[Application of the method of one-day learning in a Morris water maze to analyse the effects of sleep deprivation on memory trace recall 24 hours later, after learning].

The proposed model of a one-day spatial learning is of interest in research of how sleep influences the hippocamp-dependent memory consolidation. We have studied the influence of a one-day total sleep deprivation on spatial memory consolidation in hooded rats after a one-day learning in the Morris water maze according to Feldman et al. [2010] protocol. According to it rats had to find a submerged platform that was alternatively marked by a flag or completely invisible to an animal. In a previous study [Dorokhov et al., 2011] we have used another one-day learning protocol [Frick et al., 2000] and Wistar rats and have demonstrated a large interindividual variance in learning parameters and sleep deprivation effects on memory consolidation. In this study we confirm previously acquired results on negative impact of sleep deprivation on spatial memory consolidation. To demonstrate the effects of sleep deprivation on the results of one-day learning we are using for the first time an evaluation of the time spent by an animal in the area of the platform placement and corresponding areas in the other quadrants of the water maze.

[Sleep deprivation effect upon spatial memory consolidation in rats after one-day learning in a Morris water maze].

The effect of sleep deprivation by 'carousel' method on spatial memory consolidation in a Morris water maze was studied in Wistar male rats after one-day learning (in accordance to a protocol by Frick et al., 2000). It was found that after fast 3-hr learning the memory trace retains during 24-hr. Twenty four hour sleep deprivation followed learning impaired consolidation of spatial memory. So the rat model of a one-day learning is suitable for the studying of neurophysiological mechanisms of sleep deprivation effects on spatial memory consolidation.

Spatial organization of biopotentials and the originality of visual images.

The characteristics of the spatial organization of biopotentials in the neocortex during the mental creation of original and standard mental images were studied. Intra-and interhemisphere coherence associations at different EEG frequency ranges were assessed, along with linkages between relative changes in measures of linear (correlation coefficient) and non-linear (multiple entropy) processes between different areas of the neocortex. Creation of original thoughts was found to be associated with a significantly smaller number of associations with decreased coherence in the high-frequency alpha range between distant points than on formation of standard images. On formation of original images, the number of concordantly functioning pairs of cortical areas and the mean level of synchronization between them were greater in terms of linear processes than on formation of standard images, while in terms of non-linear processes, the number was, conversely, smaller. The correlational relationships between changes in different cortical areas for both types of process were only positive on creation of original images, while creation of standard images yielded both positive and negative correlations. These data lead to the conclusion that the spatial organization of biopotentials during the mental creation of original and standard images differs in terms of the cortical distribution of concordant changes in linear and non-linear processes, their levels of linkage, and the nature of interhemisphere interactions. Data on differential interhemisphere interactions in the diagonal and central bilateral profiles suggest the radial representation of visual imagination.

The effects of the experience of forming visual images on the spatial organization of the EEG.

The spatial organization of biopotentials in the cerebral cortex of 23 subjects who were students at the Faculty of Graphic Arts ("professionals") as well as 39 subjects lacking systematic experience of visual images ("non-professionals") was compared with the aim of identifying EEG correlates of the experience of visual images (image formation) in humans. Changes in measures of the spatial organization of biopotentials (spatial synchronization, spatial disordering, coherence, and spectral power) were analyzed as subjects mentally composed visual images consisting of two simple graphic elements - right angles and oblique lines. The total number of image elements increased in each of four sequential tasks, from a number which could be analyzed at the conscious level (4-7 elements) to a number exceeding analysis at the conscious level (8-16). Intergroup differences, particularly increases in the spatial disordering of biopotentials (non-linear processes), were detected when large numbers of elements were used (tasks 3 and 4). This measure increased more markedly in professionals than in non-professionals. Changes were significant in the anterior areas of the right hemisphere. Spatial synchronization of biopotentials (linear processes) increased in non-professionals in the posterior areas of the right hemisphere. Coherence and spectral power increased in professionals in a larger number of narrow-band EEG frequency subranges than in non-professionals. These data show that experience of visual imagery results in a more complex neurodynamic process during the activity, with non-linear dynamics and a multitude of EEG resonance systems at different frequencies.

[Spatial organization of biopotentials and original features of visual images].

