Reticular activation by splanchnic afferents: its influence on visual projections at the level of the cerebral cortex in cats]

In an previous work, we have shown a strong increase of visual evoked potentials of the medial lateral gyrus by splanchnic stimulation. This present study demonstrates that this effect is due to the activation of the substantia reticularis. Actually, we observed: 1) an increase of the reticular visual potential by splanchnic stimulus in convergent zone; 2) an increase of the visual evoked potential in the primary cortical area by stimulation of this reticular formation. These results show the existence of a functional pathway including the splanchnic nerve, the reticular formation and the visual cortex.     

Relationship between level of vigilance and changes in the receptive fields of the cat visual cortex]

The activity of 118 neurones of the primary visual cortex (17th field) was studied in unanesthetized cats, immobilized with d-tubocurarine, in a state of calm wakefulness and in strained attention, alarm. The strained attention was elicited by an air-puff directed to the corner of the closed eye, not used for the photic stimulation. Considerable rearrangments of the receptive field of neurones (94%) were observed in the state of strained attention. In the majority of the studied cortical cells (75%) during 10-30 minutes the excitatory centres of their receptive fields became narrower while their inhibitory periphery widened; in the cells with the inhibitory centres of the receptive fields they were larger in 80% of the cases. It is shown that with dark, mesopic and scotopic adaptation the major characteristics of the changes in the receptive fields remain unaltered. It is assumed that these effects have a behavioural value for the organism, because the created rise in the level of alertness is accompanied by a sharpening of the receptive fields, i.e. by a greater ability to a fine analysis and recognition of visual images.     

Organization of interneuron interaction in the cerebral cortex of cats learning to distinguish visual stimuli

Focal and impulse activity of neurones, recorded in pairs with one microelectrode, was studied in the field 18 of cat visual cortex, during learning of visual differentiation of shaped stimuli--light strips with different orientation one towards the other. Differences were found between functional properties of neighbouring visual neurones before learning and in learning dynamics. During learning, independently of visual signal stimuli orientation, reaction patterns of the same type were formed in neighbouring visual neurones.     

Synapsoarchitechtonics of the parietal and acoustic regions of the cerebral cortex of cats]

The synapse architecture of the simcipital and auditory cortex of the cat (fields 7 and 22 after M. O. Gurevich and oth., 1929) was studied electron microscopically. In the both areas of the cortex there are much more axo-dendritic synapses that axo-somatic ones. In the upper layers the synapses are more often formed on small dendrites and thorns, while in layers IV-VI they often occur on the main trunks of large dendrites. The synapses on small branches and thorns of dendrites contain spherical vesicles, and the synapses on on large dendrites are formed by the terminals of two kinds-with flattened and spherical vesicles. The amount of axo-somatic synapses increases towards the lower layers of the cerebral cortes. The synapses on the soma and apical dendrites of the pyramid neurons always contain flattened vesicles; on the stellate neurons there occur perisynaptic terminals with sperical vesicles as well.     

Causal interactions between the cerebral cortex and the autonomic nervous system

Mental states such as stress and anxiety can cause heart disease.On the other hand,meditation can improve cardiac performance.In this study,the heart rate variability,directed transfer function and corrected conditional entropy were used to investigate the effects of mental tasks on cardiac performance,and the functional coupling between the cerebral cortex and the heart.When subjects tried to decrease their heart rate by volition,the sympathetic nervous system was inhibited and the heart rate decreased.When subjects tried to increase their heart rate by volition,the parasympathetic nervous system was inhibited and the sympathetic nervous system was stimulated,and the heart rate increased.When autonomic nervous system activity was regulated by mental tasks,the information flow from the post-central areas to the pre-central areas of the cerebral cortex increased,and there was greater coupling between the brain and the heart.Use of directed transfer function and corrected conditional entropy techniques enabled analysis of electroencephalographic recordings,and of the information flow causing functional coupling between the brain and the heart.     

Connections of field 17 of the visual cortex with the mammillary nuclei in cats]

Using optical techniques by Nauta--Gygax, Wiitanen and Eager, degenerating nerve fibres and terminals were demonstrated to be present in the hypothalamic mammillary nuclei 9 days after a part of field 17 of the brain cortex was extirpated. Electron microscopic examination revealed different changes in large and small terminals of the boutons 5, 7 and 11 days after similar operations. The data represented demonstrate direct monosynaptic bilateral connections in field 17 of the optic cortex with the hypothalamic mammillary nuclei in cats. They are realized by fine fibrillae terminating mainly in large terminal boutons which form synapses on big and small dendritic branches. Thus, there is a structural base for the immediate influence of the optic cortex on the posterior hypothalamus.     

