Sleep deprivation in the rat: IV. Paradoxical sleep deprivation

Twelve rats were subjected to paradoxical sleep deprivation (PSD) by the disk apparatus. All PSD rats died or were sacrificed when death seemed imminent within 16-54 days. No anatomical cause of death was identified. All PSD rats showed a debilitated appearance, lesions on their tails and paws, and weight loss in spite of increased food intake. Their yoked control (PSC) rats remained healthy. Since dehydration was ruled out and several measures indicated normal or accelerated use of nutrients, the food-weight changes in PSD rats were attributed to increased energy expenditure (EE). The measurement of EE, based upon caloric value of food, weight, and wastes, indicated that all PSD rats increased EE, with mean levels reaching more than twice baseline values. All of these changes had been observed in rats deprived totally of sleep; the major difference was that they developed more slowly in PSD rats.     

Sleep deprivation in the rat: III. Total sleep deprivation

Ten rats were subjected to total sleep deprivation (TSD) by the disk apparatus. All TSD rats died or were sacrificed when death seemed imminent within 11-32 days. No anatomical cause of death was identified. All TSD rats showed a debilitated appearance, lesions on their tails and paws, and weight loss in spite of increased food intake. Their yoked control (TSC) rats remained healthy. Since dehydration was ruled out and several measures indicated accelerated use rather than failure to absorb nutrients, the food-weight changes in TSD rats were attributed to increased energy expenditure (EE). The measurement of EE, based upon caloric value of food, weight, and wastes, indicated that all TSD rats increased EE, with mean levels reaching more than twice baseline values.     

Sleep deprivation in the rat: XIII. The effect of hypothyroidism on sleep deprivation symptoms

Previous studies of rats subjected to total sleep deprivation by the disk-over-water method had shown a large increase in energy expenditure (EE) and an initial increase followed by a later decrease in body temperature (Tb). It had been proposed that the increase in Tb resulted from regulation toward a higher temperature or setpoint, that the later decline in Tb resulted from excessive heat loss, and that the increase in EE supported both of these thermoregulatory changes. To evaluate this proposed role of the increase in EE, we examined whether blunting the EE rise in sleep-deprived rats by making them hypothyroid attenuated and/or shortened the initial increase in Tb and accelerated the later decline in Tb. Rats made hypothyroid by propylthiouracil administration (TxD rats) were totally sleep deprived and compared to hypothyroid yoked control (TxC) rats and to previously studied, untreated, totally sleep-deprived (TSD) rats. Neither TxD nor TxC rats showed large increases in EE like those of TSD rats. TxD rats did not initially increase Tb, as TSD rats had. Presumably, TSD rats had been able to support an initially elevated Tb, in spite of excessive heat loss, by large increases in EE, although even these increases were eventually insufficient. TxD rats showed much earlier and greater declines in Tb than TxC and TSD rats, eventually becoming severely hypothermic. These results support the interpretation that the large increase in EE previously seen in TSD rats had been compensatory for deprivation-induced thermoregulatory deficits. TxD rats survived an average of 17.1 days, which was not significantly different from survival time in TSD rats. However, there were differences in mortal processes between the two groups. TxD rats died or were sacrificed after chronic, severe hypothermia without observable signs of other morbid pathology. TSD rats had not shown similarly low Tb until just prior to death, but had shown signs of severe pathology, including severely debilitated appearance, disheveled fur, and severe lesions on their tails and on the plantar surfaces of their paws. These signs were diminished or absent in TxD rats, possibly due to blunted EE, lower Tb, or other effects of hypothyroidism. Because the skin changes seen in TSD rats were minimal in TxD rats, they could not have been responsible for the excessive heat loss.     

Sleep deprivation in the rat: VIII. High EEG amplitude sleep deprivation

The disk apparatus was used to deprive six rats of the portion of non-rapid eye movement (NREM) sleep with high electroencephalogram (EEG) amplitude (HS2). All HS2 deprived (HS2D) rats died or were sacrificed when death seemed imminent within 23 to 66 days. No anatomical cause of death was identified. All deprived rats showed a debilitated appearance, lesions on their tails and paws, and weight loss in spite of increased food intake. Energy expenditure (calculated from the caloric value of food, weight change, and wastes) increased to more than twice baseline values. With one exception, yoked control rats remained generally healthy. It was not clear whether the changes in HS2D rats resulted from the loss of HS2 or the general disruption of NREM sleep that accompanied this loss. Also, it was not possible to produce major HS2 loss without incurring some loss of paradoxical sleep (PS). Control studies indicated that the partial PS loss in HS2D rats could not, in and of itself, account for all the pathological effects. However, an interaction of HS2D and partial PS loss in producing pathological effects cannot be ruled out.     

