The phenomenon of the functional dissolution of the wakefulness-sleep cycle in white rats under the influence of immobilization]

Studies have been made on functional dissolution of the sleep cycle in albino rats due to immobilization of various duration. It was shown that 1-day immobilization increases microactivational representation in the EEG, facilitates rhythmic movements of the lower jaw, affects relative duration of the diurnal and nocturnal sleep, increases sleep fragmentation, and in some of the animals decreases the EEG amplitude. It is suggested that strong stress results in the return of sleep mechanisms to a more ancient level.     

Participation of agouti-related peptide in the regulation of the wakefulness-sleep cycle

Agouti-related peptide is expressed in the hypothalamic neurons in humans and animals. Immunohistochemical studies in Wistar rats shows significant changes in the optical density of agouti-related peptide in the neurons of the arcuate hypothalamic nucleus, as well as in their processes in the hypothalamus and nucleus accumbens after 6 h of sleep deprivation (an increase) and after 2 h of post-deprivative sleep (a decrease). Comparison of these findings with the earlier results shows the opposite trends in the changes in the optical density of agouti-related peptide and the speed of the limiting enzyme of dopamine synthesis, tyrosine hydroxylase, in the hypothalamus and in the striatonigral system. An increase in the agouti-related peptide level was accompanied by a decrease in tyrosine hydroxylase, while a decrease in agouti-related peptide, on the contrary, was accompanied by an increase in the tyrosine hydroxylase activity. Our data show the role played by agouti-related peptide as a modulator of the functional activity of the dopaminergic brain neurons. The interrelation between various functions of the body, such as food behavior, sleep, and stress, is considered to be mediated by the participation of the same neurotransmitter systems in their regulation.     

Dissolution of the wakefulness-sleep cycle in patients with catatonic form of schizophrenia

Polysomnograms of two patients with catatonic form of schizophrenia of different duration of the disease were recorded and analyzed. Pronounced disturbances of the wakefulness-sleep cycle (WSC) were revealed. Apart from differences connected with duration of the disease and treatment with corresponding medications, there were detected the general features indicating dissolution of the central nervous system and the very wakefulness-sleep cycle. A certain similarity of the found WSC disturbances with the earlier shown WSC disturbances in rats with predisposition to catalepsy was noted. The conclusion is made about domination of diencephalic influences over the telencephalic one in the studied patients.     

Effect of photostimulation on the wakefulness-sleep cycle in the common frog Rana temporaria

Effect of daily 30-min photostimulation in the 10 s light: 10 s pause regime (the total of 5 days) on the time structure of the wakefulness-protosleep cycle (WPC) was studied in the common frog Rana temporaria. Changes of EEG wave components were analyzed in three immobility forms of the types of catalepsy (P-1), catatonia (P-2), and cataplexy (P-3) that form protosleep. The first three photostimulations promoted a gradual increase of the P-1 state to 84.16 ± 11.6% (the initial value (IV) 22.9 ± 9.1%) and a decrease of representation of wakefulness to 4.86 ± 2.1% (IV 13.8 ± 7.8 %), of P-2 to 11.1 ± 5.3 (IV 53.3 ± 13.3 %), and of P-3 to 2.21 ± 1.0% (IV 11.1 ± 5.6%). After 4–5 photostimulations and especially after their complete cessation the percentage of P1 in the WPC was restored to initial values, whereas the percentage of the frog WPC P-3 considered to be a precursor of the homoiothermal sleep rose to 20 ± 8.3% after 5 photostimulations and to 38.5 ± 6.7% the next day. Changes in the frog EEG spectra appeared only after one photostimulation and were characterized by a brief increase of power of α-like waves and by inhibition of slow δ-waves. In P-2 the power of the slow δ-waves gradually rose. In P-3 the EEG parameters did not change. In all experimental animals a decrease of the relative thymus and adrenal masses was revealed, which indicates the stress nature of the photostimulation regime used in the work. The obtained data allow thinking that a certain neurohormonal response to stress has already been formed at the amphibian level and that an important role in this response realization is played by a coordinated interaction of the hypothalamic sleep-regulating system providing protosleep manifestations and of the hypothalamic neurosecretory system triggering hormonal cascade of the stress-reaction.     

