PER3 polymorphism and cardiac autonomic control: effects of sleep debt and circadian phase

A variable number tandem repeat polymorphism in the coding region of the circadian clock PERIOD3 ( PER3) gene has been shown to affect sleep. Because circadian rhythms and sleep are known to modulate sympathovagal balance, we investigated whether homozygosity for this PER3 polymorphism is associated with changes in autonomic nervous system (ANS) activity during sleep and wakefulness at baseline and after sleep deprivation. Twenty-two healthy participants were selected according to their PER3 genotype. ANS activity, evaluated by heart rate (HR) and HR variability (HRV) indexes, was quantified during baseline sleep, a 40-h period of wakefulness, and recovery sleep. Sleep deprivation induced an increase in slow-wave sleep (SWS), a decrease in the global variability, and an unbalance of the ANS with a loss of parasympathetic predominance and an increase in sympathetic activity. Individuals homozygous for the longer allele ( PER3 5/5) had more SWS, an elevated sympathetic predominance, and a reduction of parasympathetic activity compared with PER3 4/4, in particular during baseline sleep. The effects of genotype were strongest during non-rapid eye movement (NREM) sleep and absent or much smaller during REM sleep. The NREM-REM cycle-dependent modulation of the low frequency-to-(low frequency + high frequency) ratio was diminished in PER3 5/5 individuals. Circadian phase modulated HR and HRV, but no interaction with genotype was observed. In conclusion, the PER3 polymorphism affects the sympathovagal balance in cardiac control in NREM sleep similar to the effect of sleep deprivation.

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Autonomic Modulation During Baseline and Recovery Sleep in Adult Sleepwalkers

Frontiers in Neurology ◽

10.3389/fneur.2021.680596 ◽

2021 ◽

Vol 12 ◽

Author(s):

Geneviève Scavone ◽

Andrée-Ann Baril ◽

Jacques Montplaisir ◽

Julie Carrier ◽

Alex Desautels ◽

...

Keyword(s):

Heart Rate ◽

Sleep Deprivation ◽

Slow Wave ◽

Slow Wave Sleep ◽

Low Frequency ◽

Medium Effect ◽

Sleep Cycle ◽

Autonomic Modulation ◽

Decomposition Group ◽

Recovery Sleep

Sleepwalking has been conceptualized as deregulation between slow-wave sleep and arousal, with its occurrence in predisposed patients increasing following sleep deprivation. Recent evidence showed autonomic changes before arousals and somnambulistic episodes, suggesting that autonomic dysfunctions may contribute to the pathophysiology of sleepwalking. We investigated cardiac autonomic modulation during slow-wave sleep in sleepwalkers and controls during normal and recovery sleep following sleep deprivation. Fourteen adult sleepwalkers (5M; 28.1 ± 5.8 years) and 14 sex- and age-matched normal controls were evaluated by video-polysomnography for one baseline night and during recovery sleep following 25 h of sleep deprivation. Autonomic modulation was investigated with heart rate variability during participants' slow-wave sleep in their first and second sleep cycles. 5-min electrocardiographic segments from slow-wave sleep were analyzed to investigate low-frequency (LF) and high-frequency (HF) components of heart rate spectral decomposition. Group (sleepwalkers, controls) X condition (baseline, recovery) ANOVAs were performed to compare LF and HF in absolute and normalized units (nLF and nHF), and LF/HF ratio. When compared to controls, sleepwalkers' recovery slow-wave sleep showed lower LF/HF ratio and higher nHF during the first sleep cycle. In fact, compared to baseline recordings, sleepwalkers, but not controls, showed a significant decrease in nLF and LF/HF ratio as well as increased nHF during recovery slow-wave sleep during the first cycle. Although non-significant, similar findings with medium effect sizes were observed for absolute values (LF, HF). Patterns of autonomic modulation during sleepwalkers' recovery slow-wave sleep suggest parasympathetic dominance as compared to baseline sleep values and to controls. This parasympathetic predominance may be a marker of abnormal neural mechanisms underlying, or interfere with, the arousal processes and contribute to the pathophysiology of sleepwalking.

