Restraint increases prolactin and REM sleep in C57BL/6J mice but not in BALB/cJ mice.

Sleep is generally considered to be a recovery from prior wakefulness. The architecture of sleep not only depends on the duration of wakefulness but also on its quality in terms of specific experiences. In the present experiment, we studied the effects of restraint stress on sleep architecture and sleep electroencephalography (EEG) in different strains of mice (C57BL/6J and BALB/cJ). One objective was to determine if the rapid eye movement (REM) sleep-promoting effects of restraint stress previously reported for rats would also occur in mice. In addition, we examined whether the effects of restraint stress on sleep are different from effects of social defeat stress, which was found to have a non-REM (NREM) sleep-promoting effect. We further measured corticosterone and prolactin levels as possible mediators of restraint stress-induced changes in sleep. Adult male C57BL/6J and BALB/cJ mice were subjected to 1 h of restraint stress in the middle of the light phase. To control for possible effects of sleep loss per se, the animals were also kept awake for 1 h by gentle handling. Restraint stress resulted in a mild increase in NREM sleep compared with baseline, but, overall, this effect was not significantly different from sleep deprivation by gentle handling. In contrast, restraint stress caused a significant increase in REM sleep compared with handling in the C57BL/6J mice but not in BALB/cJ mice. Corticosterone levels were significantly and similarly elevated after restraint in both strains, but prolactin was increased only in the C57BL/6J mice. In conclusion, this study shows that the restraint stress-induced increase in REM sleep in mice is strongly strain dependent. The concomitant increases in prolactin and REM sleep in the C57BL/6J mice, but not in BALB/cJ mice, suggest prolactin may be involved in the mechanism underlying restraint stress-induced REM sleep. Furthermore, this study confirms that different stressors differentially affect NREM and REM sleep. Whereas restraint stress promotes REM sleep in C57BL/6J mice, we previously found that in the same strain, social defeat stress promotes NREM sleep. As such, studying the consequences of specific stressful stimuli may be an important tool to unravel both the mechanism and function of different sleep stages.

Effects of pinealectomy on baseline sleep and response to sleep deprivation.

STUDY OBJECTIVES: We have previously reported that older (24 mo.) Fischer rats manifest a diminished post-sleep deprivation increase in NREM and REM sleep. In order to examine whether this decline reflects an age-related change in pineal function, we are now reporting on baseline and recovery sleep parameters in pinealectomized 3-, 12-, and 24-month old rats following 24 hours of sleep deprivation using the disk-over-water method. DESIGN: Three independent age groups; within each group there were sequential measures of sleep under baseline conditions and during recovery from sleep deprivation. SETTING: The Sleep Research Laboratory at the University of Chicago PARTICIPANTS: 56 male Fisher (F344) rats INTERVENTIONS: 24 hours of total sleep deprivation using the disk-over-water method MEASUREMENTS: Sleep staging of EEG and EMG, and power spectral analysis of the EEG RESULTS: Pinealectomized (pinex) rats did not differ from sham-operated (sham) rats in total sleep, REM sleep, super-modal high-amplitude NREM sleep (HS2), a measure of NREM EEG delta power, or circadian rhythm amplitude. In the pinex rats, there was a modest (2.5%) age-independent increase in NREM sleep (p<0.02). The pinex rats of all ages failed to manifest the increase in NREM sleep during recovery seen in the sham-operated animals (p<0.04). CONCLUSIONS: We found no evidence that altered pineal function is responsible for age-related changes in baseline sleep in the rat. These data also suggest that, independent of age, normal pineal function may be relevant to the ability to generate increased NREM sleep in response to prior sleep deprivation.

The circadian clock mutation alters sleep homeostasis in the mouse.

