Correlation between different forms of trace phenomena in the activity of rabbit visual cortex neurons]

Plastic changes in the components of the unit responses in the rabbit visual cortex (VC) in the course of electrical stimulation (with different parameters) of the lateral geniculate body (LGB) were compared with the capacity of the same units for trace driving to the LGB preceding stimulation. Potentiation of inhibition (inhibitory pauses) in reponse to electrical LGB stimulation is the main plastic phenomenon in the activity of VC units. Trace driving is characteristic predominantly of units with enhanced plasticity of the excitatory sign, a tendency toward epileptiform activity after LGB tetanization. In most cases inhibitory reaction is expressed in weakening of the periodic component of neuronal activity corresponding to the frequency of stimulation. The level of trace suppression of periodicity positively correlates with potentiation of the inhibitory pause during prolonged LGB stimulation.     

Cross-correlation analysis of background neuronal activity in guinea pig neocortical slices in vitro

Interaction between the background activity of adjoining neurons was investigated using simultaneous recording in surviving slices from the guinea pig sensory motor cortex by means of cross-correlation analysis. A numerical connection was found between the timing of successive discharges in sixteen of the twenty six neuronal pairs investigated. Significant discrepancies were observed in correlation tables, mainly in the range of time shifts of ±100 msec from zero point. These emerged as symmetrical or asymmetrical peaks of up to 150 msec in duration and negative shifts measuring up to 200 msec. More complex positive-negative cross-correlation patterns were also encountered. These findings may be compared with those obtained in the cortex of the intact brain. The subject of the contribution made by intrinsic cortical neuronal interaction and that of external afferents to firing correlation is discussed.Institute of Biological Physics, Academy of Sciences of the USSR, Pushchino, Moscow. Translated from Neirofiziologiya, Vol. 23, No. 4, pp. 392–399, July–August, 1991.     

Response of rabbit visual cortex neurons to direct stimulation by current of different intensities

Response was investigated in 47 rabbit visual cortex neurons to direct intracortical electrical stimulation consisting of single biphasic pulses of increasing intensities within the 150–2,700 µA range. Minimum level for generating all components of response to electrical stimulation remained similar from one neuron to the next, ranging between 150 and 600 µA. Three different patterns of dependence between numbers of spikes at different stages of response and current amplitude were identified: stable, gradual and selective patterns. Percentages of stable dependences were lower for after-discharges in comparison with initial firing (at 11 and 26% respectively) and the proportion of selective dependences were somewhat higher (at 32 and 21%). The selective dependence observed could imply the existence of optimum current levels at which peak neuronal response occurs. At the same time, duration of inhibitory pauses lengthened uniformly in the response of all test neurons during increasing intensity of the electrical stimuli. Findings obtained during this study may have a practical application in matters connected with visual prosthetics in the blind.M. V. Lomonosov State University, Moscow. Translated from Neirofiziologiya, Vol. 21, No. 2, pp. 239–247, March–April, 1989.     

Attention modulates contextual influences in the primary visual cortex of alert monkeys

The response properties of cells in the primary visual cortex (V1) were measured while the animals directed their attention either to the position of the neuron's receptive field (RF), to a position away from the RF (focal attention), or to four locations in the visual field (distributed attention). Over the population, varying attentional state had no significant effect on the response to an isolated stimulus within the RF but had a large influence on the facilitatory effects of contextual lines. We propose that the attentional modulation of contextual effects represents a gating of long range horizontal connections within area V1 by feedback connections to V1 and that this gating provides a mechanism for shaping responses under attention to stimulus configuration.     

Laminar distribution of neurons with different types of receptive fields in the rabbit visual cortex

Investigation of receptive fields of 232 primary visual cortical neurons in rabbits by the use of shaped visual stimuli showed that 21.1% are unselective for stimulus orientation, and 34.1% have simple, 16.4% complex, and 18.5% hypercomplex receptive fields, and 9.9% have other types. Neurons with different types of receptive fields also differed in spontaneous activity, selectivity for rate of stimulus movement, and acuteness of orientational selectivity. Neurons not selective to orientation were found more frequently in layer IV than in other layers, and very rarely in layer VI. Cells with simple receptive fields were numerous in all layers but predominated in layer VI. Neurons with complex receptive fields were rare in layer IV and more numerous in layers V and VI. Neurons with hypercomplex receptive fields were found frequently in layers II + III and IV, rarely in layers V and VI. Spontaneous unit activity in layer II + III was lowest on average, and highest in layer V. Acuteness or orientational selectivity of neurons with simple and complex receptive fields in layers II + III and V significantly exceeded the analogous parameter in layers IV and VI.A. N. Severtsov Institute of Evolutionary Morphology and Ecology of Animals, Academy of Sciences of the USSR, Moscow. Translated from Neirofiziologiya, Vol. 17, No. 1, pp. 19–27, January–February, 1985.     

