Dynamics of neuronal activity in the posterior hypothalamus during alternating phases of the sleep-wake cycle

The dynamics of neuronal activity in the posterior hypothalamus in different phases of the sleep-wake cycle were investigated during experiments on free-ranging cats. The highest frequency discharges were found to occur in 89.3% of neurons belonging to this region during the stages of active wakefulness and emotionally influenced paradoxical sleep. These neurons become less active during restful wakefulness and the unemotional stage of paradoxical sleep; this reduced activity can be most clearly observed in the context of slow-wave sleep. It was found that 7.1% of test neurons discharged at the highest rate during the stage of active wakefulness. They did not achieve an activity level characteristic of active wakefulness during the period of paradoxical sleep, although activity level was higher than during other states. Only 3.6% of neurons followed the opposite pattern, with discharges succeeding more frequently in slow-wave sleep and activity reduced to an equal degree during wakefulness and paradoxical sleep. The neurophysiological mechanisms governing the sleep-wake cycle and how the posterior hypothalamus contributes to these mechanisms are discussed.I. S. Beritashvili Institute of Physiology, Academy of Sciences of Georgian SSR, Tbilisi. Translated from Neirofiziologiya, Vol. 20, No. 2, pp. 160–167, March–April, 1988.     

Temporal patterns of unit activity of mesencephalic reticular nuclei during sleep and waking

Temporal patterns of unit activity in the mesencephalic reticular nuclei (n. cuneiformis, n. parabrachialis) were studied in unrestrained rats during the sleep-waking cycle; activity was derived by means of movable metallic microelectrodes. Analysis of the data showed that most neurons of these mesencephalic reticular nuclei (76 and 66% respectively) generate activity with the highest frequency during active waking and the emotional stage of paradoxical sleep; they discharge with lower frequency during passive wakefulness and the nonemotional stage of paradoxical sleep, and they exhibit least activity during slow-wave sleep. Comparatively few neurons (24 and 15%) demonstrate the opposite kind of temporal pattern of activity: They discharge more intensively during slow-wave sleep and more slowly during active wakefulness and the emotional stage of paradoxical sleep. Activity of these neurons during quiet wakefulness and the nonemotional stage of paradoxical sleep reaches the level of activity observed during slow-wave sleep. Neurons discharging intensively during active wakefulness were found in n. parabrachialis; their discharge frequency during passive wakefulness and slow-wave sleep and its frequency was least during paradoxical sleep. The similarity and differences of the neurophysiological mechanisms of regulation of the phases and stages of the sleepwaking cycle are discussed.I. S. Beritashvili Institute of Physiology, Academy of Sciences of the Georgian SSR, Tbilisi. Translated from Neirofiziologiya, Vol. 16, No. 5, pp. 678–690, September–October, 1984.     

Ozone-induced paradoxical sleep decrease is related to diminished acetylcholine levels in the medial preoptic area in rats

Ozone (O3) produces significant effects on sleep, characterized specially by a decrease in paradoxical sleep (PS) and increase in slow-wave sleep (SWS), which in turn represent a sleep-wake cycle disruption. On the other hand, neuronal activity recorded in the cholinoceptive hypothalamic medial preoptic area (MPO) has been involved in the regulation of sleep. However, there is no direct evidence on the role that acetylcholine (Ach) release in the MPO plays in the sleep-wake cycle. In order to study this relation, we measured the Ach concentration in dialysates collected from MPO in rats exposed to coal-filtered air (clean air) for 48 h and in rats exposed to clean air for 24 h followed by 24-h of O3 exposure to 0.5 ppm. Polygraphic sleep records were taken simultaneously to neurochemical sampling. O3 was employed to disrupt the sleep-wake cycle and relate these changes with concomitant disruptions in Ach concentration dialyzed from MPO. A clear circadian pattern of Ach concentration was observed in dialysates from MPO and also in PS, SWS and wakefulness of rats exposed to filtered air. However, O3 exposure decreased the PS by 65% (Mann-Whitney's U-test, p相似文献   

Dynamics of neuronal activity in the lateral preoptic area of hypothalamus in the course of sleep-waking cycle

Frequency and patterns of activity of 106 neurons in the lateral preoptic area of unanesthetized cats were studied under conditions of indolent head fixation. It was shown that this structure contains two somnogenic neuronal populations with different functions. Neurons increasing their discharge frequency during transition from active to quiet wakefulness and subsequent sleep development to the point of phasic stage of paradoxical sleep development are considered as elements of an anti-waking system, which is involved in the mechanisms of sleep onset and deepening by means of inactivation of the arousal system. Neurons displaying the highest firing rates during light slow-wave sleep and synchronization of discharges with sleep spindles are considered as elements of a slow-wave sleep network.     

