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昼行性啮齿动物西伯利亚花鼠的睡眠脑电图频谱分析

Sleep EEG spectral analysis in a diurnal rodent: Eutamias sibiricus.

作者信息

Dijk D J, Daan S

机构信息

Department of Zoology, University of Groningen, The Netherlands.

出版信息

J Comp Physiol A. 1989;165(2):205-15. doi: 10.1007/BF00619195.

DOI:10.1007/BF00619195
PMID:2746549
Abstract
  1. Sleep was studied in the diurnal rodent Eutamias sibiricus, chronically implanted with EEG and EMG electrodes. Analysis of the distribution of wakefulness, nonrapid eye movement (NREM) sleep, and rapid eye movement (REM) sleep over the 24 h period (LD 12:12) showed that total sleep time was 27.5% of recording time during the 12 h light period and 74.4% during the 12 h dark period. Spectral analysis of the sleep EEG revealed a progressive decay in delta power density in NREM sleep during darkness. Power density of the higher frequencies increased at the end of darkness. Power density of the higher frequencies decreased and that of the lower frequencies increased during light. 2. Analysis of the distribution of vigilance states under three different photoperiods (LD 18:6; 12:12; 6:18) revealed that changes in daylength mainly resulted in a redistribution of sleep and wakefulness over light and darkness. Under long days the percentage of sleep during light was enhanced. The time course of delta power density in NREM sleep was characterized by a long rising part and a short falling part under long days, while a reversed picture emerged under short days. As a consequence, the power density during days. As a consequence, the power density during light was relatively high under long days. 3. After 24 h sleep deprivation by forced activity, no significant changes in the percentages of wakefulness and NREM were observed, whereas REM sleep was slightly enhanced. EEG power density, however, was significantly increased by ca. 50% in the 1.25-10.0 Hz range in the first 3 h of recovery sleep. This increase gradually decayed over the recovery night. 4. The same 24 h sleep deprivation technique led to a ca. 25% increase in oxygen consumption during recovery nights. While the results of the EEG spectral analysis are compatible with the hypothesis that delta power density reflects the 'intensity' of NREM sleep as enhanced by prior wakefulness and reduced by prior sleep, such enhanced sleep depth after sleep deprivation is not associated with reduced energy expenditure as might be anticipated by some energy conservation hypotheses on sleep function.
摘要
  1. 在昼行性啮齿动物西伯利亚花鼠中进行睡眠研究,该动物长期植入了脑电图(EEG)和肌电图(EMG)电极。对24小时周期(光照12小时:黑暗12小时,LD 12:12)内觉醒、非快速眼动(NREM)睡眠和快速眼动(REM)睡眠的分布分析表明,在12小时光照期,总睡眠时间占记录时间的27.5%,而在12小时黑暗期则占74.4%。对睡眠脑电图的频谱分析显示,在黑暗期间,NREM睡眠中δ波功率密度逐渐下降。在黑暗结束时,高频功率密度增加。在光照期间,高频功率密度下降,低频功率密度增加。2. 对三种不同光周期(LD 18:6;12:12;6:18)下的警觉状态分布进行分析发现,日照长度的变化主要导致睡眠和觉醒在光照和黑暗之间重新分配。在长日照条件下,光照期间的睡眠百分比增加。在长日照条件下,NREM睡眠中δ波功率密度的时间进程特点是上升部分长、下降部分短,而在短日照条件下则出现相反的情况。因此,在长日照条件下,光照期间的功率密度相对较高。3. 通过强制活动剥夺24小时睡眠后,未观察到觉醒和NREM睡眠百分比有显著变化,而REM睡眠略有增加。然而,在恢复睡眠的前3小时内,脑电图功率密度在1.25 - 10.0赫兹范围内显著增加了约50%。这种增加在恢复夜间逐渐衰减。4. 相同的24小时睡眠剥夺技术导致恢复夜间的耗氧量增加约25%。虽然脑电图频谱分析结果与以下假设相符:δ波功率密度反映了NREM睡眠的“强度”,该强度因先前的觉醒而增强,因先前的睡眠而降低,但睡眠剥夺后这种增强的睡眠深度与一些关于睡眠功能的能量守恒假设所预期的能量消耗减少无关。

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