Cortico-cortical connections in the parietal area of the cerebral cortex

Layer-by-layer arrangement of the commissural and associative fibers has been studied in the cat parietal cortex. The commissural fibers are distributed in all the layers of the parietal cortex in the contralateral hemisphere, except the superficial part of the I layer. These fibers mainly terminate in the III, IV layers of the contralateral parietal cortex, though their termination in other layers is not excluded. The associative fibers of the parietal cortex are distributed in all the layers of the sensomotor area, except the superficial part of the I layer. They mainly terminate in the III, IV, V layers of the primary somatosensory and in the III, V layers of the motor cortex.     

Intercortical connections between the auditory fields and the motor area

The connections of auditory fields AI, AII and Ep with the motor area were studied in 14 cats by anterograde degeneration method by means of impregnation techniques of Nauta-Gigax and Fink-Heimer in Victorov's modification. Direct connections were established between the three auditory fields and the motor projection field of the forepaw. The connections coming from the auditory field Ep spread wider, to the motor projection field of the head. The greatest number of these interzonal connections originates in zone Ep, and the smallest in AII zone.     

Elementary transcallosal connections of the rabbit sensomotor cortex]

Antidromic responses of two callosal neurones to a local electrical stimulation of the rabbit sensorimotor cortex may be recorded simultaneously with one microelectrode in the homotopic cortical area. In such recording conditions the relative amplitude of extracellularly recorded action potentials of the two neurones is determined primarily by the distance between these neurones and the electrode's tip. In response to the stimulation of the symmetrical area transcallosal monosynaptic excitation of the callosal neurone may occur; two callosal neurones may exite monosynaptically one and the same recorded neurone. The results suggest the existence of clusters or columns, formed jointly by the bodies and terminals of callosal neurones; a functional interconnection between symmetrical clusters or columns may exist, in particular a positive feedback.     

Cortico-cortical connections in the motor cortex of the brain; a study using the peroxidase method]

Using a method based on retrograde axonal transport of horse-radish peroxidase (HRP), the cortico-cortical afferents of the motor cortex were studied. After enzyme injection into the posterior sigmoideus gyrus, the HRP product was found in the first and the second somatic sensory areas and in parietal cortex (fields 5a, 5b). The HRP-positive neurons occurred in layers II, III and V of the cortex and belonged to the pyramidal cells.     

An analysis of interneuronal connections in the auditory cortex of awake cats]

A statistical analysis has been made of the interaction of the auditory cortex units in alert cats with chronically implanted electrodes. Three neurones with an amplitude ratio of 4:2:1 were singled out from the multineuronal activity. The dependence between the firing of two neurones was determined by the cross interval histograms. The relationships between 78 pairs of units were studied in 26 three units microsystems. About a third of the studied pairs functioned independently. The number of pairs with one-way and two-way connections was about equal (26 and 30 respectively). The neurones which generated spikes of high and medium amplitude, had the largest number of two-way connections. One-way connections were equally represented in all the three neurones, though with regard to direction they depended on the amplitude characteristics of the spikes. In neurones with large and medium spikes, output connections predominated, while in neurones with small spikes input connections predominated considerably. The connection could be of inhibitory, excitatory or mixed type. The inhibitory type of connections was the most frequent occurrence (57 out of 86). At prolonged recording (6 to 16 min) of spike activity, most of the functional connections persisted.     

Post-tetanic strengthening of evoked electrical responses of the sensomotor cortex]

A study has been made of the posttetanic potentiation of evoked potentials (PTP EP) in the sensorimotor cortex, appearing in response to VPL stimulation. A distinct PTP EP of the cortical surface has been found as well as considerable differences in its intensity recorded at different portions of deep cortical layers (700 to 1600 mu). Suggestions were made regarding the origin of the phenomena observed.     

Effect of bradykinin and morphine on rat sensomotor cortex neurons]

As revealed in acute experiments on rats bradykinin applied microiontophoretically produced neuronal activation in the sensory-motor region of the rat brain cortex. Morphine applied iontophoretically prevented bradykinin effect. It is suggested that bradykinin interacts with opiate receptors in the cortical neurones.     

Relations between the superior colliculus and sensomotor cortex in conscious rabbits

The tonic influence of the superior colliculus (SC) on the formation of visual evoked responses of the sensomotor cortex (SMC) was demonstrated in experiments on conscious rabbits. The influence of SC on the function of SMC was found to be realized with the involvement of tectothalamocortical (through the nucleus lateral is posterior thalami — NLPT) connections. SMC of the conscious rabbit, in turn, exerts a phasic inhibitory influence on visual function of SC. The findings are discussed in the light of involvement of tectocortical and corticotectal inter-relations in the organization of visuomotor integration, which is essential for visually controlled behavior.A. I. Karaev Institute of Physiology, Azerbaidzhan Academy of Sciences, Baku. Translated from Neirofiziologiya, Vol. 24, No. 1, pp. 37–44, January–February, 1992.     

Spatial organization of direct connections of the sensomotor cortex with the rhombencephalon and spinal cord in the cat

The distribution and ultrastructure of terminals of corticofugal fibers in the rhombencephalon and spinal cord of the cat were studied by light and electron microscopy at various times (4–6 days) of experimental degeneration after extensive or local (about 3 mm in diameter) destruction of the sensomotor cortex. Definite topographical organization of corticofugal projections in the nuclei of the dorsal columns and in the spinal cord was detected by the Fink — Heimer method. After local destruction of the lateral zones of the sensomotor cortex, maximal foci of degeneration were found in the nucleus of Burdach and the lateral basilar region of the cervical segments; after local destruction of the medial zones of the sensomotor cortex maximal foci of degeneration of corticofugal fibers were observed in Goll's nucleus and the lateral basilar region of the lumbar segments. The results show that even an extremely localized area of the cat sensomotor cortex forms two separate systems of descending corticospinal fibers. The first projects into the dorsolateral and dorsomedial parts of the intermediate zone, chiefly contralaterally, whereas the second projects bilaterally into both dorsolateral and ventromedial parts of the intermediate zone. The possible physiological significance of this duality of projections is discussed.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 8, No. 2, pp. 126–133, March–April, 1976.     