The onset and duration of sleep are thought to be primarily under the control of a homeostatic mechanism affected by previous periods of wake and sleep and a circadian timing mechanism that partitions wake and sleep into different portions of the day and night. The mouse Clock mutation induces pronounced changes in overall circadian organization. We sought to determine whether this genetic disruption of circadian timing would affect sleep homeostasis. The Clock mutation affected a number of sleep parameters during entrainment to a 12 hr light/dark (LD 12:12) cycle, when animals were free-running in constant darkness (DD), and during recovery from 6 hr of sleep deprivation in LD 12:12. In particular, in LD 12:12, heterozygous and homozygous Clock mutants slept, respectively, approximately 1 and approximately 2 hr less than wild-type mice, and they had 25 and 51% smaller increases in rapid eye movement (REM) sleep during 24 hr recovery, respectively, than wild-type mice. The effects of the mutation on sleep are not readily attributable to differential entrainment to LD 12:12 because the baseline sleep differences between genotypes were also present when animals were free-running in DD. These results indicate that genetic alterations of the circadian clock system and/or its regulatory genes are likely to have widespread effects on a variety of sleep and wake parameters, including the homeostatic regulation of sleep.

Age-dependent changes in recovery sleep after 48 hours of sleep deprivation in rats.

To characterize possible changes in homeostatic regulation of sleep with aging, we have examined sleep stages during recovery sleep after 48 h of sleep deprivation in young (3 months), middle aged (12 months), and old (24 months) rats. It was found that young and middle aged, in contrast to old rats, had large (21-24%) increases in total sleep time during recovery sleep; the old rats experienced a quantitatively small (8%) but significant rise in total sleep. NREM sleep increased significantly during the recovery period in young and middle aged, but not older rats. High voltage NREM sleep (HS2) declined by 30% during recovery in the young animals, but remained unchanged compared to baseline in the middle aged and old animals. The young and middle aged rats had increases in REM sleep during recovery compared to their baseline by 96% and 93%, respectively, which was significantly greater than a 65% increase during recovery in the old rats. Increases in total sleep and REM sleep during recovery were largely confined to the first 6 h in young and middle aged rats, but maxima for the old rats occurred in the second 6 h.

Vascular resistance in the rat during baseline, chronic total sleep deprivation, and recovery from total sleep deprivation.

Rats subjected to total sleep deprivation (TSD) by the disk-over-water method exhibit an elevated temperature set point, increased energy expenditure (EE), and increased circulating norepinephrine--all of which should militate for an increase in body temperature. Instead, after a small rise early in TSD, intraperitoneal temperature (T(ip)) fell progressively, indicating a reduced ability to retain body heat. To evaluate whether vasoconstrictor defenses against heat loss in the regions of major heat dissipation in the rat (hindpaws and tail) were impaired, peripheral vascular resistance (PVR) was calculated from aortic blood pressure (BP) and blood flow (BF) (BP and BF were continuously recorded at the aortic-iliac junction). TSD rats and their yoked control (TSC) rats were subjected to TSD for 10 to 22 days. As in earlier studies, TSD rats showed excessive heat loss indicated by a falling T(ip) (after an initial rise) while EE was elevated. Temperature set point was presumably raised throughout deprivation as shown previously. Although a small decline in PVR early in deprivation could have increased heat loss, there was no evidence of a massive vasodilation in the region examined which could, in itself, account for the progressive inability to retain heat over the course of TSD. In fact, PVR was near baseline levels during the latter half of TSD. Nevertheless, there was evidence of impaired vasoconstrictive defenses in TSD rats inasmuch as they showed significantly lower PVR than TSC rats during most of the deprivation period in spite of indications that they were farther below set point. It is not yet clear whether this impairment was a major determinant of the heat loss in TSD rats. A rapid PVR rebound during recovery suggested a release from a TSD-linked blockage of vasomotor compensation for excessive heat loss.

Age-related changes in sleep in the rat.

