Interhemispheric asymmetry of neocortex and hippocampus in orienting exploratory behavior of rabbits

Correlation of discharges of cortical neurons in symmetrical points of the visual and parietal cortices and left and right hippocampal CA1 neurons was studied in freely moving rabbits during exposure to emotional stimuli. Crosscorrelation histograms were plotted. As compared to the initial state, during an active orienting exploratory reaction to stimuli, the left-side influence on right-hemispheric cortical neurons with a delay about 100 ms increased, which led to asymmetry in interhemispheric interaction with the left-side dominance. During freezing, the left-side influence became weaker, and the effects of the right hemisphere prevailed. Hippocampal asymmetry in neuronal activity was in reciprocal relationship with neocortical asymmetry. In the hippocampus, the right-side influence with a delay about 200 ms increased during the active exploratory reactions resulting in the right-side dominance. Freezing was accompanied by strengthening of the left-side influence (the left-side dominance). During the active locomotion, neuronal interaction in the hippocampus was predominantly realized in the theta-range frequency, whereas freezing was characterized by the delta-range correlation. It was concluded that the active or passive nature of a behavioral reaction to emotional stimuli was correlated with changes in asymmetry in the interhemispheric neuronal interactions at the cortical and hippocampal levels.     

Effect of electrical stimulation of the hippocampus and neocortex on cingulate cortical neurons in rabbits

Extracellular unit activity of the anterior and posterior zones of the cingulate cortex and also of the anterior and posterior cortical association areas was analyzed in unanesthetized rabbits. In the posterior zone considerably more cells (60%) responded to hippocampal stimulation than in the anterior zone (18%). In 43% of these cells in the posterior zone but only in 5% in the anterior zone, the responses followed the frequency of stimulation. Unit responses in the posterior zone could be divided into two discrete groups: those with short (12.3 ± 6.5 msec) and those with long (50.2 ± 10.0 msec) latent periods. Inhibitory phenomena also were well marked during hippocampal stimulation. More than one-third of cells of the cingulate cortex responded to stimulation of the posterior association zones by spikes which followed the stimulus, and by subsequent inhibition. Responses of this kind to stimulation of the anterior association zones were found in only a few cells in the anterior zone of the cingulate cortex. The results are discussed in the light of data from morphological investigations relating to connections between these structures.Institute of Biological Physics, Academy of Sciences of the USSR, Pushchino-on-Oka. Translated from Neirofiziologiya, Vol. 14, No. 3, pp. 270–277, May–June, 1982.     

An investigation of phase relations between theta-rhythm potentials in the neocortex and hippocampus of rabbits

Phase relations between rhythmic activity recorded from the hippocampus and from various levels of the neocortex were calculated on a two-dimensional model on the assumption of the passive spread of hippocampal activity. The calculation showed that if such a spread of activity takes place an appreciable phase shift, caused by the spatio-temporal structure of the hippocampal source of the theta-rhythm, may exist between the rhythmic components of potentials recorded from the neocortex and hippocampus. In some series of electrophysiological experiments on rabbits various consequences of the model calculations were tested. Phase relations of the theta-rhythm recorded in the neocortex and in the hippocampus in the presence of maximal correlation between cortical potentials cannot be explained, in the overwhelming majority of cases, purely by the passive spread of hippocampal activity to the surface of the neocortex.     

Cholinergic facilitation of trace eyeblink conditioning in aging rabbits

The hippocampus is importantly involved in learning and memory, and is severely impacted by aging. In in vitro hippocampal slices, both the post-burst afterhyperpolarization (AHP) and spike-frequency accommodation are reduced in hippocampal pyramidal neurons after hippocampally-dependent trace eyeblink conditioning, indications of increased cellular excitability. The AHP results from the activation of outward potassium currents, including sI(AHP) and muscarine-sensitive I(M). The AHP is significantly increased in aging hippocampal neurons, potentially contributing to age-associated learning deficits. Compounds which reduce the AHP and spike-frequency accommodation could facilitate learning in normal aging or in age-associated dementias such as Alzheimer's disease. The cholinesterase inhibitor metrifonate enhances trace eyeblink conditioning by aging rabbits and reduces the AHP and accommodation in hippocampal CA1 neurons in a dose-dependent manner. These reductions are mediated by muscarinic cholinergic transmission as they are blocked by atropine. Hippocampal neurons from metrifonate treated but behaviorally naive rabbits were more excitable and not desensitized to the effects of metrifonate since the AHP and accommodation were further reduced when metrifonate was bath applied to the neurons. These observations suggest that the facilitating effect of chronic metrifonate on acquisition of hippocampally dependent tasks is mediated at least partially by increasing the baseline excitability of CA1 pyramidal neurons. The issue of whether learning can be facilitated with muscarinic cholinergic agonists, in addition to cholinesterase inhibitors, was addressed by training aging rabbits during intravenous treatment with the M1 agonist CI1017. A dose-dependent enhancement of acquisition was observed, with rabbits receiving 1.0 or 5.0 mg/ml CI1017 showing comparably improved learning rates as those receiving 0.5 mg/ml or vehicle. Sympathetic side effects, mainly excess salivation, were seen with the 5.0 mg/ml dose. Post-training evaluations suggested that the effective doses of CI1017 were enhancing responsivity to the tone conditioned stimulus. These studies suggest that muscarinic cholinergic neurotransmission is importantly involved in associative learning; that learning in aging animals may be facilitated by enhancing cholinergic transmission; and that the facilitation may be mediated through actions on hippocampal neurons.     