Features of spatial organization of neocortical potentials during mental creating of the original and standard visual images were studied. Intrahemispheric and interhemispheric coherence in different EEG frequency bands and temporal relations between relative changes in the index of linear (correlation coefficient) and non-linear (multiple entropy) processes in different neocortical areas were analysed. Number of decreased coherence values in the high-frequency alpha subband between remote neocortical points during creating of an original image was significantly lower than during creating of a standard image. During creating of the original image, the number of synchronously functioning pairs of neocortical areas and the mean level of linear correlation between the areas were higher, and correlation by the non-linear index, on the contrary, was lower than during creation of the standard image. The correlation between changes in different neocortical areas for both processes during creating of the original image was only positive, and that during creating of the standard image was both positive and negative. The conclusion was made that creative and reproductive types of visual imagination were different in the spatial distribution of coordinated changes in the linear and non-linear processes, mean magnitudes of these changes, and the character of hemispheric interaction. The data on different interhemispheric relations in diagonal and central bilateral directions raise a question about the radial representation of visual imagination.

Emotionality and the temporospatial organization of instantaneous EEG potentials.

The characteristics of the temporospatial organization of cerebral cortical potentials at different levels of genetically determined emotionality were analyzed by constructing topograms of instantaneous EEG levels in the inbred rat strains MR and MNRA. Two parameters were calculated for each topogram: the total level and the similarity coefficient. Power spectra were calculated for the values and these were found to change in an oscillatory manner. Interstrain differences were found in the correlated changes in total levels and similarity coefficients, in the durations of changes in the total level, which were more marked than those of similarity coefficients, and the nature of interhemisphere asymmetry. In MR rats, the power spectra of both measures showed significant peaks with modes at 2.0, 6.5, and 9.0 Hz. In MNRA rats, peaks in the spectra of these measures both coincided (2.0 Hz) and differed (7.0 Hz in the spectrum of the total level and 3.0, 4.5, and 6.0 Hz in the spectrum of the similarity coefficient). These data suggest different types of functioning of the reticulothalamocortical and hippocampocortical systems in rats of these strains.

[EEG correlates of the change in information processing strategy in visual imagery].

Cnanger of the spatial organization of biopotentials (spatial synchronization and disorder, spectral power and coherence) were analyzed during mental creating of visual images from two simple elements: the angle the oblique line. With the transition from the first to the fourth task, the total number of used elements increased from the number suitable for simultaneous presentation and conscious processing (less than 7 +/- 2) to a much higher number. Changes in the characteristics of the spatial organization of biopotentials associated with the increase in the number of the elements can be explained by a change in the information processing strategy, transformation of information processing strategy, i.e. the transition from the left-hemispheric successive (conscious) analyses to the right-hemispheric simultaneous (unconscious) processing. It was shown that this change in the information processing strategy was accompanied by an increase in the index of spatial disorder sensitive to complicated nonlinear processes. Subjects were divided in two groups with different forms of the reorganization of interhemispheric and fronto-occipital relationships of biopotentials. These data are interpreted in terms of different involvement of the unconscious intellectual processes of different layers (subconsciousness and superconsciousness) in the change in information processing strategy.

[Emotionality and spatio-temporal organization of momentary EEG potentials].

With the aim to reveal features of the neocortical spatiotemporal organization of potentials characteristic of different genetically predetermined emotional levels, momentary values of EEG potentials were analyzed in inbred rats of MR and MNRA strains. A topogram was described by a basic parameter such as its general level (the mean of momentary values of potentials derived from 24 symmetrical electrodes bilaterally implanted into the brain cortex) and a similarity coefficient (correlation between the set of its momentary values and that of a standard topogram). The general level and similarity coefficient values were calculated for a series of successive topograms individually for the right and left hemisphere. Also, right- and left-side power spectra of these series were calculated. In rats of MR strain, significant (p < 0.05) peaks in the general level and similarity coefficient spectra were observed in the delta (2.0 Hz), teta (6.5 Hz) and alpha (9 Hz) frequency bands. In this strain, the general level power was higher at the right side, and the similarity coefficient power displayed the left-side dominance. In rats of MNRA strain, peaks in the delta(2.0 Hz) band coinsided in the general level and similarity coefficient spectra, whereas, independently, the general level spectra had peaks in the theta band (7.0 Hz), and similarity coefficient had peaks at frequencies 3.0, 4.5, and 6.0 Hz. The left-side general level spectral power was higher than the right-side general level spectral power in the delta and lower in the high-frequency theta bands. The similarity coefficient power displayed the left-side dominance for the peaks in the delta (2.0 Hz) and theta (3.0 Hz) bands, and it displayed the right-side dominance for the peaks in the theta (4.5 Hz) band. The specific features of the cortical spatiotemporal organization of potentials revealed in rats of MR and MNRA strains suggest different modes of functioning of at least two systems, reticulo-thalamo-corticaland hippocampo-cortical.

[The influence of visual imagery experience on EEG spatial organization].