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Sleep after arousal from hibernation is not homeostatically regulated

AJP Regulatory Integrative and Comparative Physiology ◽

10.1152/ajpregu.1999.276.2.r522 ◽

1999 ◽

Vol 276 (2) ◽

pp. R522-R529 ◽

Cited By ~ 10

Author(s):

Jennie E. Larkin ◽

H. Craig Heller

Keyword(s):

Sleep Deprivation ◽

Brain Function ◽

Extended Period ◽

Nrem Sleep ◽

Wave Activity ◽

Ground Squirrels ◽

Recovery Sleep ◽

Sleep Homeostasis ◽

Homeostatic Response ◽

Periodic Arousals

Electroencephalographic slow-wave activity (SWA) in non-rapid eye movement (NREM) sleep is directly related to prior sleep/wake history, with high levels of SWA following extended periods of wake. Therefore, SWA has been thought to reflect the level of accumulated sleep need. The discovery that euthermic intervals between hibernation bouts are spent primarily in sleep and that this sleep is characterized by high and monotonically declining SWA has led to speculation that sleep homeostasis may play a fundamental role in the regulation of the timing of bouts of hibernation and periodic arousals to euthermia. It was proposed that because the SWA profile seen after arousal from hibernation is strikingly similar to what is seen in nonhibernating mammals after extended periods of wakefulness, that hibernating mammals may arouse from hibernation with significant accumulated sleep need. This sleep need may accumulate during hibernation because the low brain temperatures during hibernation may not be compatible with sleep restorative processes. In the present study, golden-mantled ground squirrels were sleep deprived during the first 4 h of interbout euthermia by injection of caffeine (20 mg/kg ip). We predicted that if the SWA peaks after bouts of hibernation reflected a homeostatic response to an accumulated sleep need, sleep deprivation should simply have displaced and possibly augmented the SWA to subsequent recovery sleep. Instead we found that after caffeine-induced sleep deprivation of animals just aroused from hibernation, the anticipated high SWA typical of recovery sleep did not occur. Similar results were found in a study that induced sleep deprivation by gentle handling (19). These findings indicate that the SWA peak immediately after hibernation does not represent homeostatic regulation of NREM sleep, as it normally does after prolonged wakefulness during euthermia, but instead may reflect some other neurological process in the recovery of brain function from an extended period at low temperature.

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Sleep regulation in rats: effects of sleep deprivation, light, and circadian phase

AJP Regulatory Integrative and Comparative Physiology ◽

10.1152/ajpregu.1986.251.6.r1037 ◽

1986 ◽

Vol 251 (6) ◽

pp. R1037-R1044 ◽

Cited By ~ 8

Author(s):

L. Trachsel ◽

I. Tobler ◽

A. A. Borbely

Keyword(s):

Sleep Deprivation ◽

Slow Wave Sleep ◽

Rest Period ◽

Activity Period ◽

Base Line ◽

Sleep Regulation ◽

Continuous Darkness ◽

Circadian Phase ◽

Sleep Homeostasis ◽

Pentobarbital Sodium Anesthesia

Sleep states and electroencephalographic (EEG) parameters were determined in unrestrained rats that had been implanted with electrodes under deep pentobarbital sodium anesthesia. Two base-line days with a light-dark cycle (LD) and 2 days under continuous darkness (DD) were followed by 24 h of sleep deprivation (SD) ending in the middle of the circadian activity period and by 2 recovery days in DD. In the base-line LD rest period, the amount of rapid-eye-movement sleep (REMS) and the EEG amplitude of non-REMS (NREMS) were lower than in the corresponding DD period. SD caused an immediate enhancement of REMS, NREMS, the slow-wave sleep (SWS) fraction of NREMS, and NREMS EEG amplitude. Although REMS, NREMS, and SWS showed a second peak at habitual light onset, they did not exceed base line. Subsequently, all parameters exhibited a marked negative rebound. We conclude that REMS and the EEG amplitude of NREMS are suppressed by light, amplitude and frequency parameters of NREMS are differently affected by light as well as by SD, and the short duration of the SD-induced increase of SWS may reflect a circadian influence on sleep homeostasis.

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Assessment of effects of total sleep deprivation and subsequent recovery sleep: a methodological strategy feasible without sleep laboratory

BMC Psychology ◽

10.1186/s40359-021-00641-3 ◽

2021 ◽

Vol 9 (1) ◽

Author(s):

Cindy Stroemel-Scheder ◽

Stefan Lautenbacher

Keyword(s):

