Reflection of the plastic properties of very simple neuronal assemblies in the statistical characteristics of the spike activity of their elements. Monosynaptically connected neurons

Changes of cross-correlation histograms (CCH) of impulse trains and of mean interspike intervals (ISI) of monosynaptically connected neurones under changes of interneuronal connection efficiency, neuronal excitability and action on these neurones of independent irregular afferent synaptic inflows, were studied by methods of mathematical and biomathematical modelling of synaptic neuronal interaction (computer-controlled experiment on mollusc neurones). It was shown that statistical of increase of efficiency of monosynaptic excitatory or inhibitory interneuronal connection (amplitude enhancement of corresponding postsynaptic potential) is an increase of the main peak or trough of normalized CCH of impulse trains accompanied by a decrease of mean ISIs of both neurones.     

Reflection of the plastic properties of monosynaptically interconnected neurons in the statistical characteristics of their spike activity

By mathematical and biomathematical methods of neuronal interaction modelling, changes were studied of cross-correlation histograms (CCH) of impulse flows and of average interimpulse intervals of monosynaptically interconnected neurones, at changes of efficiency of forward and backward connections, of excitability of neurones and of summate action on them of independent random afferent synaptic inflows. It is shown, that a single sign of efficiency increase of monosynaptic excitatory or inhibitory connection between neurones (amplitude increase of the corresponding postsynaptic potential) consists in amplitude increase of the main peak or trough the rated CCH of their impulse flows, followed by a decrease of average interspike intervals of both neurones.     

Reflection of the plastic properties of 2 neurons with a common monosynaptic input in the statistical characteristics of their impulse activity

Changes of cross-correlation histograms (CCH) of impulse trains and of mean interspike intervals (ISI) of neurones N1 and N2 with a common monosynaptic excitatory or inhibitory-excitatory input from N3, at changes of efficiency of interneuronal connections, neurone excitability and summate action on them of independent random afferent synaptic inflows were studied by methods of mathematical and biomathematical modelling of neuronal interaction. It was shown that the increase of amplitude of the central peak (trough) of a normalized CCH of N1-N2 accompanied by reduction of mean ISI of N1 and N2, is either a sign of an increase of the amplitude of postsynaptic potentials of N1 and N2 elicited by impulses of the nonrecorded N3 or a sign of an increase of mean ISI of N3.     

A comparative statistical study of hippocampal neuronal spontaneous spike activity in situ and in vitro

The statistical characteristics of the spontaneous spike activity of rat hippocampal neurons in fields CA_1?2 were compared in situ and in tissue culture. Statistical analyses have shown strong similarities in estimators of basic numerical characteristics of interspike interval (ISI) distributions. These similarities may serve as evidence of maintenance of normal functional properties and an “organotypic arrangement” of neurons in tissue culture, and they are also indicative of an intrahippocampal origin of the spontaneous impulse activity in the hippocampus. On the other hand, some differences are noted in the tests of firing patterns. Interpretation of these results leads to some assumptions about mechanisms of the phenomenon under study.     

Modeling of ionic channel properties and its role in shaping neuronal spike activity

An electronic analog of a neuron operating in real time is presented. The sequence of signal formation in the analog follows that of processes occurring at the synapse, postsynaptic membrane, and soma of the cell. Concepts of the synapse as a "key" and of the postsynaptic membrane as ionic channel with conductance changing under the action of transmitter and intracellular potential having been put into effect in the physical model, the neuronal analog could be set up along the same lines as a spike generator in which operation of the synaptic apparatus and the structure of neuronal dendrites could be reproduced. Spike train transformation processes typical of different types of neurons (such as motoneurons and Renshaw cells) were modeled by changing the parameters of membrane resistance and capacitance. Findings from research on simple neuronal networks have made it possible to use the analogs suggested to study the principles governing organization of neuronal structures as well as mechanisms underlying neuronal interaction, particularly those of the motor control system.I. P. Pavlov Institute of Physiology, Academy of Sciences of the USSR, Leningrad. Translated from Neirofiziologiya, Vol. 21, No. 3, pp. 379–389, May–June, 1989.     