The comparison of EEG spatial organization between groups of 23 students of graphic arts department ("professional" subjects) and 39 subjects of another specialization ("non-professional" subjects) was made in order to find EEG correlates of visual imagery experience. Changes in the spatial organization of biopotentials (spatial synchronization and spatial disorder, spectral power and coherence) were analyzed while subjects mentally composed visual images from two simple elements, right angle and oblique line. The total number of elements presented for the image composition increased with each subsequent task (in total, four tasks were presented) from the number adequate to simultaneous perception and conscious processing (less than 7 +/- 2) to a much higher number. Intergroup differences, especially, in the degree of the spatial disorder (non-linear processes), were most evident under conditions when the subjects operated with a greater number of elements (tasks 3 and 4). This parameter increased more rapidly in "professionals" than in "non-professionals". These changes were most pronounced in the right anterior cortex. In "non-professional" subjects, spatial synchronization (linear processes) increased in the right posterior area. In "professional" subjects, coherence and spectral power increased in a greater number of narrow EEG frequency subbands than in "non-professional" subjects. The findings suggest that the imagery performance in subjects with visual imagery experience involves complicated neurodynamic processes such as non-linear dynamics and numerous EEG spatial resonance systems.

[Effect of novel anxiolytic agent aphobazole on coherence of the brain biopotentials in MR and MNRA rats]. / Vliianie novogo anksiolitika afobazola na kogerentnost' biopotentsialov kory golovnogo mozga krys linii MR i NMRA.

Effect of the anxiolytic drugs afobazole, diazepam, and chlordiazepoxide on the cortical biopotential coherency was studied in MR and MNRA rats with increased and decreased level of emotionality, respectively. Afobazole increased a difference in the biopotential coherency between rats of the two lines in the range of EEG theta, alpha, and beta rhythms. In the subrange of dominating theta activity (6.00-7.25 Hz), this effect took place at the expense of reduced coherency in MNRA rats in the absence of changes in the MR line. Afobazole decreased the biopotential coherency in the alpha activity band (7.5-8.25 Hz) in the rats of both lines. This is indicative of the presence of a CNS-stimulating component in the pharmacological activity spectrum of afobazole. The expediency of using afobazole in patients with different levels of anxiety is discussed.

[Effect of a novel antimigraine preparation tropoxin on EEG of MR and MNRA rats]. / Vliianie novogo protivomigrenevogo preparata tropoksina na EEG krys linii MR i MNRA.

Effect of the new antimigraine drug tropoxin on the EEG profile was studied in MR and MNRA rats with genetically determined high and low levels of emotionality, respectively. In MR rats, tropoxin decreased the number of the bioelectric activity parameters changed by the stressor action (0.9% NaCl, i.p.). The drug reduced the spectral power in the EEG delta band, and increased that in the theta, beta-1, and beta-2 bands. This was evidence of the central stimulating action and the possible enhancement of the exploratory activity. In MNRA rats no changes in bioelectric activity were observed in the low-frequency delta and theta bands, while the spectral power in the beta-1, and beta-2 bands showed a decrease. It was concluded that a neural component is present in the mechanism of the tropoxin action, which may play an important part in the therapeutic effect of the new drug.

[Features of the stress reaction in rats with genetically-determined emotionality (from EEG indicators)]. / Osobennosti stress-reaktsii u krys s geneticheski determinirovannoi émotsional'nost'iu (po pokazateliam EEG).

The features of the EEG spatial organization in two rat strains, i.e., with expressed emotional reactions (Maudsley reactive, MR) and less reactive (Maudsley nonreactive, MNR) were compared in two stress situations: during exposure to the action of pain (P) (i.p. injection of 0.9% NaCl solution) and during 24-hour water deprivation (D). Multichannel EEG recording (24 derivations) and their multiparametric estimation (840 signs) made it possible to differentiate characteristic features of the EEG spatial organization in rats with initially increased emotional reactions and passive behavioral strategy during exposure to stress. In both stress-inducing conditions, an increase in crosscorrelation and coherence between cortical potentials in parallel with rise of the spectral power in the range of high-frequency theta and its drop in the range of EEG high-frequency band was observed in the MR rats. The MNR rats showed the opposite changes. Different reactivity of the ratio between the coherence and spectral power of potentials was observed in two strains of rats. This index characterizes the level of the information-energy component of the spatial organization of cortical potentials. It is suggested that different character of the EEG changes reflects the features of interhemispheric relations, information-energy processes, and cortical regulation of autonomic processes in the system of adaptive stress reactions at different levels of emotionality and behavioral strategy.

[Spatial organization of EEG in rats with genetically determined emotionality]. / Prostranstvennaia organizatsiia EEG pri geneticheski determinirovannoi émotsional'nosti u krys.