Role of septal and entorhinal inputs in the generation of hippocampal electrical activity in the cat sleep-wake cycle

The effects of septal lesion and entorhinal cortex section on hippocampal electrical activity during the cat sleep-wake cycle were investigated in chronic experiments. The medial portion of the septum only was found to participate in generation of this activity. Complete suppression of hippocampal theta rhythm during active wakefulness and paradoxical sleep were the main effects of septal lesion. In slow-wave sleep, the effects of septal lesion manifested in a slight attenuation of the intensity of the dominant frequency (of 1 Hz). Widespread septal lesion does not add to the changes occurring when the medial portion of the septum is so isolated. Section of the entorhinal cortex produces a sharp increase in hippocampal theta rhythm during waking and paradoxical sleep. Clearcut attenuation of delta and subdelta rhythm intensities were observed in slowwave sleep. It is postulated that under normal conditions hippocampal entorhinal input exerts a modulating effect on the genesis of hippocampal theta rhythm.I. S. Beritashvili Institute of Physiology, Academy of Sciences of the Georgian SSR, Tbilisi. Translated from Neirofiziologiya, Vol. 19, No. 5, pp. 622–630, September–October, 1987.     

Neurophysiological analysis of the effects of partial paradoxical sleep deprivation

A neurophysiological study was made of the effects of partial and complete paradoxial sleep deprivation by substituting episodes of active wakefulness for spells of paradoxical sleep (PS) of the same duration in the sleep-wake cycle. Neither accumulated need for paradoxical sleep (culminating in increased onset of PS during deprivation), PS rebound during the post-deprivation period, nor dissociation of the stages of paradoxical sleep resulting in their intervening individually at unaccustomed points in the sleep-wake cycle were observed during our experimental procedure. The phenomenon of self-deprivation, increased heart rate, eye movements, and pontogeniculooccipital (PGO) action potentials also failed to occur during the post-deprivation period. It is postulated that PS requirement and the need for periods of wakefulness stem from the same neurochemical alterations.I. S. Beritashvili Institute of Physiology, Academy of Sciences of the Georgian SSR, Tbilisi. Translated from Neirofiziologiya, Vol. 20, No. 1, pp. 20–28, January–February, 1988.     

Dynamics of neuronal activity in the cingulate gyrus during the sleep-wake cycle

Dynamics of neuronal activity in the cingulate gyrus (CG) was investigated during the sleep-wake cycle (SWC) of free-ranging cats. The highest activity rate was found to occur in 65.4% of neurons during active emotional consciousness (EC) and the so-called emotional phase of paradoxical sleep (PS), while firing rate decreased during passive consciousness (PC) and slow-wave sleep (SS). Peak firing rate was observed during SS in 15% of neurons, while divisions of activity between stages of the SWC remained the same in 19.6%. In addition, discharge patterns in 75.2% of neurons changed consistently in step with phase shifts. More particularly, neurons fired during EC and PS with single action potentials with a more or less even time distribution, whereas a burst-phase activity pattern occurred in the course of SS. Firing rate declined (in 42.6% of units) or remained unchanged (in 50.4%) in the majority of CG neurons (even amongst those manifesting highest activity during EC and PS) as episodes of isolated EEG arousal developed (whether in the context of SS or as PS wore off). This would indicate that the CG actually contributes to shaping the behavioral state of consciousness. The CG, therefore, as one of the higher divisions of the limbic system, must play a major part in controlling the basic mechanisms of the SWC, as well as emotionally motivated processes evolving in the cycle.I. S. Beritashvili Institute of Physiology, Academy of Sciences of the Georgian SSR, Tbilisi. Translated from Neirofiziologiya, Vol. 21, No. 6, pp. 832–840, November–December, 1989.     