Sleep Deprivation ◽

Slow Wave Sleep ◽

Successful Implementation ◽

Experimental Protocol ◽

Subsequent Recovery ◽

Total Sleep Deprivation ◽

Recovery Sleep ◽

Sleep Parameters ◽

Sleep Laboratories ◽

At Home

Abstract Background Sleep is critical for maintaining homeostasis in bodily and neurobehavioral functions. This homeostasis can be disturbed by sleep interruption and restored to normal by subsequent recovery sleep. Most research regarding recovery sleep (RS) effects has been conducted in specialized sleep laboratories, whereas small, less-well equipped research units may lack the possibilities to run studies in this area. Hence, the aims of the present study were to develop and validate an experimental protocol, which allows a thorough assessment of at-home recovery sleep after sleep deprivation. Methods The experimental protocol, comprising one night of baseline sleep (BL) at home, one night of monitored total sleep deprivation and a subsequent recovery night at home, was tested in a sample of 30 healthy participants. Subjects’ fatigue and alertness were assessed prior to and after each night. Sleep at home (BL, RS) was objectively assessed using portable polysomnography. To check whether our at-home sleep assessments yielded results that are comparable to those conducted in sleep laboratories, we compared the sleep data assessed in our study with sleep data assessed in laboratory studies. Results Sleep parameters assessed during RS exhibited changes as expected (prolonged total sleep time, better sleep efficiency, slow wave sleep rebound). Sleep parameters of BL and RS were in line with parameters assessed in previous studies examining sleep in a laboratory setting. Fatigue normalized after one night of RS; alertness partly recovered. Conclusions Our results suggest a successful implementation of our new experimental protocol, emphasizing it as a useful tool for future studies on RS outside of well-equipped sleep laboratories.

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008 ARC Genotype Modulates Slow Wave Sleep Following Total Sleep Deprivation

SLEEP ◽

10.1093/sleep/zsab072.007 ◽

2021 ◽

Vol 44 (Supplement_2) ◽

pp. A4-A4

Author(s):

Brieann Satterfield ◽

Darian Lawrence-Sidebottom ◽

Michelle Schmidt ◽

Jonathan Wisor ◽

Hans Van Dongen

Keyword(s):

Individual Differences ◽

Sleep Deprivation ◽

Slow Wave ◽

Molecular Mechanisms ◽

Slow Wave Sleep ◽

Early Gene ◽

Total Sleep Deprivation ◽

Recovery Sleep ◽

Sleep Homeostasis ◽

Arc Gene

Abstract Introduction The activity-regulated cytoskeleton associated protein (ARC) gene is an immediate early gene that is involved in synaptic plasticity. Recent evidence from a rodent model suggests that Arc may also be involved in sleep homeostasis. However, little is known about the molecular mechanisms regulating the sleep homeostat. In humans, sleep homeostasis is manifested by a marked increase in slow wave sleep (SWS) following acute total sleep deprivation (TSD). There are large, trait individual differences in the magnitude of this SWS rebound effect. We sought to determine whether a single nucleotide polymorphism (SNP) of the ARC gene is associated with individual differences in SWS rebound following TSD. Methods 64 healthy normal sleepers (ages 27.2 ± 4.8y; 32 females) participated in one of two in-laboratory TSD studies. In each study, subjects had a baseline day with 10h sleep opportunity (TIB 22:00–08:00) which was followed by 38h TSD. The studies concluded with 10h recovery sleep opportunity (TIB 22:00–08:00). Baseline and recovery sleep were recorded polysomnographically and scored visually by a trained technician. Genomic DNA was extracted from whole blood. The ARC c.*742 + 58C>T non-coding SNP, rs35900184, was assayed using real-time PCR. Heterozygotes and T/T homozygotes were combined for analysis. The genotype effect on time in SWS was assessed using mixed-effects ANOVA with fixed effects for ARC genotype (C/C vs. T carriers), night (baseline vs. recovery), and their interaction, controlling for study. Results The genotype distribution in this sample – C/C: 41; C/T: 17; T/T: 6 – did not vary significantly from Hardy-Weinberg equilibrium. There was a significant interaction between ARC genotype and night (F1,62=7.27, p=0.009). Following TSD, T allele carriers exhibited 47.6min more SWS compared to baseline, whereas C/C homozygotes exhibited 62.3min more SWS compared to baseline. There was no significant difference in SWS between genotypes at baseline (F1,61=0.69, p=0.41). Conclusion ARC T allele carriers exhibited an attenuated SWS rebound following TSD compared to those homozygous for the C allele. This suggests that the ARC SNP is associated with trait individual differences related to sleep homeostasis, and may thus influence molecular mechanisms involved in long-term memory. Support (if any) ONR N00014-13-1-0302, NIH R21CA167691, and USAMRDC W81XWH-18-1-0100.