Reflection of space characteristics of an acoustic signal in the neuronal activity of the caudate nucleus

In chronic experiment, responses of single neurons of the caudate nucleus (CN) to spatial characteristics of acoustic signal have been investigated in dogs. It is shown that 92% of neurons of the caudate nucleus' head responding to sound stimulation asymmetrically react to contra- and ipsilateral monoaural, with a greater efficacy of a contralateral stimulation. For 50% of the CN neurons simultaneous sound inputs appear more effective in comparison with contralateral stimulation. 77% of the caudate neurons responding to sound have shown sensitivity to change of the value and sign of the interaural delay.     

Correlations of neuronal spike discharges of VL neurons during spontaneous firing and during the activity evoked by peripheral stimulation

The temporal relations between simultaneously recorded neurons of the nucleus ventralis lateralis (VL) of cat thalamus were studied. The interaction and the functional connections between individual VL neurons are described. This was achieved with an application of cross correlation techniques. The response patterns of different individual neurons to somatic sensory and photic stimuli were also analyzed. For the purpose of classifying neurons as thalamocortical relay cells (T-C) and non relay cells (N-C) which do not project to the motor sensory cortex antidromic cortical stimulation was used. This stimulation was also used as conditioning one when proceeded peripheral stimuli. To analyze the nonspecific specific interactions upon single neurons conditioning photic stimuli were applied. The results show that T-C neurons are antidromically excited from a wide cortical areas and that the functional interaction between T-C neurons is mediated by a shared input from common sources. It is further postulated that N-C cells interposed between relay neurons subserve the functions of gating units modifying the neuronal network of lateral ventral nucleus of the thalamus.     

2 types of neurons differing in their plastic properties: study of ionic mechanisms

Plasticity ionic mechanisms of 2 types of neurones identified in the brain of snail Helix pomatia: habituating and non-habituating to rhythmic intracellular stimulation by DC pulses were studied. It has been shown that the development of habituation is due to entering of Ca2+ into the cell and by its activation of Ca-dependent K-conductivity of the membrane, leading to hyperpolarization, decrease of input resistance and elimination of spike response to stimulation. Depression of Ca-dependent K-conductivity by quinine totally blocks the ability of the neurons to habituate to stimulation. The data obtained on non-habituating neurons testify that their non-habituation to intracellular stimulation results from their absence or weak manifestation of Ca-dependent K-conductivity in their membrane. Ca2+ entering non-habituating cells during electrical stimulation may have depolarizing and facilitating effects.     

Background spike activity of cerebellar nucleus interpositus neurons in rats

Using computer analysis of the background spike activity recorded from cell units of the cerebellar nucleus interpositus, it was possible to distinguish several dynamic types and regularity gradings that specifically characterize these neurons, and to correlate these characteristics with the statistical parameters of their activity.Translated from Neirofiziologiya, Vol. 25, No. 2, pp. 98–100, March–April, 1993.     

Regression analysis of the spontaneous spike activity of neurons in snail ganglia

Regression analysis of the spontaneous spike activity of neurons in Helix pomatia was carried out with the aim to establish the statistical parameters of this activity under constant experimental conditions and during longer time intervals. The activity of 38 randomly chosen neurons in visceral and parietal ganglia, penetrated by microelectrodes and activated either endogenously by pacemaker potentials or by synaptic inputs, was recorded during time intervals lasting from 20 min to 3 h. The main results of the statistical analyses are presented in the table where the parameters of both cell types are listed. The validity of the regression analysis applied here is discussed from the point of the possibility it offers for carrying on the data processing quickly and without applying complex calculating means. The results are also considered regarding the current interest of our research group.     