The role of the medial preoptic area in the organization of paradoxical sleep

Influence of electrical stimulation of the medial preoptic area of cats on characteristics of paradoxical sleep and activity of medial preoptic neurons were studied in the course of sleep-waking cycle. Low-frequency stimulation of this structure in the state of slow-wave sleep evoked short-latency electrocortical desynchronization and induced transition to paradoxical sleep or paradocical sleep-like state. The same stimulation during the whole period of paradoxical sleep results in a reduction of its duration, practically complete disappearance of tonic stage, and increase in the density of rapid eye movements in phasic stage. The vast majority of meurons in the medial preoptic area decreased their firing rates during quiet waking and slow-wave sleep and dramatically increased their activity during paradoxical sleep. More than 50% of such neurons displayed activation 20-70 s prior to the appearance of electrocorticographic correlates of paradoxical sleep. Some neurons were selectively active during paradoxical sleep. Approximately 50% of cells increased their firing rates a few seconds prior to and/or during series of rapid eye movements. The results suggest that the medial preoptic area contains the units of the executive system (network) of paradoxical sleep and are involved in the mechanisms of neocortical desynchronization.     

Neuronal plasticity in thalamocortical networks during sleep and waking oscillations

Spontaneous brain oscillations during states of vigilance are associated with neuronal plasticity due to rhythmic spike bursts and spike trains fired by thalamic and neocortical neurons during low-frequency rhythms that characterize slow-wave sleep and fast rhythms occurring during waking and REM sleep. Intracellular recordings from thalamic and related cortical neurons in vivo demonstrate that, during natural slow-wave sleep oscillations or their experimental models, both thalamic and cortical neurons progressively enhance their responsiveness. This potentiation lasts for several minutes after the end of oscillatory periods. Cortical neurons display self-sustained activity, similar to responses evoked during previous epochs of stimulation, despite the fact that thalamic neurons remain under a powerful hyperpolarizing pressure. These data suggest that, far from being a quiescent state during which the cortex and subcortical structures are globally inhibited, slow-wave sleep may consolidate memory traces acquired during wakefulness in corticothalamic networks. Similar phenomena occur as a consequence of fast oscillations during brain-activated states.     

Effects of broad-spectrum monoamine oxidase inhibitors on the structure and ratio of stages in in the cat sleep-wake cycle

Monoamine oxidase (MAO) inhibitors disturb the structure of the sleep-wake cycle and its ultradian rhythms by extending total slow-wave sleep, completely suppressing paradoxical sleep, and reducing total waking period considerably. Once the synchrony induced by MAO inhibitors has stopped, a rebound effect of increased waking occurs preceding and during partial restoral of paradoxical sleep. This fact is viewed as an indication of a waking requirement accumulating during the aforementioned partial deprivation under the effects of MAO inhibitors. Especially marked effects are exerted by MAO inhibitors on paradoxical sleep, in which they produce long-term suppression of tonic and phasic components. It is suggested that inhibition of paradoxical sleep is brought about by selective impairment of functional state of its neurophysiological trigger mechanisms.I. S. Beritashvili Institute of Physiology, Academy of Sciences of the Georgian SSR, Tbilisi. Translated from Neirofiziologiya, Vol. 20, No. 4, July–August, 1988, pp. 463–470.     

Chloramphenicol decreases brain glucose utilization and modifies the sleep-wake cycle architecture in rats

We studied the effects of chloramphenicol on brain glucose utilization and sleep-wake cycles in rat. After slightly anaesthetized animals were injected with [18F]fluoro-2-deoxy-D-glucose, we acquired time-concentration curves from three radiosensitive beta microprobes inserted into the right and left frontal cortices and the cerebellum, and applied a three-compartment model to calculate the cerebral metabolic rates for glucose. The sleep-wake cycle architecture was analysed in anaesthetic-free rats by recording electroencephalographic and electromyographic signals. Although chloramphenicol is a well-established inhibitor of oxidative phosphorylation, no compensatory increase in glucose utilization was detected in frontal cortex. Instead, chloramphenicol induced a significant 23% decrease in the regional cerebral metabolic rate for glucose. Such a metabolic response indicates a potential mismatch between energy supply and neuronal activity induced by chloramphenicol administration. Regarding sleep-wake states, chloramphenicol treatment was followed by a 64% increase in waking, a 20% decrease in slow-wave sleep, and a marked 59% loss in paradoxical sleep. Spectral analysis of the electroencephalogram indicates that chloramphenicol induces long-lasting modifications of delta-band power during slow-wave sleep.     