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Galanin neurons in the hypothalamus link sleep homeostasis, body temperature and actions of the α2 adrenergic agonist dexmedetomidine

10.1101/565747 ◽

2019 ◽

Cited By ~ 1

Author(s):

Ying Ma ◽

Giulia Miracca ◽

Xiao Yu ◽

Edward C. Harding ◽

Andawei Miao ◽

...

Keyword(s):

Body Temperature ◽

Sleep Deprivation ◽

Core Body Temperature ◽

Neuronal Cell ◽

Nrem Sleep ◽

Temperature Characteristic ◽

Adrenergic Agonist ◽

Delta Power ◽

Recovery Sleep ◽

Sleep Homeostasis

AbstractSleep deprivation induces a characteristic rebound in NREM sleep accompanied by an immediate increase in the power of delta (0.5 - 4 Hz) oscillations, proportional to the prior time awake. To test the idea that galanin neurons in the mouse lateral preoptic hypothalamus (LPO) regulate this sleep homeostasis, they were selectively genetically ablated. The baseline sleep architecture of LPO-ΔGal mice became heavily fragmented, their average core body temperature permanently increased (by about 2°C) and the diurnal variations in body temperature across the sleep-wake cycle also markedly increased. Additionally, LPO-ΔGal mice showed a striking spike in body temperature and increase in wakefulness at a time (ZT24) when control mice were experiencing the opposite - a decrease in body temperature and becoming maximally sleepy (start of “lights on”). After sleep deprivation sleep homeostasis was largely abolished in LPO-ΔGal mice: the characteristic increase in the delta power of NREM sleep following sleep deprivation was absent, suggesting that LPO galanin neurons track the time spent awake. Moreover, the amount of recovery sleep was substantially reduced over the following hours. We also found that the α2 adrenergic agonist dexmedetomidine, used for long-term sedation during intensive care, requires LPO galanin neurons to induce both the NREM-like state with increased delta power and the reduction in body temperature, characteristic features of this drug. This suggests that dexmedetomidine over-activates the natural sleep homeostasis pathway via galanin neurons. Collectively, the results emphasize that NREM sleep and the concurrent reduction in body temperature are entwined at the circuit level.SignificanceCatching up on lost sleep (sleep homeostasis) is a common phenomenon in mammals, but there is no circuit explanation for how this occurs. We have discovered that galanin neurons in the hypothalamus are essential for sleep homeostasis as well as for the control of body temperature. This is the first time that a neuronal cell type has been identified that underlies sleep homeostasis. Moreover, we show that activation of these galanin neurons are also essential for the actions of the α2 adrenergic agonist dexmedetomidine, which induces both hypothermia together with powerful delta oscillations resembling NREM sleep. Thus, sleep homeostasis, temperature control and sedation by α2 adrenergic agonists can all be linked at the circuit level by hypothalamic galanin neurons.

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Time course of EEG power density during long sleep in humans

AJP Regulatory Integrative and Comparative Physiology ◽

10.1152/ajpregu.1990.258.3.r650 ◽

1990 ◽

Vol 258 (3) ◽

pp. R650-R661 ◽

Cited By ~ 10

Author(s):

D. J. Dijk ◽

D. P. Brunner ◽

A. A. Borbely

Keyword(s):

Slow Wave ◽

Process Model ◽

Time Course ◽

Slow Wave Sleep ◽

Nrem Sleep ◽

Sleep Stages ◽

Base Line ◽

Sleep Regulation ◽

Recovery Sleep ◽

Electroencephalogram Eeg

In nine subjects sleep was recorded under base-line conditions with a habitual bedtime (prior wakefulness 16 h; lights off at 2300 h) and during recovery from sleep deprivation with a phase-advanced bedtime (prior wakefulness 36 h; lights off at 1900 h). The duration of phase-advanced recovery sleep was greater than 12 h in all subjects. Spectral analysis of the sleep electroencephalogram (EEG) revealed that slow-wave activity (SWA; 0.75-4.5 Hz) in non-rapid-eye-movement (NREM) sleep was significantly enhanced during the first two NREM-REM sleep cycles of displaced recovery sleep. The sleep stages 3 and 4 (slow-wave sleep) and SWA decreased monotonically over the first three and four NREM-REM cycles of, respectively, base-line and recovery sleep. The time course of SWA in base-line and recovery sleep could be adequately described by an exponentially declining function with a horizontal asymptote. The results are in accordance with the two-process model of sleep regulation in which it is assumed that SWA rises as a function of the duration of prior wakefulness and decreases exponentially as a function of prior sleep. We conclude that the present data do not provide evidence for a 12.5-h sleep-dependent rhythm of deep NREM sleep.

