Effect of the enkephalin derivative DAGO on neuronal behavior and activity in the neocortex and hippocampus of rabbits during the acquisition of conditioned defense and inhibitory reflexes

After subcutaneous injection of 25 mkg/kg morphine-like opiate--DAGO a decrease was observed of probabilities of rabbits movements at light flashes--defensive reflex signal. The level of the background neuronal impulse activity became gradually lower in the sensorimotor cortex and the hippocampus and did not change in the visual cortex. Decrease and restoration of responses to the reinforcing stimulus (electrocutaneous limb stimulation) in all studied cortical zones proceeded in one direction while there were significant differences in dynamics of responses to inhibitory and reinforced light flashes depending on the studied cortical zone and biological significance of the stimulus. Appearance is discussed of particular characteristics of neurones systemic organization during learning at change of reinforcement properties under the influence of the studied substance, as well as similarity of some features of mechanisms of internal inhibition elaboration in a defensive situation and of properties of positive reinforcement.     

Effect of piracetam on the neuronal activity of the neocortex and on behavior in rabbits during learning

Against the background of the action of piracetam--a cyclic derivative of GABA--in a dose of 200-400 mg/kg, no significant changes were observed of probabilities of motor reactions to inhibitory and reinforced light flashes. Piracetam in that dose did not affect inhibitory pauses in responses of neurones in the visual area and corresponding late components of the evoked potential to nonreinforced light flashes, i.e. it did not intensify inhibitory hyperpolarization processes in the cerebral cortex. Piracetam administration improved differentiation of inhibitory and reinforced light flashes judging by bioelectric parameters of the brain activity as a result of intensification of pain reinforcement action on cortical neurones. The carried-out experiments revealed significant differences in neurophysiological mechanisms of action of piracetam and fenibut--GABA linear derivate related to nootropic class.     

On neurotransmitter mechanisms of reinforcement and internal inhibition

Experiments reported in this study have been performed in order to investigate cholinergic and GABA-ergic neurotransmitter systems and substance P in the realization of internal inhibition and pain reinforcement. This was accomplished during the elaboration of inhibitory and defensive conditioned reflexes to light flashes in alert, nonimmobilized rabbits. Present results together with a review of past research indicate that the cholinergic system is directly involved in transmitting the effects of pain reinforcement to neocortical neurons. Substance P, a neuropeptide, reduces the background activity of neocortical and hippocampal neurons and the response of cortical neurons to pain and positive conditioned stimuli. The cholinergic system and substance P exert a modulating effect on the elaboration of internal inhibition. Phenybut, a GABA derivative capable of penetrating the blood-brain barrier, enhances inhibitory hyperpolarization in the cerebral cortex and improves discrimination between the inhibitory and reinforcing light flashes. It appears, therefore, that the GABA-ergic system plays a leading part in the elaboration of internal inhibition. Neuronal activity and slow potential changes in response to positive conditioned and pain stimuli occur in the same direction after administering the preparations, and the dynamics of these changes is different from that in responses to inhibitory stimuli. It may be supposed on these grounds that the neurotransmitter and neuromodulator systems studied possess a considerable degree of plasticity.     

Effect of ethanol on excitatory and inhibitory processes in the visual cortex of rabbits undergoing learning

Subcutaneous ethanol injection to waking rabbits in a dose of 2-6 g/kg causes discoordination of movements, a decline in motor reactions to inhibitory and reinforced light flashes, and appearance of equalizing and paradoxical relations in the number of reactions to these stimuli. Under the influence of ethanol, activating and disinhibitory action of the pain reinforcement on neurones of the visual area temporarily weakens, while the disinhibitory influence of light flashes (CS) is preserved. Judging from the dynamics of phasic reactions to the inhibitory light flashes, the ethanol in a dose of 2-6 g/kg does not influence the inhibitory hyperpolarization processes in the cerebral cortex of rabbits. Tonic inhibition of the cortical unit activity temporarily intensifies after the ethanol injection.     