Rhythmic aftereffects in the osmotic stimulation-induced spike activity of thermosensitive neurons of the preoptic region

Acute experiments on cats showed that mild shifts in osmotic homeostasis (within physiological limits) result in modifications of the spike activity in a significant share of thermosensitive neurons of the Preoptic region (RPO); in particular, rhythmic aftereffects (RAE) are induced in these units. The neurons were identified as thermosensitive cells according to their responses to local heating/cooling (±7°C) of the pad surface of the contralateral forelimb. Osmotic stimulation was performed by infusions of 0.1–0.3 ml of 3.0 or 0.2% NaCl solutions in thea. carotis communis dextra. The RAE phenomenon more frequently developed in thermosensitive neurons after infusions of the hyportonic solution (13/34) than after hypotonic infusions (6/34), while in non-thermosensitive neurons the situation was reverse: hypotonic infusions induced RAE more frequently. Certain specificities were also observed in localization of the thermosensitive RPO neurons, in which osmotic stimulation-induced RAE was observed. The mechanisms of such induction and possible functional role of spike grouping in the activity of thermosensitive neurons are discussed.     

Extra spike formation in sensory neurons and the disruption of afferent spike patterning

The peculiar pseudounipolar geometry of primary sensory neurons can lead to ectopic generation of "extra spikes" in the region of the dorsal root ganglion potentially disrupting the fidelity of afferent signaling. We have used an explicit model of myelinated vertebrate sensory neurons to investigate the location and mechanism of extra spike formation, and its consequences for distortion of afferent impulse patterning. Extra spikes originate in the initial segment axon under conditions in which the soma spike becomes delayed and broadened. The broadened soma spike then re-excites membrane it has just passed over, initiating an extra spike which propagates outwards into the main conducting axon. Extra spike formation depends on cell geometry, electrical excitability, and the recent history of impulse activity. Extra spikes add to the impulse barrage traveling toward the spinal cord, but they also travel antidromically in the peripheral nerve colliding with and occluding normal orthodromic spikes. As a result there is no net increase in afferent spike number. However, extra spikes render firing more staccato by increasing the number of short and long interspike intervals in the train at the expense of intermediate intervals. There may also be more complex changes in the pattern of afferent spike trains, and hence in afferent signaling.     

Regulation of the plastic properties of an electro-excitable neuronal membrane by serotonin

The action of serotonin on plastic properties of electroexcitable membrane was studied in Helix lucorum parietal ganglia on neurones of two types: habituating (HC) and nonhabituating (NHC) to rhythmic intracellular stimulation by impulses of depolarizing current. Serotonin produced an effect of facilitation on HC (increase of responses to stimulation against the background of depolarization and rise of input resistance of the cell). Besides, serotonin completely blocked the ability of these cells to habituate to rhythmic stimulation. The obtained data testify that such action of serotonin may be based on suppression by it of C-dependent K-conductivity. Serotonin suppresses responses of NHC to stimulation and contributes to their habituation to rhythmic stimulation. Such action is due to serotonin suppression of Ca-conductivity, and, consequently, to elimination of the mechanism of action potential generation.     

Generation of spike activity by dendrites of secondary neurons of the rat olfactory bulb

Experiments on secondary neurons of the rat olfactory bulb showed the existence of a third region of action potential generation. It evidently consists of dendrites. This is shown by the distance from the soma of the point where action potentials arise initially and by the recording of spontaneous action potentials of comparatively low amplitude, not spreading into the axon. Action potentials are generated by apical dendrites and also, perhaps, by basal dendrites. Besides partial action potentials with stable amplitude, partial action potentials with, for practical purposes, a stepwise changing amplitude also were recorded. It is suggested that the amplitude of the partial action potentials is modified by IPSPs in the spike-generating zones.M. V. Lomonosov Moscow State University. Translated from Neirofiziologiya, Vol. 8, No. 3, pp. 282–290, May–June, 1976.