Effects of dietary resveratrol on the sleep-wake cycle in the non-human primate gray mouse lemur (Microcebus murinus)

Converging evidence shows that the non-human primate gray mouse lemur (Microcebus murinus) is ideal for the study of the aging process and for testing the effects of new therapies and dietary interventions on age-associated pathologies. One such dietary supplement is resveratrol (RSV), a dietary polyphenolic compound with several positive effects on metabolic functions and longevity. However, little is known about the effect of RSV on the lemur sleep-wake cycle, which reflects mammalian brain function and health. In the present study, the authors investigated this effect by comparing sleep-wake cycles in adult lemurs based on electroencephalographic (EEG) rhythms. The effect of short-term RSV supplementation on the sleep-wake cycle of mouse lemurs was evaluated in entrained conditions (long-day photoperiods, light:dark 14:10). After 3 wks of RSV supplementation, the animals exhibited a significantly increased proportion of active-wake time, occurring mainly during the resting phase of the sleep-wake cycle (+163%). The increase in active-wake time with RSV supplementation was accompanied by a significant reduction of both paradoxical sleep (-95%) and slow-wave sleep (-38%). These changes mainly occurred during the resting phase of the sleep-wake cycle (RSV supplementation induced negligible changes in active-wake time during the active phase of the sleep-wake cycle). The present data suggest that RSV may be a potent regulator of sleep-wake rhythms and could be of major interest in the study of sleep perturbations associated with aging and neuropathology.     

Oscillations in the oxidation-reduction potential of the brain tissue in rats developing during wakefulness and slow-wave sleep

Variations of the brain cortex redox state potential (E) were recorded in freely moving white rats (mass of 300-350 g) with implanted platinum electrodes (with the platinum reference electrode in the nasal bone) during sleep-wake cycles. It was found that transitions from the slow-wave sleep to wakefulness were accompanied in the number of cortical areas (metabolic-active sites) by the E rise, while the transitions from the wakefulness to slow-ware sleep were associated with a drop of E. However, the episodes of the short-term arousals during the slow-wave sleep were accompanied by the respective decreases in E thus forming the irregular E variations (1.5-3 min in duration). It was also found that the oscillations of a typical pattern (quasisinusoidal with the frequency of 10-20 osc/min and the amplitudes up to several mV) could take place in the metabolic-active cortical sites. These oscillations were defined as fast E oscillations. During the slow-wave sleep, the less regular oscillations with the lower frequency (1.2-10 osc/min) and higher amplitude were recorded in the same cortical sites. These oscillations were defined as slow. It is suggested that the fast metabolic oscillations of wakefulness are mainly controlled by the mitochondria of neuronal populations, whereas the slow metabolic oscillations which occur in the slow-wave sleep are related with glycolysis in populations of glial cells.     

Activation of extracellular signal-regulated kinase signaling in the pedunculopontine tegmental cells is involved in the maintenance of sleep in rats

Considerable evidence suggests that receptor-mediated excitation and inhibition of brainstem pedunculopontine tegmental (PPT) neurons are critically involved in the regulation of sleep-wake states. However, the molecular mechanisms operating within the PPT-controlling sleep-wake states remain relatively unknown. This study was designed to examine sleep-wake state-associated extracellular-signal-regulated kinase 1 and 2 (ERK1/2) transduction changes in the PPT of freely moving rats. The results of this study demonstrate that the levels of ERK1/2 expression, phosphorylation, and activity in the PPT increased with increased amount of time spent in sleep. The sleep-associated increases in ERK1/2 expression, phosphorylation, and activity were not observed in the cortex, or in the immediately adjacent medial pontine reticular formation. The results of regression analyses revealed significant positive relationships between the levels of ERK1/2 expression, phosphorylation, and activity in the PPT and amounts of time spent in slow-wave sleep, rapid eye movement sleep, and total sleep. Additionally, these regression analyses revealed significant negative relationships between the levels of ERK1/2 expression, phosphorylation, and activity in the PPT and amounts of time spent in wakefulness. Collectively, these results, for the first time, suggest that the increased ERK1/2 signaling in the PPT is associated with maintenance of sleep via suppression of wakefulness.     