Afferent connections of the prefrontal cerebral cortex in cats

In experiments with unilateral injections of horseradish peroxidase microdoses into the dorsal sites of external g. proreus. using the method of retrograde axonal transport, labeled neurons have been revealed ipsilaterally in the singular cortex of telencephalon, in amygdala and thalamic structures of the brain (n.medio-dorsal nucleus, anterior group of nuclei and intralaminar nuclei). The role of the direct projections discovered to the prefrontal cortex in the formation of emotional component of pain is discussed.     

Neural assemblies and laminar interactions in the cerebral cortex

 Neural assemblies are assumed to become organized and to operate within the cerebral cortex, and so must be constrained by the cytological and physiological properties of this laminated structure. A hypothesis of such assemblies is presented, based on important details of neuronal architecture and physiology in different cortical laminae. Laminae II, III and VI, which are the origin and termination of most cortico-cortical projections, are regarded as the site of storage of most of the information encoded by assemblies – a neuronal ‘library’. Laminae II and III are the most sensitive coincidence detectors, and therefore probably initiate the process of assembly formation. However, these three laminae have very low levels of spontaneous activity in the waking state, and so active cell assemblies cannot base their functioning on these laminae alone. Lamina V pyramidal cells have a much higher level of spontaneous activity. Thus, indirect pathways between ‘library’ cells, via lamina V pyramidal cells, are likely to be more secure than direct ones. It is proposed that direct links between ‘library’ cells become stabilized by Hebbian strengthening, once the recipient ‘library’ cell has been ‘primed’ by neural activity transmitted indirectly via lamina V neurones. Thus lamina V neurones could catalyse the process of assembly formation. Given this proposal, lamina V cells, in their interaction with ‘library’ cells, would code information in terms of precisely timed individual impulses, but would employ a code based on slower frequency changes in their descending influences upon neural centres in the brainstem and spinal cord. Predictions for single unit and electrographic experiments are discussed. Received: 30 November 1995/Accepted in revised form: 3 June 1996     

Distribution of terminal intragenicular depolarization of visual afferences during reserpine PGO activity]

The distribution during reserpine-induced PGO spikes of terminal depolarization among the visual afferents in cat lateral geniculate nucleus was studied. The terminal depolarization was found to be distributed rather evenly among the crossed and uncrossed retinal afferents of different conduction velocities.     

Representation of three-dimensional visual space in the cerebral cortex

This article reviews two issues relevant to the topic of how three-dimensional space is represented in the cerebral cortex. The first is the question of how individual neurons encode information that might contribute to stereoscopic estimation of visual depth. Particular attention is given to the current understanding of the neural representation of motion through three-dimensional space and to the complexities that arise in interpreting neuronal responses to this complex stimulus parameter. The second issue considered is the disorderlines that exists in the retinotopic mapping of the visual field in some cortical visual areas. Several extrastriate areas have been found to contain maps of the contralateral visual hemifield that are disorderly in the sense that the representation of various parts of the visual field are often misplaced or grossly over-or under-represented. It is suggested that this disorderlines may in some cases represent adaptations to facilitate certain types of visual functions.     

Dynamics of functional reciprocal connections between cerebral motor cortex neurons under stimulation in cats

Activity was recorded from neurons belonging to the representation of the forelimb in the motor cortex (sulcus cruciatus, L 7–9 mm) using multiple multi-channel/barrel electrodes during acute experiments on cats. Cross-correlation analysis of impulse trains was adopted to investigate dynamics of interneuronal connections during passive flexion and electrical stimulation of the limb contralateral to the recording site. It was found that neither passive bending nor electrical stimulation of the limb leads to a significant increase in the total number of direct relationships between cortical neurons. At the same time, passive flexion does produce a considerable decrease in the number of instances of both inputs operating in neighboring neurons (50–100 µm apart) and an increase in cells located further (between 100 and 400 µm) apart. Some increase in the number of direct inhibitory interactions between neighboring neurons was observed during electrical stimulation.Institute of Higher Nervous Activity and Neurophysiology, Academy of Sciences of the USSR, Moscow. Nentskii Institute of Experimental Biology, Warsaw, Poland. Center of Experimental and Clinical Medicine, Warsaw, Poland. Translated from Neirofiziologiya, Vol. 23, No. 1, pp. 73–80, January–February, 1991.