Participation of vertebrate forebrain activating systems in organization of the wakefulness-sleep cycle

The article considers mechanisms of diencephalic-telencephalic interactions in regulation of the wakefulness-sleep cycle in various classes of vertebrates. In such interactions a special role is played by the dopaminergic systems that perform neurosecretory function at the level of diencephalon and neurotransmitter function at the level of telencephalon. Concepts of A.I. Karamyan and A.L. Polenov about the stage pattern of development of CNS and neurosecretory systems are presented, as well as the interconnection of dopaminergic and glutamatergic neurotransmitter systems in the mammalian neostriatum in the wakefulness-sleep cycle is considered. Comparison of dynamics of expression of the dopamine metabotropic receptors and of the glutamate ionotropic receptors in neostriatum showed unidirectional changes of D₁ and AMPA on the background of the 6-h sleep deprivation as well as of D₂ and NMDA on the background of postdeprivative sleep. The corticofugal direction of glutamate impulsation and its relatively fast actions allow admitting its triggering action on generation of the sleep-inducing processes in the underlying brain parts.     

Effect of photostimulation on the wakefulness-sleep cycle in the common frog Rana temporaria

Effect of daily 30-min photostimulation in the 10 s light: 10 s pause (the total of 5 days) on the time structure of the wakefulness--protosleep cycle (WPC) was studied in the common frog Rana temporaria. Changes were analyzed of EEG wave components in three immobility forms of the type of catalepsy (P-1), catatonia (P-2), and cataplexy (P-3) that form protosleep. The first three photostimulations promoted a gradual increase of the P-1 state to 84.16 +/- 11.6% [the initial value (IV) 22.9 +/- 9.1%] and a decrease of representation of wakefulness to 4.86 +/- 2/1% (IV 13.8 +/- 7.8%), of P-2 to 11.1 +/- 5.3 (IV 53.3 +/- 13.3%), and of P-3 to 2.21 +/- 1.0% (IV 11.1 +/- 5.6%). After 4-5 photostimulations and especially after their complete cessation the percentage of P-1 in the WPC was restored to initial values, whereas the percentage of the frog WPC P-3 considered to be a precursor of the homoiothermal sleep rose to 20 +/- 8.3% after 5 photostimulations and to 38.5 +/- 6.7% the next day. Changes in the frog EEG spectra appeared only after one photostimulation and were characterized by a brief increase of power of alpha-like waves and by inhibition of slow 6-waves. In P-2 the power of the slow delta-waves gradually rose. In P-3 the EEG parameters did not change. In all experimental animals a decrease of the relative thymus and adrenal masses was revealed, which indicates the photostimulation regime used in the work induces stress. The obtained data allow thinking that a certain neurohormonal response to stress has already been formed at the amphibian level and that an important role in this response realization is played by a coordinated interaction of the hypothalamic sleep-regulating system providing protosleep manifestations and of the hypothalamic neurosecretory system triggering the stress-reaction hormonal cascade.     

The wakefulness-sleep cycle in rats with a genetic predisposition to catalepsy

Neurophysiological studies on wakefulness-sleep cycle have been made in rats selected for hereditary inclination to catalepsy. It was shown that in these animals, the stage of delta-sleep is significantly reduced, whereas the duration of a superficial slow-wave sleep is increased. In a sleeping phase of the cycle, large amount of spindles in the range of alpha- and beta 1-oscillations was observed, especially significant in electrograms of n. caudatum and sensorimotor cortex. This activity is considered as a pathological manifestation of a transient hypnotic phase which includes the increase in immobilization of a cataleptic type.     