Sleep deprivation in the rat: XI. The effect of guanethidine-induced sympathetic blockade on the sleep deprivation syndrome

In earlier studies, rats totally deprived of sleep by a disk-over-water apparatus (TSD rats) had shown an increase in energy expenditure (EE) that could not be explained by increased motor activity or the metabolic expense of wakefulness. Excessive activation of a calorigenic mediator was a possibility, and norepinephrine-mediated sympathetic activation was the most likely candidate, because plasma norepinephrine (NE) levels had risen sharply in TSD rats. To determine whether this activation was necessary for increased EE in sleep deprived rats, the peripheral sympathetic blocking agent guanethidine (GU) was administered to six sleep-deprived (GD) rats and their yoked control (GC) rats. GU attenuated the increase in NE previously seen in TSD rats, but the increase in EE was not attenuated. Apparently, NE-mediated sympathetic activation was not critical for increased EE in sleep-deprived rats. On the other hand, plasma epinephrine (EPI) levels were significantly increased in GD (but not in GC) rats above those previously seen in TSD rats, suggesting the substitution of one calorigenic mediator for another in response to an abnormally elevated need for EE. Temperature data suggest that increased need for EE could arise from an elevated temperature setpoint and an inability to retain body heat. GD (but not GC) rats also showed other effects previously seen in TSD rats, including debilitated appearance; severe ulcerative and hyperkeratotic lesions on the tails and plantar surfaces; initially increased and later decreased body temperature; decreased plasma thyroxine; increased triiodothyronine-thyroxine ratio; and eventual death. Evidently, NE-mediated sympathetic activation was not critical to any of these effects, although a role for catecholamines cannot be ruled out.     

Total sleep deprivation increases extracellular serotonin in the rat hippocampus

Sleep deprivation exerts antidepressant effects after only one night of deprivation, demonstrating that a rapid antidepressant response is possible. In this report we tested the hypothesis that total sleep deprivation induces an increase in extracellular serotonin (5-HT) levels in the hippocampus, a structure that has been proposed repeatedly to play a role in the pathophysiology of depression. Sleep deprivation was performed using the disk-over-water method. Extracellular levels of 5-HT were determined in 3 h periods with microdialysis and measured by high performance liquid chromatography coupled with electrochemical detection. Sleep deprivation induced an increase in 5-HT levels during the sleep deprivation day. During an additional sleep recovery day, 5-HT remained elevated even though rats displayed normal amounts of sleep. Stimulus control rats, which had been allowed to sleep, did not experience a significant increased in 5-HT levels, though they were exposed to a stressful situation similar to slee-deprived rats. These results are consistent with a role of 5-HT in the antidepressant effects of sleep deprivation.     

Sleep deprivation and c-fos expression in the rat brain

SUMMARY  This study examined the effects of sleep deprivation on the expression of the immediate early gene c-fos in the brain with both in situ hybridization and immunocytochemistry. Rats were manually sleep-derived for 3 h, 6 h, 12 h, and 24 h starting at light onset (08.00 hours), and for 12 h starting at dark onset (20.00 hours). c-Fos expression was found to be higher in sleep-deprived rats with respect to control animals in several brain areas. The increase was evident both in terms of c-fos mRNA and Fos protein, although with a different time course. Among the areas that showed a consistent induction of c-fos were many cortical regions, the medial preoptic area and the posterior hypothalamic area, some thalamic nuclei, and several nuclei of the dorsal pontine tegmentum. The pattern of c-fos expression after sleep deprivation was very similar to that observed after comparable periods of spontaneous wakefulness (Pompeiano et al. 1994). In general, the increase in c-fos expression was not simply proportional to the amount of previous wakefulness. In many areas, the highest levels of c-fos were seen after 3 h of sleep deprivation. These observations are discussed with respect to the homeostatic regulation of sleep and to the functional consequences of wakefulness in specific brain areas.     

Sleep continuity and the REM-nonREM cycle in the rat under baseline conditions and after sleep deprivation

Wakefulness, nonrapid eye movement sleep (nonREMS) and REMS of rats were scored in 4-s epochs during the first 8 h of the 12-h light period of a baseline (BL) day and during recovery (REC) from 24-h sleep deprivation (SD). Vigilance state continuity was investigated by analyzing the distribution of state episodes. After SD, state continuity was enhanced. The reduced occurrence of short wake episodes resulted in a consolidation of sleep states. The distribution of the REM-nonREM cycle length showed a mode at 10-13 min for both BL and REC. The variability of the cycle length was reduced after SD. The mean cycle length was markedly influenced by the criteria of minimum REMS episode duration and maximal allowed REMS episode interruption.     