Temporal structure of the spike trains of neuronal pairs in the neocortex during calm wakefulness in rabbits

For revealing the conjugation of impulse activity of simultaneously recorded neurones in the visual and sensorimotor areas of rabbits neocortex, histograms were built of cross- and autocorrelation (CCH and ACH) of their discharges sequences. From successions of discharges of the visual cortex neurones, forming pairs of cells acting in correlation, spikes were singled out conjugated with neuronal discharges in the sensorimotor area, and their ACHs were built. In 77% of cases a resemblance was observed of temporal structure of conjugated discharges and real spike sequences, in 23%--there was no such resemblance. Analysis of conjugated discharges ACHs showed that they appeared predominantly periodically (87% of cases). The number of fragments with periodic discharges frequency within delta-frequency range from 3 to 4 Hz prevailed.     

Fibrinolytical processes in rabbits activated by the magnetic field

Rabbits were exposed to a constant magnetic field of 0.005 T, 0.1 T and 0.3 T induction for one hour per day each day for a period of four weeks. It was found that the magnetic field increases the rate of fibrinolytical processes. A decrease in fibrinogen concentration, an increase in the level of fibrinogen degradation products and a considerably shorter time of fibrinolysis in plasma were all noted. The magnitude of these processes was proportional to duration of exposure to the magnetic field in action. These date confirms the similar effect observed in other mammalians (guinea pigs, rats). Thus, the application of a static magnetic field of intensity as low as 0.005 T to increase a fibrinolytical processes in the thrombotic therapy seems to be justified.     

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.     

Demonstration of Cajal-Retzius cells and their processes in the neocortex of newborn mice using horseradish peroxidase

In newborn mouse neocortex, the so-called Cajal-Retzius cells (CRc), which are usually considered as neurons due to their polarity, located exclusively in the first cortical layer, were visualized using local application of horseradish peroxidase (HRP) on the neocortex followed by its tangential sectioning. Close to the application site, the exogenous enzyme, taken up by some of the CRc, was revealed with 3,3' diaminobenzidin (DAB) according to the Graham and Karnovsky technique. The brown reaction product was seen to fill almost completely some of these cells giving a "Golgi like" picture. They had a fusiform bipolar pericaryon and processes extending only into the first cortical layer. A single thick process whose length reached 300 to 400 microns, almost rectilinear and tapering progressively at its end was a dendrite which bore thin expansions reaching the cortical surface where they sometimes ramified between the endfeet of the radial glia. The dendrite sometimes showed symmetrical synapses with an afferent axon of unknown origin. The CRc axon was very thin (0.5 microns in diameter) and gave off at random numerous collaterals whose number and trajectories varied greatly from one cell to the other. The axonal processes could often be followed over a millimeter. They ended either abruptly because HRP had not diffused far enough into the process or terminated with large growth cones bearing numerous digitiform filopodia. The presence of growth cones thus suggested that the processes were exploring the cellular environment of the first cortical layer. In the newborn, CRcs appeared as still immature neurons.     

Systems organization of cerebral processes in the cat during learning while undergoing electrical stimulation of the neocortex

A delayed spatial choice (DSC) was elaborated in five cats during electrical stimulation (ES) of the frontal cortical parts with a frequency of 80 imp/s. Then the task fulfillment was tested following cessation of the electrostimulation or under the action of other current frequencies (35,3 and 120 imp/s). The number of erroneous choices increased in the absence of ES or during 3 imp/s ES of the frontal parts. The effects of frequencies of 35,80 and 120 imp/s did not differ. Three cats were trained to DSC without ES. The conditioned reflexes were tested during ES of the frontal cortical parts with current frequency of 3 and 80 imp/s. Statistically significant increase of the number of erroneous responses took place in both situations. The obtained data are discussed from the point of view of the integrative activity of the cerebral structures in DSC. Its disturbance during ES of the cortical zones and dissociation (discordance) after cancellation of stimulation during which the conditioned reflex had been elaborated, point to systemic organization of brain functioning in goal-directed forms of behaviour.