Focal evoked potentials in the rabbit visual cortex: Current source density analysis

Focal evoked potentials arising in the rabbit visual cortex in response to photic stimulation from a point source were analyzed by determination of the current source density. The response to a point stimulus arises in a circumscribed area of cortex, corresponding retinotopically to the stimulated point of the visual field and it consists of two components. The first component is created by a local current sink at a depth of 0.6 to 1.0 mm (the level of layer IV) and has a latent period of 30 msec and a peak time of 50 msec. The second component is created by a more diffuse current sink at a depth of 0.2–0.3 to 1.3–1.5 mm (levels between layers III and VI); the time to the maximum was 90–100 msec. These local sinks are regarded as active, created by depolarizing synapses. Passive current sources are concentrated around zones of active sinks. The two components of the response may reflect two consecutive waves of activation of cortical neurons.A. N. Severtsov Institute of Evolutionary Morphology and Ecology of Animals, Moscow. Translated from Neirofiziologiya, Vol. 13, No. 5, pp. 474–481, September–October, 1981.     

Microiontophoretic study of the effect of biogenic amines on unit activity in the rabbit visual cortex

The effect of acetylcholine, noradrenalin, and serotonin on spontaneous activity of visual cortical neurons and on their activity evoked by flashes, recorded extracellularly, was studied by microiontophoresis in unanesthetized rabbits. The ability of visual cortical neurons to respond to light does not correlate with their sensitivity to acetylcholine. This substance, which changes the spontaneous firing rate of many of the neurons tested, was less effective against their evoked activity. Noradrenalin had a powerful depressant action on both spontaneous and evoked activity of most neurons studied. Serotonin acted in different ways on the spontaneous and evoked activity of some neurons tested. It is postulated that acetylcholine mediates reticulo-cortical inputs, noradrenalin is a true inhibitory mediator in the cerebral cortex, and serotonin has a presynaptic action by preventing the liberation of natural mediators.     

Effect of strychninization of the rabbit visual cortex on evoked activity in the lateral geniculate body

Changes in the parameters of responses of "low-frequency" and "high-frequency" neurons evoked in the lateral geniculate body by flashes or electrical stimulation of the optic nerve were investigated in immobilized and anesthetized rabbits after strychninization of the visual cortex. Under these conditions mainly an increase in the mean discharge frequency in the responses and a decrease in their latent periods were found in the "low-frequency" neurons, probable evidence of dominance of corticofugal facilitation. In most "high-frequency" neurons, on the other hand, the mean discharge frequency in the responses decreased and the latent periods were increased, evidence of dominance of corticofugal inhibition. It is suggested that reciprocal corticofugal influences exist on neurons connected with central and peripheral channels of the visual projection pathway.Institute of Higher Nervous Activity and Neurophysiology, Academy of Sciences of the USSR, Moscow, Translated from Neirofiziologiya, Vol. 8, No. 5, pp. 459–466, September–October, 1976.     

Computation of color and brightness differences by neurons in the rabbit visual cortex

Changes in activity of 54 neurons in the rabbit visual cortex evoked by the replacement of eight color and eight achromatic stimuli in pairs were analyzed. The diffused stimuli generated by color SVGA monitor were used in the experiments. The earliest response of phasic neurons (50-90 ms after the replacement) was strongly correlated with differences between stimuli in color or intensity. This response ("the signal of differences") was used as a basis of a matrix (8 x 8) constructed for each neuron. Such matrices included mean numbers of spikes per second in responses to changes of different stimuli pairs. All matrices were subjected to factor analysis, and the basic axes (the main factors) of sensory spaces were revealed. It was found that 16 neurons (30%) detected only achromatic differences between stimuli. Perceptual spaces of these neurons were two-dimensional with brightness and darkness orthogonal axes. The spaces of 12 neurons (22%) were four-dimensional with two chromatic and two achromatic axes. The structure of the perceptual space reconstructed from neuronal spikes was similar to the space calculated from the early VEP components recorded under similar conditions and to another space reconstructed on the basis of rabbit's instrumental learning. The fundamental coincidence of color spaces revealed by different methods may reflect the general principle of vector coding in the visual system and suggests the coexistence of two independent cortical mechanisms of the detection of chromatic and achromatic differences.