascicular and interfascicular regions in this herbaceous dicotyledon. Near the pith vessels are restricted to the fascicular regions of the xylem. During secondary growth vessels are formed in some radial files in the interfascicular regions. Anticlinal divisions are of two types, oblique and lateral. In interfascicular files consisting of fibers only, about two-thirds of the anticlinal divisions are oblique. The oblique partition averages 31% of the length of the dividing initials. In interfascicular files consisting of vessel elements and fibers, there are almost equal numbers of oblique and lateral divisions. The oblique partition averages 37% of the length of the dividing initials in these files. Lateral divisions account for approximately three-fifths of the anticlinal divisions in the fascicular regions, consisting of vessel elements and fibers. The partitions formed in oblique anticlinal divisions average 64% of the length of the dividing cells in the fascicular regions. The frequency of anticlinal division is much higher in files consisting of vessel elements and fibers than in those consisting of fibers only. There is no loss of fusiform initials, except by ray formation. Ray initiation occurs by simple subdivision of fusiform initials. The findings are discussed in relation to the developmental changes in the vascular cambium in plants of different habits.     

胼胝体输入对猫皮层17/18交界区细胞方向和取向选择性的影响

用抑制性神经递质GABA阻断胼胝体输入、用微机控制的运动光棒作为视觉刺激,用金属电极胞外记录技术,研究猫皮层17/18区交界附近细胞方向选择性和取向选择性的变化.在被检测的48个细胞中,50%细胞的方向选择性强度,54.2%细胞的取向选择性强度发生了改变;约20%细胞的最优反应方向或.及最优取向发生了10-30°的偏移;共有56.2%细胞的方向选择性、58.3%细胞的取向选择性受到明确的影响.这些结果表明胼胝体对皮层细胞视觉反应的贡献是多方面的.     

Intrinsic organization of the paramedian pontine reticular formation of the cat.

A morphoquantitative analysis was carried out to clarify the cytoarchitectural organization of the paramedian pontine reticular formation (PPRF) which is considered to be an important site in the control of eye movements. The study was carried out on the cat, using the Golgi staining method. The topographic position and detailed structure of the neurons were demonstrated using morphoquantitative methods. On the basis of their neuronal arborization, fusiform neurons and two types of multipolar cells were identified. Fusiform neurons show dendrites which are given off from the two poles of the small- to medium-sized cell body. The arborization generally runs caudorostrally, ending inside the PPRF. These neurons are ubiquitous. Type 1 multipolar neurons, the most frequent elements of the neuronal population (60%), have a small- to large-sized cell body from which 2 or 3 primary spiny dendrites and the axon emerge. Their dendritic field is oval and generally oriented in the vertical plane. These neurons are scattered everywhere in the PPRF. Type 2 multipolar cells are large neurons endowed with numerous primary spiny dendrites constituting a wide round dendritic field and with a thick axon. They are located almost exclusively at the boundaries of the PPRF and preferentially in the caudal region. The characteristics of the neurons suggest that the fusiform cells may play an interneuronal role, while the multipolar neurons could have both a projective function and an important receptive role for the afferent fibers to the PPRF. The lack of homogeneity found among the multipolar neurons is in agreement with the variety of projective elements shown by functional investigations.(ABSTRACT TRUNCATED AT 250 WORDS)     

Interaction between the left and right sided systems of secretory conditioned reflexes following section of commissural pathways of the dog brain]

By means of stereotype rhythmic presentation of positive and inhibitory stimuli, systems of unilateral reflexes were elaborated in dogs with symmetrical parts of the tongue brought out by Abuladze method. After section of the corpus callosum as well as of the corpus callosum and the hippocampal and fornix commissures, differentiation of stimuli in the left- and right-side reflexes systems is impeded, and the systemic nervous process is also disturbed. The significance of the interhemispheric interaction has been revealed for the formation of unilateral dominant excitation sites necessary for achievment of a distinct unilateral reaction. The longer retention of unilaterally organized sites of latent excitation after callosotomy testifies to the role of interhemispheric interaction in the timely erasing of traces of unilateral stimuli.     

Memory disorders in lesions of the corpus callosum in man

It is shown in seven patients with partial commissurotomy in connection with arterial aneurysms of the anterior conjunctival and pericallosal arteriae, that the section of the corpus callosum leads to memory disturbances, qualitatively differing by their structure from mnemic disorders described in literature. Important role of the knee of the Corpus callosum in genesis of these disturbances is revealed, their types are described and neuropsychological are criteria formulated of evaluation of disturbance of interhemispheric interaction in the mnemic sphere, opening new perspectives in diagnosis and correction of mental processes disturbances at local brain lesions.