Unit activity in the cat visual cortex in the sleep-waking cycle

Changes in spontaneous unit activity in the primary visual cortex during the sleep-waking cycle were studied in chronic experiments on dark-adapted cats. In the cell population studied activity in states of wakefulness and of paradoxical sleep did not differ significantly either in mean discharge frequency or in pattern. Activity of most cells in a state of slow sleep differed significantly from that in states of wakefulness and paradoxical sleep by the development of a "burst-pause" pattern in the unit discharges.A. N. Severtsov Institute of Evolutionary Morphology and Ecology of Animals, Moscow. Translated from Neirofiziologiya, Vol. 8, No. 4, pp. 343–349, July–August, 1976.     

PER3 polymorphism predicts sleep structure and waking performance

Circadian rhythmicity and sleep homeostasis interact to regulate sleep-wake cycles [1-4], but the genetic basis of individual differences in sleep-wake regulation remains largely unknown [5]. PERIOD genes are thought to contribute to individual differences in sleep timing by affecting circadian rhythmicity [6], but not sleep homeostasis [7, 8]. We quantified the contribution of a variable-number tandem-repeat polymorphism in the coding region of the circadian clock gene PERIOD3 (PER3) [9, 10] to sleep-wake regulation in a prospective study, in which 24 healthy participants were selected only on the basis of their PER3 genotype. Homozygosity for the longer allele (PER3(5/5)) had a considerable effect on sleep structure, including several markers of sleep homeostasis: slow-wave sleep (SWS) and electroencephalogram (EEG) slow-wave activity in non-rapid eye movement (non-REM) sleep and theta and alpha activity during wakefulness and REM sleep were all increased in PER3(5/5) compared to PER3(4/4) individuals. In addition, the decrement of cognitive performance in response to sleep loss was significantly greater in the PER3(5/5) individuals. By contrast, the circadian rhythms of melatonin, cortisol, and peripheral PER3 mRNA expression were not affected. The data show that this polymorphism in PER3 predicts individual differences in the sleep-loss-induced decrement in performance and that this differential susceptibility may be mediated by its effects on sleep homeostasis.     

The effect of multiple audiogenic seizures upon the sleep organization in rats

The organization of sleep during and after frequentative convulsions, consisting of 2, 3, or 5 comparatively rare seizures (following one another with a 90-minute interval) or of 3, 5 or 9 comparatively frequent seizures (following one another with a 45-minute interval) of generalized tonic-clonic character in Krushinskii-Molodkina strain rats with inherited predisposition to audiogenic convulsions, was studied. In frequentative convulsions with rare seizures, between separate seizures, passive wakefulness (75.2 +/- 4.6% time) prevailed under low (24.8 +/- 4.3%) slow-wave sleep and full absence of fast-wave sleep. In rats under frequentative convulsions with frequent seizures, in interictal period, only passive wakefulness was observed under reduction of slow-wave sleep and fast-wave sleep, i.e. total sleep deprivation. Minimal latensy of first episodes of the slow-wave sleep after frequentative convulsions was 59.9 +/- 10.8, and of fast-wave sleep: 158.2 +/- 13.4 min. First episodes of slow-wave sleep and fast-wave sleep had normal structure, though they were lesser and shorter than in control experiments. In spite of long-lasting (up to 7 hrs) absence of slow-wave sleep during seizure and prolonged (8.5 hrs) reduction of fast-wave sleep with no subsequent compensatory increase, these conditions occurred in the wakefulness-sleep cycle during 12-hour reconstruction after convulsions. The reconstruction period after frequentative convulsions was characterized by increase in general share of wakefulness and reduction of total slow-wave and fast-wave sleep as compared with control data. Paroxysmal status seems to disorganize work of the brain somnogenic structures. The function of systems responsible for slow-wave sleep are affected to a lesser extent, but disorganization of the system responsible for fast-wave sleep is more significant and associated with mechanisms of starting the phase of sleep in the first place.     