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.     

Increased regularity of activity of cortical neurons in learning due to disinhibitory effect of reinforcement

This paper reviews the author's studies on neurophysiologic mechanisms of conditioned reflex learning. Electroencephalograms, evoked potentials, activity of neocortical and hippocampal neurons and the rabbits' behavior in the course of elaboration of defensive and inhibitory conditioned reflexes to light flashes have been recorded. Electric shock (ECS) applied to the paw served as reinforcement. The study demonstrated three types of reinforcement effect on the activity of cortical neurons: activating, disinhibitory, and inhibitory. EEG activation due to reinforcement is accompanied by a change in phasic cortical neuronal activity from chaotic or irregular, typical of rest or inhibition, to regular tonic discharges (in neocortex and hippocampus) and group discharges in the stress rhythm, 5-7 Hz in the hippocampus. Following a number of conditioning trials, the effect of reinforcement is simulated by the effect of a conditioned stimulus. With EEG activation and increased regularity in impulses, facilitation of motor reactions is observed.     

Effect of sodium nitrite on the activity of the neocortex neurons during realization of defense and inhibition conditioned reflexes

A decrease in intensity and duration of short-latency reaction components of the sensorimotor and visual cortical neurons to specific stimuli (pain reinforcement and light flashes, respectively) was observed after the administration of NO-generating sodium nitrite (11 mg/kg, subcutaneously). Activation decrease in the visual cortex took place irrespective of biological significance of the light flashes, i.e., in case when this stimulus was a signal of defensive conditioning and in case when these flashes were applied with continuous light (a conditioned inhibitor). Sodium nitrite almost did not change the late activation of sensorimotor and visual neurons in response to pain reinforcement and disinhibitory action of the latter. The results confirm the viewpoint about different neurotransmitters in "specifically modal" and "non-specific" pathways to the neocortex during learning.     

Synchronization dynamics in the neuronal work of the neocortex and hippocampus during learning before and after the administration of nootropics and narcotics

The basal difference in action of the studied drugs was that nootropics (phenybut in a dose of 40 mg/kg and pyracetam in a dose of 200-400 mg/kg) did not change the initial action of pain reinforcement on synchronism in responses of the cortical neurones of alert nonimmobilized rabbits by inhibitory type (coincidence of the presence and absence of impulse activity) towards its decrease, while narcotics of various types (ethanol in a dose of 4-6 mg/kg, morphine-like opiate DAGO and opioid peptide DADLE in doses of 250 mkg/kg) eliminated the action of pain reinforcement on synchronism in responses of the cortical neurones both by inhibitory and activation (time of coincidence only of the presence of impulse activity) types. These and other drugs mainly weakened the initial action of both the inhibitory and reinforced light flashes of synchronism in neurones activity both by inhibitory and activation types. There was no constant parallelism between changes of synchronization and the frequency of the cortical impulses.     

The mechanism of action of a reinforcing stimulus]

Experiments on alert non-immobilized rabbits revealed that electrical cutaneous stimulation of a limb, used as a reinforcing agent in elaboration of a conditioned reflex to photic flashes, weakened slow polyrhythmic oscillations of background EEG and late components of evoked potentials in the visual cortex to photic flashes. Against this background, the connection between slow potentials and spike activity in both the visual and sensorimotor cortical areas considerably diminished. During EEG activation, induced by the reinforcing stimulus, inhibitory pauses and post-inhibitory activation in the firing of the neocortical units weakened and protracted, ordered spike activity appeared. The data obtained are in agreement with the hypothesis that weakening of the recurrent inhibition system is one of the basic mechanisms in the action of the reinforcing stimulus in conditioning.     