In order to study the possibility of EEG discrimination of genetically determined emotionality (increased propensity to emotional and stress reactions and anxiety) brain electrical activity was recorded in rats of two strains: Maudsley Reactive and Maudsley Nonreactive (24 derivations from the convexital skull surface were used). The program package "Synchro-EEG" was used for EEG processing. It was demonstrated that the two rat strains were significantly different in 120 EEG parameters of 840 ones analyzed. On the basis of 37 parameters, each rat was correctly recognized as belonging to the respective group with the error of 4.89%. The analysis of the detected signs allowed their classification to be performed in accordance with the peculiarities of the emotional and cognitive processes and the level of nonspecific activation. Specific forms of interaction between these components in the system of emotional reactions were revealed.

[EEG study of the anxiolytic effect of scopolamine]. / EEG-issledovanie anksioliticheskogo éffekta skopolamina.

Effect of the central M-cholinolytic scopolamine on spatial organization of the rat brain electrical activity was studied under conditions of high and low emotional-stress responses. The EEG changes were estimated by 840 parameters. A possibility of the EEG discrimination by means of interstrain differences in responses to scopolamine, was shown. A more obvious decrease in spectral power and potentials coherence was revealed in Maudsley Reactive rats (MR) as compared with the Maudsley Nonreactive rats (MNRA), in parieto-temporal and occipital areas of the right hemisphere, and the reverse interrelationship occurred in the anterior parts of the right and posterior parts of the left hemisphere. These findings suggest some specifics in the spatial distribution of the maximum scopolamine action foci depending on the initial emotional level. Changes occurring under the scopolamine effect in different EEG frequency bands are different in the MR and the MNRA rats. The findings are discussed in respect to the EEG indices of anxiolytic component of cholinergic regulation of the brain activity.

[The dynamics of neocortical modifications: the dependence on motivational and emotiogenic systems]. / Dinamika neokortikal'nykh modifikatsii: zavisimost' ot motivatsio- i émotsiogennykh sistem.

A concept is advanced according to which for complete and successive development of membrane and synaptic modifications in the neocortex during the conditioned reflex (CR) elaboration the differentiated changes in impulse flow structure of the motivation and emotion systems of the hypothalamus and reciprocal character of excitatory and inhibitory interactions between them are necessary. Motivation excitation coordinated with repeated activation of synaptic inputs by pairing stimuli contributes to temporary (lasting about hour) increase in somatodendritic electroexcitability of neocortical neurons. It is necessary for maintaining cells in the state of readiness for summation of polymodal excitations during the CR generalization stage. Emotion excitation contributes to long-lasting (about twenty-four hours) increase in synaptic efficacy of excitatory and inhibitory connections which determine a conditioned act during the stage of specialization. Hetero- and homosynaptic facilitation of synaptic transmission lead to global and local character of spatial synchronization of slow activity during these stages. These processes are mainly determined cooperative interaction glutamatergic system with modulator cholin- and monoaminergic (noradren- and serotonin-) systems activating during motivational and emotional behavior components, respectively.

[The effect of scopolamine on the spatial organization of rat cortical potentials]. / Vliianie skopolamina na prostranstvennuiu organizatsiiu potenstialov kory golovnogo mozga krys.

The influence of scopolamine (1 mg/kg, i.p.) on the spatial organization of the neocortical electrical activity was studied in rats. A decrease in the spectral power and coherence of brain potentials in the range of the dominant theta-rhythm peak (6.00-7.25 Hz) and their increase in the adjacent low-frequency band were observed. Both indices were decreased in the wide beta band (19.00-30.00 Hz). The described changes took place over the whole areas of the right hemisphere and parieto-temporal region of the left hemisphere. The obtained results are discussed with respect to the role of the cholinergic brain system in the higher nervous activity.

[Changes in the direct and interhemispheric responses of the pyramidal tract after tetanization of the cortex and lateral hypothalamus]. / Izmenenie priamykh i mezhpolusharnykh otvetov piramidnogo trakta posle tetanizatsii kory i lateral'nogo gipotalamusa.

Changes in pyramidal tract response after unilateral neocortical and lateral hypothalamic tetanization were analyzed in unanesthetized and nonimmobilized rabbits. Membrane and synaptic modifications were revealed in intra- and interhemispheric connections. Changes in excitability of callosal collaterals of pyramidal tract neurons in contralateral hemisphere and changes in somatodendritic excitability in ipsilateral hemisphere could be oppositely directed. Plasticity of callosal connections may contribute to the interhemispheric asymmetry during learning.