Human sleep in old age is characterized by a number of changes, including reductions in sleep efficiency, amounts of visually scored slow-wave and REM sleep, and amplitude of the diurnal sleep/wake rhythm. In older rats, some, but not all, of these traits have been reported, including a decrease in the mean duration of sleep bouts, an increase in the number of sleep bouts, and a modest reduction of REM sleep. Studies of the diurnal rhythm of total sleep have had varied results. There are, however, virtually no data indicating at what point across the rat's lifetime the changes seen in old age begin to occur. In order to more fully characterize sleep in older rats, and to develop data on when they first appear, we have examined sleep in young adult (3 months), middle-aged (12 months), and older (24 months) rats during 24 hours under constant dim light. Analyses of variance revealed no age-related changes in total sleep, NREM or REM sleep, wake time after sleep onset, or three different measures of the amplitude of the sleep/wake circadian rhythm. There were, however, significant age-related reductions in high-voltage NREM sleep ("HS2"), the mean length of sleep bouts, and REM-onset duration. These were seen in the 1-year-old rats, indicating that the changes seen in the older animals were evident by midlife.

Effects of method, duration, and sleep stage on rebounds from sleep deprivation in the rat.

Total sleep deprivation (TSD) of rats for 24 hours or less by continually enforced locomotion has consistently produced subsequent rebounds of slow-wave or high-amplitude EEG activity in NREM sleep, which has contributed to the widely held view that this EEG activity reflects particularly "intense" or restorative sleep. These rebounds usually have been accompanied by substantial rebounds of REM sleep. In contrast, chronic TSD (2 weeks or longer) by the disk-over-water (DOW) method has produced only huge, long-lasting rebounds of REM sleep with no rebound of high-amplitude NREM sleep. To evaluate whether the different rebounds result from different methods or from different lengths of deprivation, rats were subjected to 24-hour TSD by the DOW method. Rebounds included increases in high-amplitude and slow-wave activity; i.e., the methods produced similar rebound patterns following short-term TSD. (Chronic TSD by continually enforced locomotion would be strategically difficult and severely confounded with motor fatigue.) Rats subjected to DOW-TSD for 4 days, well before the development of severe TSD symptoms, showed primarily REM sleep rebounds. Rats subjected to 1 day of selective REM sleep deprivation, but not their closely yoked control rats, showed large, significant REM sleep rebounds, which evidently were not induced by the stress of the deprivation method per se. The combined findings prompted reexamination of published evidence relevant to "sleep intensity," including "negative rebounds," rebounds in other species, the effects of stress and fatigue, depth of sleep indicators, and extended sleep. The review points out pitfalls in the designation of any specific pattern as intense sleep.

EEG delta power during sleep in young and old rats.

Delta EEG power density, which has been viewed as a measure of intensity of NREM sleep, declines across the lifetime in humans, cats, and hamsters, but data in rats have been unclear. It is also uncertain whether older rats differ from younger animals in the degree of change in delta power during recovery sleep following short-term sleep deprivation. We have examined delta power density in NREM sleep under baseline conditions and following 48 h of sleep deprivation in young (3 months), middle-aged (12 months), and older (24 months) rats. The presence or absence of age effects was highly dependent on the method of normalizing the data. When expressed as a fraction of total NREM EEG power, there was no age effect on baseline delta power density, or on the change from baseline to recovery conditions. When expressed as a multiple of delta power in REM under the same condition, the younger rats had higher delta power density than the middle-aged and older rats. For all the ages combined, there was an increase in delta power density in the recovery condition. When examined by age, the younger rats (which started from a higher level of delta power density than the other groups) did not have an increase in delta during recovery; the middle-aged rats tended to, and the older rats (which started from lower baseline levels) significantly increased delta power density in the recovery condition. This suggests that the lower delta power seen during baseline in older rats is not due to decreased ability to generate delta activity.

Effects of paradoxical sleep deprivation on thermoregulation in the rat.