Enhanced brain small‐worldness after sleep deprivation: a compensatory effect

Sleep deprivation has a variable impact on extrinsic activities during multiple cognitive tasks, especially on mood and emotion processing. There is also a trait‐like individual vulnerability or compensatory effect in cognition. Previous studies have elucidated the altered functional connectivity after sleep deprivation. However, it remains unclear whether the small‐world properties of resting‐state network are sensitive to sleep deprivation. A small‐world network is a type of graph that combines a high local connectivity as well as a few long‐range connections, which ensures a higher information‐processing efficiency at a low cost. The complex network of the brain can be described as a small‐world network, in which a node is a brain region and an edge is present when there is a functional correlation between two nodes. Here, we investigated the topological properties of the human brain networks of 22 healthy subjects under sufficient sleep and sleep‐deprived conditions. Specifically, small‐worldness is utilized to quantify the small‐world property, by comparing the clustering coefficient and path length of a given network to an equivalent random network with same degree distribution. After sufficient sleep, the brain networks showed the property of small‐worldness. Compared with the resting state under sufficient sleep, the small‐world property was significantly enhanced in the sleep deprivation condition, suggesting a possible compensatory adaptation of the human brain. Specifically, the altered measurements were correlated with the neuroticism of subjects, indicating that individuals with low‐levels of neuroticism are more resilient to sleep deprivation.     

睡眠剥夺后大鼠皮质、海马和杏仁核微管相关蛋白-2及神经丝蛋白的表达变化

目的探讨睡眠剥夺后大鼠皮质、海马和杏仁核微管相关蛋白-2(MAP-2)及神经丝蛋白(NF-200)表达的变化。方法采用改良小平台水环境法制作大鼠睡眠剥夺模型,大鼠随机分为睡眠剥夺组(SD组)、环境对照组(TC组)和空白对照组(CC组)。SD组包括睡眠剥夺6h、12h、1d、2d、3d、5d、7d共7个时点,每个时间点5只大鼠,CC组5只。免疫组织化学法观察MAP-2和NF-200阳性表达。结果睡眠剥夺5d和7d时,皮质、CA1、CA2、CA3、齿状回和杏仁核MAP-2和NF-200阳性表达减少(P0.05,P0.01)。结论睡眠剥夺可导致脑组织MAP-2和NF-200表达减少。     

Homeostasis of REM sleep after total and selective sleep deprivation in the rat

During specific rapid eye movement (REM) sleep deprivation its homeostatic regulation is expressed by progressively more frequent attempts to enter REM and by a compensatory rebound after the deprivation ends. The buildup of pressure to enter REM may be hypothesized to depend just on the time elapsed without REM or to be differentially related to non-REM (NREM) and wakefulness. This problem bears direct implications on the issue of the function of REM and its relation to NREM. We compared three protocols that combined REM-specific and total sleep deprivation so that animals underwent similar 3-h REM deprivations but different concomitant NREM deprivations for the first 2 (2T1R), 1 (1T2R), or 0 (3R) hours. Deprivation periods started at hour 6 after lights on. Twenty-two chronically implanted rats were recorded. The median amount of REM during all three protocols was approximately 1 min. The deficits of median amount of NREM in minutes within the 3-h deprivation periods as compared with their baselines were, respectively for 2T1R, 1T2R, and 3R, 35 (43%), 25 (25%), and 7 (7%). Medians of REM rebound in the three succeeding hours, in minutes above baseline, were, respectively, 8 (44%), 9 (53%), and 9 (50%), showing no significant differences among protocols. Attempted transitions to REM showed a rising trend during REM deprivations reaching a final value that did not differ significantly among the three protocols. These results support the hypothesis that the build up of REM pressure and its subsequent rebound is primarily related to REM absence independent of the presence of NREM.     