Changes in cortical unit activity during selective reinforcement of a chosen interspike interval range

In experiments on immobilized unanesthetized rabbits selective automatic reinforcement of certain ranges of short and long interspike intervals in spontaneous unit activity recorded from single cortical units was given by means of a nociceptive stimulus. Analysis of postinterval histograms showed that the total number of intervals reinforceable by nociceptive stimuli is reduced as a result of the consequent reorganization of the firing pattern. If short intervals are reinforced the mean firing rate is reduced and the probability of appearance of long intervals immediately after the short reinforcements is increased. After reinforcement of long intervals the mean firing rate was increased in one group of cortical neurons, with a corresponding decrease in the total number of long intervals. In the other group of cells a decrease in the number of long intervals was accompanied by a decrease in the mean firing rate of the cells. It is postulated that reorganization of the firing pattern is determined by the level of synchronization of ascending activating influences and by their summation with phases of excitation and inhibition in reciprocally interacting neuron populations.Institute of Experimental Medicine, Academy of Medical Sciences of the USSR, Leningrad. Translated from Neirofiziologiya, Vol. 4, No. 4, pp. 339–348, July–August, 1972.     

The dynamics of the activating and inhibitory types of cortical neuron synchronization during the realization of a defensive reflex and internal inhibition

In the visual and sensorimotor areas of the neocortex and in the hippocampus of alert nonimmobilized rabbits, in response to combinations of light flashes with electrocutaneous limb stimulation an increase was observed of synchronization in the activity of the near-by neurones by activation by inhibitory type (coincidence of the presence and absence of impulse activity). In response to flashes against the light background--conditioned inhibitor--in the visual cortex synchronization of neurones increased by inhibitory type, and in the sensorimotor cortex and hippocampus changes of synchronization appeared, similar to the action of pain reinforcement but considerably weaker. The increase of synchronization by the activation type took place mainly in the neurones pairs with unidirected increase of impulses frequency and by the inhibitory one--with its decrease. Along with this, in a considerable part of neurones pairs both changes of synchronization appeared at the impulses frequency changes of different direction.     

Blockade of a putative GABA-mediated neurotransmission in the cerebellum by benzodiazepine receptor inverse agonists

An exponential relationship was observed between the firing rate of cerebellar Purkinje cells in urethane-anaesthetized rats and the duration of inhibition evoked in these cells by electrical stimulation of the nearby cortical surface. Benzodiazepines, administered i.v., decreased cell firing and increased the duration of the inhibitory response but did not alter the relationship between the two parameters. These effects of one benzodiazepine, RU 32007, were reversed by the benzodiazepine antagonist Ro15-1788 which had little effect alone. The benzodiazepine inverse agonists methyl- or ethyl-beta-carboline-3-carboxylate increased cell firing with the expected reductions in duration of inhibitory response in some cases. However, in 50% of recordings the inhibitory response disappeared, independent of the firing rate. All the effects of the beta-carboline esters were reversed by Ro15-1788 or the benzodiazepine, RU 32007. This action of the benzodiazepine receptor inverse agonists represents an in vivo blockade of an endogenous synaptic inhibition which is thought to be mediated by release of GABA.     

Effect of a derivative of GABA, phenibut, on behavior and the activity of visual cortex neurons of the rabbit during elaboration of a defensive reflex and internal inhibition

In experiments on alert non-immobilized rabbits the effect of subcutaneous administration of the GABA-derivate--phenibut on behaviour, slow potentials and impulse activity of neurones of the visual cortex was studied during elaboration of a defensive reflex to light flashes and of conditioned inhibition. During the action of phenibut late negative-positive components of the evoked potentials to flashes, corresponding inhibitory pauses and postinhibitory activation gradually increased; then stable predominance of slow high-amplitude potential oscillations and corresponding neuronal group bursts appeared, separated by inhibitory pauses and in intersignal periods. Reinforcing stimulus, as before phenibut administration, lowered the amplitudes of slow potential oscillations and weakened inhibitory pauses in neuronal impulse activity. Dynamics of movements in response to the stimuli was of a phasic character. 3 hours after phenibut administration the discrimination of reinforced and inhibitory light flashes has distinctly improved. The obtained results confirm the initial concept of the significant role of the GABA-ergic inhibitory system in the process of elaboration of internal inhibition.     