Rats were subjected to chronic paradoxical sleep deprivation (PSD) by the disk-over-water method to determine if they would develop the sustained increase in core (hypothalamic) temperature (T(hy)); elevated temperature setpoint (Tset); and the attenuation of the normal decline in core temperature during the transition from wake to sleep observed in rats subjected to total sleep deprivation (TSD). PSD rats did not show a significant elevation in T(hy). PSD rats and their yoked controls (PSC) were provided with a continuously available operant by which they could increase ambient temperature (Tamb). Change in Tset was assessed by evaluating operant behavior as a function of hypothalamic and intraperitoneal temperature (T(ip)). Unlike TSD rats, PSD and PSC rats maintained near-baseline Tamb at all T(hy) and T(ip) values throughout the deprivation, indicating no change in Tset. As deprivation progressed, PSD rats displayed an attenuation of the normal fall of T(hy) and T(ip) during the transition from wake to sleep. PSC rats did not. During the final quarter of survival time, T(ip) in PSD rats actually rose above waking values during the transition to NREM. These results indicate that PS loss may alter thermoregulation during sleep. It would appear that selective PSD is sufficient to attenuate the normal decline in T(hy) and T(ip) during NREM sleep, whereas NREM loss is required for elevations in T(hy) and Tset.

Effects of aging on sleep in the golden hamster.

The golden hamster (Mesocricetus auratus) has been a model organism for the study of circadian rhythmicity and, in particular, the effects of age on the circadian system. Surprisingly, nothing is known about the effects of advanced age on sleep in this species. As a first step in determining the effects of aging on sleep in the golden hamster, we recorded sleep for 24 hours in 12 young (3 months) and 18 old (17-18 months) golden hamsters entrained to a 14:10 light:dark (LD) cycle. Aged hamsters exhibited small but significant increases in overall NREM sleep time, primarily due to an increase in time the old animals spent in the NREM sleep state during the dark period relative to the young hamsters. There were no significant differences in REM sleep, median sleep episode length, or the number of arousals. The most striking differences between the sleep of young and old hamsters was in NREM delta (0.5-4 Hz) power per epoch. Old hamsters showed approximately 27% less (p=0.0004) delta power per NREM epoch than young hamsters. It is possible that increased NREM sleep time in the old hamsters may be a failed attempt to maintain cumulative delta power; ie, old hamsters may have more NREM sleep in order to make up for the lower intensity of their sleep. This decline in delta power with age parallels earlier findings in cats and humans, although has it not been previously reported in rodents.

Operant control of ambient temperature during sleep deprivation.

Rats subjected to total sleep deprivation (TSD) by the disk-over-water method were provided with a continuously available operant by which they could increase ambient temperature (T(amb)). TSD rats progressively increased operant responses for heat to 700% of baseline levels. During the last quarter of sleep deprivation, they maintained mean T(amb) at 9 degrees C above baseline and held T(amb) over 40 degrees C for 35% of the day. In contrast, yoked control rats (TSC) did not change mean T(amb). Although both TSD and TSC rats showed a progressive decline in intraperitoneal temperature (T(ip)), TSD rats maintained an elevated T(amb) even during periods when T(ip) and brain temperatures (T(br)) were above baseline levels. Thus these results confirm and extend earlier findings that rats subjected to TSD show an increase in temperature set point (T(set)). The earlier studies, which utilized short daily trials in a thermal gradient, demonstrated an increase in T(set) early in the deprivation period. The present study, which obtained more extensive data on thermal preference at a range of body temperatures demonstrated an increasing T(amb) for almost all T(ip) and T(br) values, suggesting a progressive increase in T(set) over the course of sleep deprivation. Surprisingly, survival time was shorter than in previous TSD studies. Reduced survival could not be attributed to differences in T(br), T(ip), energy expenditure, or sleep loss from previous studies.

Effect of extended sleep deprivation on tumor growth in rats.