Dynamics of spontaneous activity in random networks with multiple neuron subtypes and synaptic noise

During slow-wave sleep, brain electrical activity is dominated by the slow (< 1 Hz) electroencephalogram (EEG) oscillations characterized by the periodic transitions between active (or Up) and silent (or Down) states in the membrane voltage of the cortical and thalamic neurons. Sleep slow oscillation is believed to play critical role in consolidation of recent memories. Past computational studies, based on the Hodgkin-Huxley type neuronal models, revealed possible intracellular and network mechanisms of the neuronal activity during sleep, however, they failed to explore the large-scale cortical network dynamics depending on collective behavior in the large populations of neurons. In this new study, we developed a novel class of reduced discrete time spiking neuron models for large-scale network simulations of wake and sleep dynamics. In addition to the spiking mechanism, the new model implemented nonlinearities capturing effects of the leak current, the Ca²⁺ dependent K⁺ current and the persistent Na⁺ current that were found to be critical for transitions between Up and Down states of the slow oscillation. We applied the new model to study large-scale two-dimensional cortical network activity during slow-wave sleep. Our study explained traveling wave dynamics and characteristic synchronization properties of transitions between Up and Down states of the slow oscillation as observed in vivo in recordings from cats. We further predict a critical role of synaptic noise and slow adaptive currents for spike sequence replay as found during sleep related memory consolidation.     

Role of hypothalamic adenosinergic systems in regulating states of wakefulness in the rat

Immunohistochemical localization of adenosine deaminase (ADA), marker for the putative neurotransmitter/neuromodulator adenosine, has revealed a population of ADA-positive neurons in the ventrolateral hypothalamus in the rat brain. These posterior neurons possess adenosine uptake sites. We have studied the effects of local injections of adenosinergic drugs on the sleep-wake cycle in the rat. Microinjection of erythro-9-(hydroxy-2, nonyl-3) adenine (EHNA), a specific inhibitor of adenosine deaminase, resulted in a significant decrease in wakefulness (W) and an increase in deep slow wave sleep (SWS, or S2) and paradoxical sleep (SP). On the other hand, microinjections of soluflazine, a nucleoside transport inhibitor, increased W and decreased total sleep. These opposite modifications may reflect opposite variations in the extracellular concentrations of Ado and consequently different responses of A1/A2 adenosine receptors.     

Central but not systemic administration of ghrelin induces wakefulness in mice

Ghrelin is a brain-gut peptide hormone widely known for its orexigenic and growth hormone-releasing activities. Findings from our and other laboratories indicate a role of ghrelin in sleep regulation. The effects of exogenous ghrelin on sleep-wake activity in mice are, however, unknown. The aim of the present study was to determine the sleep-modulating effects of ghrelin after central and systemic administrations in mice. Sleep-wake activity after intracerebroventricular (i.c.v.) administration of 0.2, 1 and 5 μg ghrelin and intraperitoneal injections of 40, 100, and 400 μg/kg ghrelin prior to light onset were determined in C57BL/6 mice. In addition, body temperature, motor activity and 1-hour food intake was measured after the systemic injections. Sleep effects of systemic ghrelin (40 and 400 μg/kg) injected before dark onset were also determined. I.c.v. injection of ghrelin increased wakefulness and suppressed non-rapid-eye-movement sleep and electroencephalographic slow-wave activity in the first hour after injections. Rapid-eye-movement sleep was decreased for 2-4 hours after each dose of ghrelin. Sytemic administration of ghrelin did not induce changes in sleep-wake activity in mice at dark or light onset. Motor activity and body temperature remained unaltered and food intake was significantly increased after systemic injections of ghrelin given prior the light period. These findings indicate that the activation of central, but not peripheral, ghrelin-sensitive mechanisms elicits arousal in mice. The results are consistent with the hypothesis that the activation of the hypothalamic neuronal circuit formed by ghrelin, orexin, and neuropeptide Y neurons triggers behavioral sequence characterized by increased wakefulness, motor activity and feeding in nocturnal rodents.