Effects of noradrenaline on neuronal response induced in the motor cortex by conditioned stimuli

In chronic experiments on cats, the effects were investigated of iontophoretic application of the adrenomimetic ephedrine and the -blocker obsidan (propranolol) on neuronal response induced in the motor cortex by conditioned stimulus presentation during performances of instrumental lever-pressing response. Inhibition of background firing activity and response in most neurons induced by conditioned stimuli was produced by ephedrine, whereas obsidan application enhanced this activity. It was concluded that steady, tonic inhibitory action of the noradrenergic system on background and induced firing activity in cortical neurons takes place during free-ranging behavior. Temporary reinforcement of noradrenergic influences could be an important element in mechanisms of external inhibition during stressful situations, aversive effects, and distractive stimuli.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 22, No. 5, pp. 680–688, September–October, 1990.     

Tonic component of the conditioned reflex process and its functional role

Tonic background activity of 266 neurones in the hippocampus and different neocortical areas was studied in freely moving rabbits in the process of defensive and food instrumental conditioned performance and during switching-over of instrumental and classical food and defensive reflexes. Associations of CS and reinforcement evoke background activity changes in most of recorded cortical neurones preceding the development of other conditioned manifestations. Conditioned reflex was performed only after reaching the background firing rate of almost every examined neurone optimal for its realization. The performance of different conditioned reflexes was associated with different background activity levels of cortical neurones. The above mentioned data form the experimental basis for the identification of the tonic component in conditioned process which reflects tonic character of temporary connection formation and function.     

Electric responses of the cerebral cortex to central excitation and inhibition

An attempt was made to evaluate critically the extent to which the background electrocorticogram, neuronal impulse activity, and evoked potentials reflect the state of cortical excitation and inhibition. It was shown that during electrocorticogram desynchronization, firing neurons predominated in the surface (mainly afferent) layers, while inhibited neurons were in the majority in the lower layers of the cortex. Consequently, desynchronization does not reflect diffuse excitation of the cortex and cannot be taken as an index of central excitation. Slow electrocortical waves cannot be used as indicators of an inhibitory state, even though they may be associated with processes leading to the development of inhibition. Under the effects of different stimuli, the number of neurons participating in impulse condition, and the number of neurons temporarily inhibiting impulse activity in the projection cortical area were stable (ratio 2:1). It was found that the correlation between impulse discharges of neuronal pairs increases during both central excitation and central inhibition. Nonetheless, differences between cortical excitation and inhibition were seen in the reorganization of neuronal columns. The use of evoked potentials to determine cortical excitation or inhibition is complicated by the fact that the amplitude of evoked-potential components reflects the divergent influences of many factors. It was shown that conditional excitation diminished the evoked potential to a light stimulus in the projection cortical area, but caused it to increase in the region of the motor analyzer. The elaboration of a conditional inhibition (extinction) is accompanied by the growth of an evoked potential to a stimulus in the primary cortical area, and by its repression in the region of the motor analyzer. In this case, a large delayed negative wave appears in the evoked potential.This report was presented at the All-Union Symposium on Electric Responses of the Cerebral Cortex to Afferent Stimuli, Kiev, October, 1969.Rostov-on-Don State University. Translated from Neirofiziologiya, Vol. 2, No. 2, pp. 140–154, March–April, 1970.     

The effect of a high-intensity radiation exposure on the brain function of monkeys. The postradiation changes in the EEG response to rhythmic photostimulation]

In experiments with monkeys (Macaca fascicularis) it has been shown that whole-body irradiation with a dose of 45 Gy (6.5 Gy/s) causes considerable changes in the EEG response to rhythmic photostimulation (PS). These changes are: reduction of the desynchronizing effect of PS with regard to a background rhythmicity; decrease in the reception rate of the rhythms of light flashes (RLF); narrowing of the RLF frequency range; and increase in the reaction momentum. The postirradiation changes in the EEG response to PS are considered as a manifestation of inhibition of the cortex functional activity and impairment of sensory information processing in the brain.     