To assess the effect of chronic sleep deprivation on host defense, we observed growth and regression of a subdermal allogenic carcinoma (Walker 256 rat tumor) in rats undergoing 10 days of total sleep deprivation (TSD rats), yoked stimulus control (TSC) rats that were partially sleep deprived, and home cage control (HCC) rats. Tumor size was measured daily. Integrated tumor size was smaller in TSD rats than in both TSC (P = 0.04) and HCC rats (P = 0.0003). Thus host defense against these tumors (as defined by reduction in tumor size) was improved by sleep deprivation. This improvement could be a nonspecific effect, e.g., tumor growth can be inhibited by a catabolic state (dietary restriction). TSD and TSC rats lost body weight, indicating a catabolic state. However, tumor size was not predicted by body weight change, but was predicted by change in sleep time (P = 0.02). Host defense enhancement could alternatively result from enhanced immune response. Early tumor size (5 days) was similar in the three groups, but peaked sooner in TSD rats than in both TSC (P = 0.05) and HCC rats (P = 0.01), leading to large differences in size later. Immune-suppressed rats also showed little difference from HCC rats in early growth but large differences later. Thus host defense in an in vivo model that manifests a systemic immune response can be enhanced by sleep deprivation with timing, which is consistent with an enhancement of the immune response.

Are physiological effects of sleep deprivation in the rat mediated by bacterial invasion?

Recent reports have indicated that rats subjected to total sleep deprivation (TSD) by the disk-over-water method and sacrificed when death appeared imminent showed aerobic bacteria in their blood. Yoked control rats did not. Extrapolating from these results, it has been suggested that the late body temperature declines and eventual deaths of TSD rats are caused by septicemia, and that other, earlier-appearing effects of TSD-including weight loss, increased energy expenditure, and regulation of temperature at a higher level-might be mediated by impaired host defenses against bacterial invasion. Three measures of aerobic bacterial invasion were used to evaluate these hypotheses: bacteremia, bacterial colonization in major organs of filtration (liver, kidney, and mesenteric lymph nodes), and adherence of bacteria to the cecal wall. Experiment 1 showed nonsignificant trends toward more bacterial invasion in 4-day TSD rats compared to yoked control rats and no relationship between the bacterial indicators and the early TSD effects. Experiment 2 showed that the elimination of aerobic bacterial infection by antibiotic treatment did not prevent the early TSD effects in 4-day TSD rats. Experiment 3 showed that the elimination of aerobic bacterial invasion in TSD rats did not eliminate the late temperature decline or the progression towards death. The results showed no significant evidence of aerobic bacterial invasion early in TSD and no indication that the major effects of TSD were dependent upon aerobic bacterial invasion.

Increased basal REM sleep but no difference in dark induction or light suppression of REM sleep in flinders rats with cholinergic supersensitivity.

Increased cholinergic sensitivity in the central nervous system has been postulated to account for some of the neuroendocrine abnormalities and sleep disturbances seen in human depressives. The Flinders Sensitive Line (FSL) rats, which exhibit increased sensitivity to cholinergic agents, have been shown to have REM sleep patterns similar to those seen in depressives, including shorter REM sleep latency and increased daily percentage of REM sleep. We studied the response of FSL and control rats to brief dark pulses administered during the normal light period (which are known to stimulate REM sleep in albino rats) and to brief light pulses during the normal dark period (which suppress REM sleep in albino rats) to determine whether these responses are affected by central cholinergic hypersensitivity. FSL rats showed REM sleep patterns indistinguishable from controls during light or dark pulses, which does not support the primary involvement of cholinergic systems in this mechanism of REM sleep regulation. We also examined REM and non-REM (NREM) sleep patterns in FSL rats and their controls to determine whether they show sleep continuity disturbances or decreased sleep intensity as seen in depression. In agreement with an earlier study, we found that FSL rats had more daily REM sleep and accumulated less NREM sleep between REM bouts than controls. Duration of NREM sleep bouts, total daily NREM sleep time, and EEG amplitude of NREM sleep did not differ between FSL and control rats, suggesting that the cholinergic abnormalities in FSL rats do not produce substantial NREM sleep changes.