Connections between the parietal cortex with the lateral suprasylvian gyrus (Clare-Bishop area) and auditory cortex in cats

Projections between areas 5 and 7 and the lateral suprasylvian gyrus (Clare-Bishop area) were investigated using anterograde degeneration techniques. This showed a topographic organization of projections from areas 5 and 7 to the lateral suprasylvian gyrus. Area 5 association fibers terminate mainly in the anterior portion of the lateral suprasylvian gyrus; this corresponds to the intermediate zone and anterior section of the posterior suprasylvian region. Area 7 efferents are located more caudally, terminating in the posterior section of the intermediate zone and in the posterior region, excluding the outer posterior limits. Fields 5 and 7 give rise to single efferent fibers terminating in the auditory cortex. Fibers from area 5 terminate in the medial ectosylvian and medial, sylvian gyri, i.e., in zones Al and AII or areas 22 and 50. A projection from area 7 terminates at the superior border of the medial ectosylvian gyrus, corresponding to the upper limit of zone A1 or areas 22 and 50.L. A. Orbeli Institute of Physiology, Academy of Sciences of the Armenian SSR, Erevan. Translated from Neirofiziologiya, Vol. 22, No. 6, pp. 739–745, November–December, 1990.     

Interhemispheric connections of the parietal area of the cat cerebral cortex

The interhemispheric connections of the temporal cortical area in the cat cerebrum have been investigated after electrolytic coagulation of separate fields with subsequent study of the degenerated fibers course after Nauta--Gygax method. The fields 5 and 7 give origin mainly to homotopic fibers, terminating in symmetrical fields of the contralateral hemisphere. These fields also give origin to a small number of heterotopic commissural fibers, that provide bilateral connection of the fields 5 and 7 and do not get beyond the limits of the temporal cortex. The commissural fibers of the temporal cortex get into the contralateral hemisphere through the corpus callosum. In the latter, the commissural fibers of the field 5 are situated more rostral of the fibers running from the field. 7. This corresponds to topographic arrangement of the fields on the cortical surface.     

Comparative study of inter- and intrahemispheric cortico-cortical connections in gerbil auditory cortex

Topographic distributions and laminar pattern of cortico-cortical projections from the primary auditory field (AI), anterior auditory field (AAF), dorsoposterior field (DP), ventroposterior field (VP), dorsal field (D) and ventral field (V) were studied in relation to tonotopic maps in combined anatomical, electrophysiological and 2-deoxyfluoro-D-glucose (2DG) experiments. Distributions of axons were examined by means of retrogradely-transported fluorescent tracer Fast Blue (FB) injected in the primary (AI) and anterior (AAF) auditory field. Injections of fluorescent tracer were placed in electrophysiologically-identified locations of AI and AAF. Neurons in AAF, DP, VP and V project to AI in the ipsilateral hemisphere. This area also receives projections from AI, AAF and D from the contralateral hemisphere. In AI, DP and VP, neurons are connected with AAF in the ipsilateral hemisphere and AI and AAF in the opposite hemisphere. In all cases, patches of labeling are distributed along 2DG bands oriented parallel to the isofrequency line. Substantial numbers of retrogradedly labeled neurons with similar best frequencies (BFs) were observed in the ipsilateral and moderate to scant numbers in the contralateral hemisphere. In general, regions near the injection sites receive more densely-labeled projections than do more distant targets. In both hemispheres, the supragranular layer III contains the greatest concentration of cortico-cortical cells bodies; the granular and infragranular layer V contains a somewhat lower concentration.     

Relationship between size and eccentricity of receptive fields in the cat cerebral cortex area 21

Sizes of receptive fields (RF) in areas 21, 7, and 19 of the cerebral cortex were measured in cats. No correlation between size of RF and eccentricity (average: R=0.15; p>0.05) was found in area 21, as distinct from areas 7 and 19, where size of RF increased with distance from the center to the periphery (R=0.5; p<0.01 and R=0.9; p<0.0001 respectively). Larger RF were found in the left hemisphere than in the right in field 21; size of RF also decreased and leveled out with a move away from area 21 and towards areas 7 and 19.I. P. Pavlov Institute of Physiology, Academy of Sciences of the USSR, Leningrad. Translated from Neirofiziologiya, Vol. 19, No. 2, pp. 233–236, March–April, 1987.     

Reactions of neurons in the dental projection area of the rabbit sensomotor cortex to photic, acoustic and painful stimulation of the dental pulp]

In experiments on unrestrained rabbits interactions of sound (tone, click), light and pain excitation occurring during stimulation of the dental pulp in the neurons of the cortical sensomotor zone, in the area of representation of the dental afferents were studied by the microelectrode method. It was shown that bi- and polysensor convergence of excitation is realized in the cells of this area. It is suggested that convergence of excitation underlies the mechanisms of formation of the integral systemic pain reaction during stimulation of the dental receptors.     

The mechanism of interaction between the thalamic posterior lateral nucleus and the sensomotor cortex in rabbits

The thalamic posterior lateral nucleus was shown to exert phasic and tonic effects on the function of sensomotor cortex: the former in the form of pulvinar-cortical responses, and the latter in the form of foci of increased or decreased excitability. The findings suggest an inhibitory tonic effect of the sensomotor cortex on neuronal network of the posterior lateral nucleus.