Cortical Network Models of Firing Rates in the Resting and Active States Predict BOLD Responses

Measurements of blood oxygenation level dependent (BOLD) signals have produced some surprising observations. One is that their amplitude is proportional to the entire activity in a region of interest and not just the fluctuations in this activity. Another is that during sleep and anesthesia the average BOLD correlations between regions of interest decline as the activity declines. Mechanistic explanations of these phenomena are described here using a cortical network model consisting of modules with excitatory and inhibitory neurons, taken as regions of cortical interest, each receiving excitatory inputs from outside the network, taken as subcortical driving inputs in addition to extrinsic (intermodular) connections, such as provided by associational fibers. The model shows that the standard deviation of the firing rate is proportional to the mean frequency of the firing when the extrinsic connections are decreased, so that the mean BOLD signal is proportional to both as is observed experimentally. The model also shows that if these extrinsic connections are decreased or the frequency of firing reaching the network from the subcortical driving inputs is decreased, or both decline, there is a decrease in the mean firing rate in the modules accompanied by decreases in the mean BOLD correlations between the modules, consistent with the observed changes during NREM sleep and under anesthesia. Finally, the model explains why a transient increase in the BOLD signal in a cortical area, due to a transient subcortical input, gives rises to responses throughout the cortex as observed, with these responses mediated by the extrinsic (intermodular) connections.     

On the O2 flash yields of two cyanophytes

We explored O₂ flash yield in two cyanophytes, Anacystis nidulans and Agmenellum quadruplicatum. On a rate-measuring electrode, a single flash gave a contour of O₂ evolution with a peak at about 10 ms which was maximum (100) for 680 nm background light. On 625 nm illumination the peak was smaller (62) but was followed by an increased tail of O₂ attributed to enhancement of the background. After a period of darkness, repetitive flashes (5 Hz) gave a highly damped initial oscillation in individual flash yields which finally reached steady state at 94% of the yield for 680 nm illumination. When O₂ of repetitive flashes was measured as an integrated flash yield the results was distinctive and similar to that for a continuous light 1 (680 nm). An apparent inhibition of respiration which persisted into the following dark period was taken as evidence for the Kok effect. With a concentration-measuring electrode, integrated flash yield vs. flash rate showed the same nonlinear behavior as O₂ rate vs. intensity of light 1. We draw three conclusions about the two cyanophytes. (a) The plastoquinone pool is substantially reduced in darkness. (b) Because of a high ratio of reaction centers, reaction center 1 / reaction center 2, for the two photoreactions, saturating flashes behave as light 1. (c) Because repetitive flashes are light 1, they also give a Kok effect which must be guarded against in measurements designed to count reaction centers.     

Spontaneous spiking and synaptic depression underlie noradrenergic control of feed-forward inhibition

Inhibitory interneurons across diverse brain regions commonly exhibit spontaneous spiking activity, even in the absence of external stimuli. It is not well understood how stimulus-evoked inhibition can be distinguished from background inhibition arising from spontaneous firing. We found that noradrenaline simultaneously reduced spontaneous inhibitory inputs and enhanced evoked inhibitory currents recorded from principal neurons of the mouse dorsal cochlear nucleus (DCN). Together, these effects produced a large increase in signal-to-noise ratio for stimulus-evoked inhibition. Surprisingly, the opposing effects on background and evoked currents could both be attributed to noradrenergic silencing of spontaneous spiking in glycinergic interneurons. During spontaneous firing, glycine release was decreased due to strong short-term depression. Elimination of background spiking relieved inhibitory synapses from depression and thereby enhanced stimulus-evoked inhibition. Our findings illustrate a simple yet powerful neuromodulatory mechanism to shift the balance between background and stimulus-evoked signals.