Sleep deprivation in rats with preoptic/anterior hypothalamic lesions.

Chronic total sleep deprivation (TSD) of rats by the disk-over-water method reliably produces initial increases and subsequent decreases in waking intraperitoneal (Tip) and hypothalamic (Thy) temperatures, progressive increases in energy expenditure, skin lesions on the tail and plantar surfaces, debilitated appearance, and eventual death. We investigated the possible role of the preoptic/anterior hypothalamus (POAH) in the mediation of the TSD effects by comparing these effects in POAH-lesioned and unlesioned rats. Bilateral POAH lesions sufficient in size to impair homeothermic responses to changes in ambient temperature did not produce TSD-like temperature changes under baseline ambient temperatures of 28-29 degrees C, implying that the thermoregulatory changes produced by TSD do not result from impairment of the lesioned area. However, the possibility remains that the TSD effects are mediated by damage to POAH areas that were not lesioned. During TSD, lesioned and unlesioned rats showed similar progressive increases in energy expenditure, but the lesioned rats showed earlier, steeper, and eventually greater declines in Tip and Thy. This result suggests that in unlesioned rats the POAH may counter-regulate against, and thereby attenuate, the reduction in heat retention caused by TSD. This failure of regulation in lesioned rats is consistent with their impaired response to ambient temperature change and implies that, in unlesioned rats, some POAH thermoregulatory mechanisms continue to function normally during TSD. Lesioned rats did not show the characteristic TSD-induced early increases in Tip and Thy. This result could imply either that heat retention was so compromised that body temperatures did not rise in spite of a TSD-induced increases in thermoregulatory setpoint, or that the setpoint increase in unlesioned rats is POAH-mediated. Notwithstanding the greater Tip and Thy declines in lesioned rats, they survived the TSD procedure longer than the unlesioned rats, thus supporting previous indications that death did not result from hypothermia.

Sleep deprivation in the rat: XX. Differences in wake and sleep temperatures during recovery.

We examined the relationship between wake and sleep peritoneal temperature (T(ip)) during recovery from short-term (five rats, 5 days of deprivation) and long-term (nine rats, 14-21 days) total sleep deprivation (TSD). Mammalian body temperature normally declines in the passage from wakefulness to sleep. Recovery from TSD featured reductions of the typical wake-sleep T(ip) differences. Previous studies from our laboratory have shown that chronic TSD in the rat produces a progressive rise in energy production and an initial rise in wake T(ip), followed by a later fall in T(ip) to below baseline that becomes more acute as death becomes imminent. During recovery from both short-term TSD (wherein pre-recovery wake T(ip) was still above baseline) and long-term TSD (wherein pre-recovery wake T(ip) had fallen to below baseline), wake T(ip) and energy production quickly returned towards baseline. On the first recovery day, both short- and long-term TSD rats showed mean non-rapid eye movement (NREM) and paradoxical sleep (PS) T(ip) values that were slightly, although not significantly, above mean wake T(ip). In short-term TSD rats, wake-NREM and wake-PS T(ip) differences were reduced from baseline significantly (p < 0.0025) on the first recovery day and nonsignificantly on the remaining three recovery days. In long-term TSD rats, wake-NREM and wake-PS T(ip) differences were significantly (p < 0.001) reduced from baseline on the first four recovery day block. On the last four recovery day block, wake-sleep T(ip) differences tended to return toward baseline. Hypothalamic wake-sleep temperature differences in long-term TSD rats showed similar reductions during recovery. The reduction of wake-sleep temperature differences in recovery does not support either energy reduction or cooling functions for sleep.

Sleep deprivation in the rat by the disk-over-water method.