Electroencephalographic analysis of manifestations of latent forms of paroxysmal syndrome in the wakefulness-sleep cycle in rats

An electroencephalographic study of the brain activity in the wakefulness-sleep cycle was carried out on rats of Krushinskii-Molodkina line (KM) with hereditary predisposition to audiogenic convulsions and on Wistar rats that were insensitive to the convulsiogenic sound effect, but with epileptiform manifestations appearing on the background of cadmium intoxication and administration of kainic acid into the caudate nucleus head. There were revealed several EEG patterns whose presence was an indicator of formation of disorders of the CNS activity of the paroxysmal character in the animals. It has been established that in the phase of the rat rapid-wave sleep, a high representation of episodes with predominance of a-diapason EEG oscillations can be considered a specific non-paroxysmal abnormality due to the presence of convulsive syndrome in these animals. It was shown the long steady decrease of sensitivity of KM rats to the convulsiogenic sound effect, which appeared after multiple audiogenic generalized tonicoclonic convulsive attacks, correlated with a decrease of the degree of theta-diapason oscillations and with an increase of representation of alpha-diapason waves on EEG in the state of the animal quiet consciousness. A role of disintegration in activity of the ascending activating brain systems in the animal and human paroxysmal syndromes is discussed.     

Electroencephalographic analysis of manifestations of hidden forms of paroxysmal syndrome in the wakefulness-sleep cycle in rats

An electroencephalographic study of the brain activity in the wakefulness-sleep cycle was carried out on rats of Krushinskii-Molodkina line (KM) with hereditary predisposition to audiogenic convulsions and on Wistar rats that were insensitive to the convulsiogenic sound effect, but with epileptiform manifestations appearing on the background of cadmium intoxication and administration of kainic acid into the caudate nucleus head. There were revealed several EEG patterns whose presence was an indicator of formation of disorders of the CNS activity of the paroxysmal character in the animals. It has been established that in the phase of the rat rapid-wave sleep, a high representation of episodes with predominance of α-diapason EEG oscillations can be considered a specific non-paroxysmal abnormality due to the presence of convulsive syndrome in these animals. There was shown a long steady decrease of sensitivity of KM rats to the convulsiogenic sound effect, which appeared after multiple audiogenic generalized tonicoclonic convulsive attacks, correlated with a decrease of the degree of ?-diapason oscillations and with an increase of representation of α-diapason waves on EEG in the state of the animal quiet wakefulness. The role of disintegration in activity of the ascending activating brain systems in the animal and human paroxysmal syndromes is discussed.     

Reactivity of the somesthesic cortex (S1) during the wakefulness-sleep cycle in the rat]

The changes in amplitude of the activities evoked in the S1 cortex by stimulation of the specific radiations have been studied during the sleep-waking cycle. The recovery mode of these activities after a short or long delay has been tested by the paired stimuli method. Results are in general agreement with those described in the cat.     

Effect of apomorphine on the wakefulness-sleep cycle of the common frog <Emphasis Type="Italic">Rana temporaria</Emphasis>

This work considers effects of introduction into spinal lymphatic sac of dopamine agonist-apomorphine (APO)-at doses of 0.1, 1.0, 2.0, and 4.0 mg/kg body weight on the common frog wakefulness-sleep cycle (WSC). Usually the frog WSC is represented by wakefulness and three types of passive-protective behavior: the immobility states of the type of catalepsy, catatonia, and cataplexy that are characterized by high thresholds of arousal and by different (corresponding to the name) skeletal muscle tones. These immobility forms are considered as homologues of mammalian stressreaction, hibernation, and sleep. Low apomorphine doses produced in WSC a marked decrease of portion of wakefulness and an increase of the immobility state of the catalepsy type; high doses, on the contrary, initially promoted in CNS an increase of wakefulness and the state of catalepsy by demonstrating thereby its stressogenic action; after this, in WSC there increased the portion of the sleep-like immobility state of the catalepsy type that is considered a functional homologue of sleep of homoiothermal animals. In spectra of electrograms of the frog telencephalon the representation of waves of the delta diapason rose. Taking into account that the states of catalepsy and cataplexy in frogs are under control of anterior hypothalamus, it can be suggested that manifestations of cataplexy (sleep) in frog are due to the low level of dopaminergic activity, whereas manifestations of catalepsy (the homologue of stress reaction) are due to the high dopamine content in the anterior hypothalamic structures. Comparative analysis of changes in WSC of amphibians and mammals in response to administration of dopamine and its agonists allows thinking that the role of the dopaminergic neurotransmitter system in regulation of the vertebrate WSC certainly consists in that the low level of activity of this system facilitates development of sleep (catalepsy), whereas the high level provides reaction of arousal and is actively included in the system providing stress-reaction.