Sleep regulation in the Djungarian hamster: comparison of the dynamics leading to the slow-wave activity increase after sleep deprivation and daily torpor

STUDY OBJECTIVES: Emerging from daily torpor, Djungarian hamsters (Phodopus sungorus) show an initial increase in electroencephalographic slow-wave activity (power density between 0.75 and 4.0 Hz) during sleep that gradually declines. This feature is typical for sleep following prolonged waking and supports the hypothesis that sleep pressure increases during daily torpor. After hamsters were subjected to sleep deprivation or partial non-rapid eye movement sleep deprivation immediately following torpor, slow-wave activity remained high and decreased only when sleep was allowed. An analysis of the dynamics of the process underlying the build-up of sleep pressure during episodes of waking and torpor may provide insights into the regulation of normal sleep and wakefulness. We have analyzed in more detail the timecourse of the process that is common for waking and daily torpor and that could account for the subsequent increase in slow-wave activity. DESIGN: Continuous 24-hour recordings of electroencephalography, electromyography, cortical temperature, and electroencephalographic spectral analysis were performed. Torpor data of 28 hamsters and sleep-deprivation data of diverse durations collected previously in 15 hamsters were analyzed. SETTING: N/A. PATIENTS OR PARTICIPANTS: N/A. INTERVENTIONS: Sleep deprivation. MEASUREMENTS AND RESULTS: Slow-wave activity invariably increased as a function of the duration of both prior waking and torpor. However, the time constant of the build-up of slow-wave activity was approximately 2.75 times slower during torpor compared to sleep deprivation. Brain temperature recorded during the torpor bouts was 10 degrees to 12 degrees C below euthermic brain temperature. Therefore, the temperature coefficient of the time constant for the slow-wave-activity increase is between 2.3 and 2.8, a range typical for biochemical processes. CONCLUSIONS: We conclude that the processes occurring during daily torpor in the Djungarian hamster are similar to those occurring during sleep deprivation, but the build-up of sleep pressure during torpor appears to be slowed down by the lower brain temperature.     

Sleep after immobilization stress and sleep deprivation: common features and theoretical integration

The goal of the present paper is to elucidate and to resolve contradictions in the relationships among different forms of stress, sleep deprivation, and paradoxical sleep (PS) functions. Acute immobilization stress and the stress of learned helplessness are accompanied by an increase of PS, whereas the stress of defense behavior and the stress of self-stimulation cause PS reduction. Recovery sleep after total sleep deprivation performed on the rotating platform is marked by a dramatic rebound of PS although NREM (non-rapid eye movement) sleep deprivation is more prominent than PS deprivation. This PS rebound leads to a quick reversal of the pathology caused by prolonged sleep deprivation. The search activity (SA) concept presents an explanation for these contradictions. SA increases body resistance to stress and diseases, whereas renunciation of search (giving up, helplessness) decreases body resistance. PS and dreams contain covert SA, which compensates for the lack of the overt SA in the preceding period of wakefulness. The requirement for PS increases after giving up and decreases after active defense behavior and self-stimulation. Immobilization stress prevents SA in waking behavior and increases the need in PS. Sleep deprivation on the rotating platform, like immobilization stress, prevents SA, produces conditions for learned helplessness and, suppresses PS. Such a combination increases PS pressure and decreases body resistance.     

Gene expression in the rat brain during sleep deprivation and recovery sleep: an Affymetrix GeneChip study

Previous studies have demonstrated that macromolecular synthesis in the brain is modulated in association with the occurrence of sleep and wakefulness. Similarly, the spectral composition of electroencephalographic activity that occurs during sleep is dependent on the duration of prior wakefulness. Since this homeostatic relationship between wake and sleep is highly conserved across mammalian species, genes that are truly involved in the electroencephalographic response to sleep deprivation might be expected to be conserved across mammalian species. Therefore, in the rat cerebral cortex, we have studied the effects of sleep deprivation on the expression of immediate early gene and heat shock protein mRNAs previously shown to be upregulated in the mouse brain in sleep deprivation and in recovery sleep after sleep deprivation. We find that the molecular response to sleep deprivation and recovery sleep in the brain is highly conserved between these two mammalian species, at least in terms of expression of immediate early gene and heat shock protein family members. Using Affymetrix Neurobiology U34 GeneChips , we also screened the rat cerebral cortex, basal forebrain, and hypothalamus for other genes whose expression may be modulated by sleep deprivation or recovery sleep. We find that the response of the basal forebrain to sleep deprivation is more similar to that of the cerebral cortex than to the hypothalamus. Together, these results suggest that sleep-dependent changes in gene expression in the cerebral cortex are similar across rodent species and therefore may underlie sleep history-dependent changes in sleep electroencephalographic activity.     

Sleep deprivation in the rat: II. Methodology

Methods common to several studies in this series are described. A key feature is a sleep deprivation apparatus in which an experimental and a yoked control rat are housed on opposite sides of a divided disk suspended over shallow water. When the experimental rat enters a "forbidden" sleep stage, the disk is automatically rotated, forcing the experimental rat to walk to avoid being carried into the water. The control rat receives the same physical stimulation but can sleep ad lib when the disk is stationary.     