Chronic sleep deprivation may be required to reveal the most serious physiological consequences of sleep loss, but it usually requires strong stimulation which can obscure the interpretation of effects. The disk-over-water method permits chronic sleep deprivation of rats with gentle physical stimulation that can be equally applied to yoked control rats. A series of studies with this method has revealed little or no pathology in the control rats. The deprived rats show a reliable syndrome that includes temperature changes (which vary with the sleep stages that are lost); heat seeking behavior; increased food intake; weight loss; increased metabolic rate; increased plasma norepinephrine; decreased plasma thyroxine; an increased triiodothyronine-thyroxine ratio; and an increase of an enzyme which mediates thermogenesis by brown adipose tissue. The temperature changes are attributable to excessive heat loss and an elevated thermoregulatory setpoint, both of which increase thermoregulatory load, and the other changes are interpretable as responses to this increased load. This pattern indicates that sleep serves a thermoregulatory function in the rat. The sleep deprived rats also show stereotypic ulcerative and hyperkeratotic lesions localized to the tail and plantar surfaces of the paws, and they die within a matter of weeks; the mediation of these changes is unresolved.

Sleep deprivation in the rat: XIX. Effects of thyroxine administration.

Chronic total sleep deprivation (TSD) in the rat produces an initial elevation and then declining body temperatures, increasing metabolic rate and eventual death. Because TSD rats will engage in warming behavior, one hypothesis is that the metabolic increase is an unsuccessful attempt at warming to combat a lethal hypothermia. However, TSD rats also undergo weight loss and progressive deterioration of skin and fur, suggesting TSD-induced pathological catabolic activity, possibly secondary to increased metabolic rate, that could be lethal. To evaluate these alternatives, the metabolic rate of rats was increased by thyroxine (T4) treatment while subjecting them to TSD. Compared to TSD rats not given T4, they had higher metabolic rates, higher body temperatures and reduced warming behavior, but their survival period was 37% shorter. Thus, it is unlikely that hypothermia is the cause of death in TSD rats. Weight and appearance declined more rapidly in T4-treated rats, but at the same proportions of survival time, skin pathology and decline in appearance were less evident in T4-treated rats than in TSD rats not given T4. Thus, there is some doubt whether a general pathological catabolic process is the cause of death. It is also possible that a specific morbid process normally reversed by sleep was accelerated by T4 administration.

Sleep deprivation in the rat: XVIII. Regional brain levels of monoamines and their metabolites.

Several theories have linked sleep with change in monoamine activity. However, the use of sleep deprivation to show that changes in sleep generate changes in monoamines (directly or through feedback) has produced inconsistent results. To explore whether longer sleep deprivation, better documented sleep loss, more complete controls or regional brain analyses would produce clear sleep loss-induced change, eight rats were subjected to total sleep deprivation (TSD) by the disk-over-water method for 11-20 days and were guillotined along with yoked control (TSC) and home-cage control (HCC) rats. Brains were removed and dissected to obtain the caudate, frontal cortex, hippocampus, hypothalamus, midbrain and hindbrain (pons-medulla). Tissue sections were analyzed for concentrations of serotonin (5HT), its metabolite 5-hydroxyindoleacetic acid (5HIAA), dopamine (DA), its metabolite 3,4-dihydroxyphenylacetic acid (DOPAC), and either norepinephrine or, in the caudate section, the DA metabolite homovanillic acid. The ratios DOPAC/DA and 5HIAA/5HT, which under some conditions are indicators of turnover, were also calculated. Because sleep deprivation time varied across sets of TSD, TSC and HCC rats and not all eight sets were analyzed simultaneously, a repeated-measures ANOVA was performed within sets with HCC, TSC and TSD considered as successive levels of sleep deprivation treatment. In no case did TSD rats have significantly higher or lower values of amines, metabolites or ratios than both HCC and TSC rats. The most common outlying values were for TSC rats. Thus, these results failed to demonstrate sleep loss-induced regional changes in levels of major brain monoamines or their metabolites.(ABSTRACT TRUNCATED AT 250 WORDS)