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A human sleep homeostasis phenotype in mice expressing a primate‐specific PER3 variable‐number tandem‐repeat coding‐region polymorphism

The FASEB Journal ◽

10.1096/fj.13-240135 ◽

2014 ◽

Vol 28 (6) ◽

pp. 2441-2454 ◽

Cited By ~ 21

Author(s):

Sibah Hasan ◽

Daan R. Veen ◽

Raphaelle Winsky‐Sommerer ◽

Alexandra Hogben ◽

Emma E. Laing ◽

...

Keyword(s):

Tandem Repeat ◽

Variable Number Tandem Repeat ◽

Variable Number ◽

Coding Region ◽

Human Sleep ◽

Sleep Homeostasis

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Natural hypothermia and sleep deprivation: common effects on recovery sleep in the Djungarian hamster

AJP Regulatory Integrative and Comparative Physiology ◽

10.1152/ajpregu.1996.271.5.r1364 ◽

1996 ◽

Vol 271 (5) ◽

pp. R1364-R1371 ◽

Cited By ~ 6

Author(s):

T. Deboer ◽

I. Tobler

Keyword(s):

Sleep Deprivation ◽

Brain Temperature ◽

Alternative Hypothesis ◽

Nrem Sleep ◽

Wave Activity ◽

Daily Torpor ◽

Djungarian Hamster ◽

Subsequent Increase ◽

Recovery Sleep ◽

Sleep Debt

Sleep, daily torpor, and hibernation have been considered to be homologous processes. However, in the Djungarian hamster, daily torpor is followed by an increase in slow-wave activity (SWA; electroencephalogram power density 0.75-4.0 Hz) that is similar to the increase observed after sleep deprivation. A positive correlation was found between torpor episode length and the subsequent increase in SWA, which was highest when SWA was assumed to increase with a saturating exponential function. Thus the increase in SWA propensity during daily torpor followed similar kinetics as during waking, supporting the hypothesis that when the animal is in torpor it is incurring a sleep debt. An alternative hypothesis, proposing that the mode of arousal causes the subsequent SWA increase, was tested by warming the animals during emergence from daily torpor. Irrespective of mode of arousal, more non-rapid eye movement (NREM) sleep and a similar SWA increase was found after torpor. The data are compatible with a putative neuronal restorative function for sleep associated with the expression of SWA in NREM sleep. During torpor, when brain temperature is low, this function is inhibited, whereas the need for restoration accumulates. Recovery takes place only after return to euthermia.

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Effect of cognitive load and emotional valence of distractors on performance during sleep extension and subsequent sleep deprivation

SLEEP ◽

10.1093/sleep/zsaa013 ◽

2020 ◽

Vol 43 (8) ◽

Author(s):

Sara E Alger ◽

Allison J Brager ◽

Thomas J Balkin ◽

Vincent F Capaldi ◽

Guido Simonelli

Keyword(s):

Sleep Deprivation ◽

Cognitive Load ◽

Slow Wave Sleep ◽

Emotional Valence ◽

Extension Phase ◽

Total Sleep Deprivation ◽

Impaired Performance ◽

Recovery Sleep ◽

Sleep Debt ◽

Sleep Extension

Abstract Study Objectives The purpose of the present study was to assess the extent to which sleep extension followed by sleep deprivation impacts performance on an attentional task with varying cognitive and attentional demands that influence decisions. Methods Task performance was assessed at baseline, after 1 week of sleep extension, and after 40 h of total sleep deprivation. Results One week of sleep extension resulted in improved performance, particularly for high cognitive load decisions regardless of the emotional salience of attentional distractors. Those who extended sleep the most relative to their habitual sleep duration showed the greatest improvement in general performance during sleep extension. However, a higher percentage of time spent in slow-wave sleep (SWS) on the last night of the sleep extension phase was negatively correlated with performance on more difficult high cognitive load items, possibly reflecting a relatively higher level of residual sleep need. Sleep deprivation generally resulted in impaired performance, with a nonsignificant trend toward greater performance decrements in the presence of emotionally salient distractors. Performance overall, but specifically for high cognitive load decisions, during total sleep deprivation was negatively correlated with longer sleep and higher SWS percentage during subsequent recovery sleep. Conclusions The present findings suggest two possibilities: those who performed relatively poorly during sleep deprivation were more vulnerable because (1) they utilized mental resources (i.e. accrued sleep debt) at a relatively faster rate during wakefulness, and/or (2) they failed to “pay down” pre-study sleep debt to the same extent as better-performing participants during the preceding sleep extension phase.

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