Sleep deprivation in the rat: IX. Recovery

Eight rats were subjected to total sleep deprivation, paradoxical sleep deprivation, or high amplitude sleep deprivation until they showed major deprivation-induced changes. Then they were allowed to sleep ad lib. Three rats that had shown the largest temperature declines died within two to six recovery days. During the first 15 days of ad lib sleep, surviving rats showed complete or almost complete reversal of the following deprivation-induced changes: debilitated appearance, lesions on the paws and tail, high energy expenditure, large decreases in peritoneal temperature, high plasma epinephrine and norepinephrine levels, and low thyroxine levels. The most prominent features of recovery sleep in all rats were immediate and large rebounds of paradoxical sleep to far above baseline levels, followed by lesser temporally extended rebounds. Rebounds of high amplitude non-rapid eye movement (NREM) sleep occurred only in some rats and were smaller and less immediate.     

Effects of sleep deprivation on extracellular serotonin in hippocampus and frontal cortex of the rat

Sleep deprivation improves the mood of depressed patients, but the exact mechanism behind this effect is unclear. An enhancement of serotonergic neurotransmission has been suggested. In this study, we used in vivo microdialysis to monitor extracellular serotonin in the hippocampus and the frontal cortex of rats during an 8 h sleep deprivation period. These brain regions were selected since both have been implicated in depression. The behavioral state of the animal was continuously monitored by polygraphic recordings during the experiment. Sleep deprivation produced a gradual decline in extracellular serotonin levels, both in the hippocampus and in the frontal cortex. In order to investigate whether the reduction in serotonin was due to other factors than sleep deprivation, i.e. time of day effect, another experiment was performed. Here animals were allowed to sleep during most of the recording period. This experiment showed the expected changes in extracellular serotonin levels: consistently higher levels in the awake, non-sleep deprived animals compared to during sleep, but no time of day effect. The reduction in extracellular serotonin during sleep deprivation may suggest that serotonin does not play a major role in the mood-elevating effect of sleep deprivation. However, since 5-HT levels are strongly behavioral state dependent, by eliminating sleep, there may be a net increase in serotonergic neurotransmission during the sleep deprivation period.     

The effect of sleep deprivation and recovery sleep on plasma corticosterone in the rat

The effect of 24-h sleep deprivation by forced locomotion on plasma corticosterone was investigated in the rat. Corticosterone was slightly elevated after 21.5 h sleep deprivation, but did not differ from controls after a 2.5-h recovery period. An acute 20-min forced locomotion period caused a marked rise in plasma corticosterone. It is concluded that stress is not a major factor contributing to the massive effects of sleep deprivation on sleep parameters.     

Sleep deprivation has a neuroprotective role in a traumatic brain injury of the rat

During the process of a brain injury, responses to produce damage and cell death are activated, but self-protective responses that attempt to maintain the integrity and functionality of the brain are also activated. We have previously reported that the recovery from a traumatic brain injury (TBI) is better in rats if it occurs during the dark phase of the diurnal cycle when rats are in the waking period. This suggests that wakefulness causes a neuroprotective role in this type of injury. Here we report that 24 h of total sleep deprivation after a TBI reduces the morphological damage and enhances the recovery of the rats, as seen on a neurobiological scale.     

Rapid eye movement sleep deprivation modulates synapsinI expression in rat brain

Rapid eye movement sleep (REMS) deprivation (REMSD) has been reported to elevate neurotransmitter level in the brain; however, intracellular mechanism of its increased release was not studied. Phosphorylation of synapsinI, a synaptic vesicle-associated protein, is involved in the regulation of neurotransmitter release. In this study, rats were REMS deprived by classical flowerpot method; free moving control (FMC), large platform control (LPC) and recovery control (REC) was carried out. In another set REMS deprived rats were intraperitoneally (i.p.) injected with α1-adrenoceptor antagonist, prazosin (PRZ). Effects of REMSD on Na-K ATPase activity and on the total synapsinI as well as phosphorylated synapsinI levels were estimated in synaptosomes prepared from whole brain. It was observed that REMSD significantly increased synaptosomal Na-K ATPase activity, which was prevented by PRZ. Western blotting of the same samples by anti-synapsinI and anti-synapsinI-phosphoSer603 showed that REMSD increased both the total as well as phospho-form of synapsinI as compared to respective levels in FMC and LPC samples. These findings suggest a functional link between REMSD and synaptic vesicular mobilization at the presynaptic terminal, a process that is essential for neurotransmitter release. The findings help explaining the intracellular mechanism of elevated neurotransmitter release associated to REMSD.