NO对大鼠睡眠-觉醒的调节

目的和方法：通过对大鼠侧脑室微量注射ＮＯＳ抑制剂Ｌ－ＮＡＭＥ及ＮＯ的前体Ｌ－精氨酸（Ｌ－Ａｒｇ）观察两种物质对大鼠睡眠－觉醒的影响。结果：注射１ｍｇ Ｌ－ＮＡＭＥ（５μＬ）后４ｈ觉醒（Ｗ）明显增加,尤以注射后第１￣２ｈ显著;４ｈ慢波睡眠（ＳＷＳ）明显减少,该效应同样以注射后第１￣２ｈ显著;异相睡眠（ＰＳ）无明显变化。小剂量Ｌ－ＮＡＭＥ（０．２ｍｇ,５μｌ）对大鼠的Ｗ、ＳＷＳ、ＰＳ无明显影响;同样方     

腺苷和睡眠觉醒调节

腺苷作为神经调质,调节多种神经生物学功能.随觉醒时间延长,动物脑内腺苷水平逐渐增高,在睡眠期显著降低.因此,腺苷被认为是调节睡眠的内稳态因子之一.腺苷受体(receptor,R)有A1R、A2AR、A2BR和A3R四种亚型,其中A1R和A2AR与诱导睡眠相关.激活A1R可抑制促觉醒神经元诱导睡眠,也可抑制促眠神经元导致...     

大鼠中脑腹侧被盖区在睡眠—觉醒调节中的作用

本实验在３１只清醒自由行动的雄性ＳＤ大鼠进行。结果如下：（１）以侧中脑腹侧被盖区（ＶＴＡ）微量注射３．３ｎｍｏｌ溴亭后第２－３ｈ觉醒时间显著增加（Ｐ＜０．０１）;６．６ｎｍｏｌ溴隐亭有类似效果;０．６６和１．３３ｎｍｏｌ溴隐亭无明显作用。（２）同样方法ＶＴＡ微量注射２ｎｍｏｌ和４ｎｍｏｌＳＣＨ２３３９０后第２－３ｈ觉醒时间明显减少（分别为Ｐ＜０．０１和Ｐ＜０．０５）,但注射３．４ｎｍｏｌ舒必利则无     

昼夜节律系统与成人昼夜节律睡眠觉醒障碍

昼夜节律是存在于所有生命体中、接近24小时的内源性生物节律。昼夜节律与社会或环境节律的长期不同步,会引起睡眠、情绪等一系列变化。本文阐述了昼夜节律系统与睡眠之间的联系,重点介绍成人昼夜节律睡眠觉醒障碍疾病的临床研究成果,以期加强临床医生对该病的认识和诊治。     

家兔半慢性“孤立脑”制备的睡眠-觉醒周期

高位胸髓横断(T_1或 T_2)和切断双侧臂丛的“孤立脑”家兔可以长期维持自主腹式呼吸。此制备的睡眠-觉醒周期可明确地分为四个时相,即觉醒期、慢波浅醒期、慢波深睡期和快眼动睡眠期。与正常家兔的睡眠周期相比,此制备的周期持续时间大为缩短,深睡期和快眼动睡眠期明显减少。     

基底外侧杏仁核对睡眠-觉醒的调节作用

采用多道睡眠描记方法,观察了基底外侧杏仁核在睡眠－觉醒调节中的作用。结果发现,电损毁双侧ＢＬＮ引起慢波睡眠和快波睡眠增加,觉醒减少;在双侧ＢＬＮ内注射选择性损毁神经元胸体剂量的红藻氨酸引起双相效应,注射ＫＡ后第１天出现失眠,自第３天开始,ＳＷＳ增多,Ｗ减少,但ＰＳ无显著变化。     

下丘脑hypocretin神经元协调睡眠-觉醒功能

哺乳动物的生活实际上是由睡眠与觉醒、休息与活动、镇静与警戒组成的。上世纪早期的研究预示了在下丘脑后部有一促觉醒区 ,目前神经科学家已证实了上述预测。下丘脑的hypocretin(也称为orexin)神经元对于觉醒系统的调节起着决定性作用 ,该神经元的活动能使睡意减少 ,同时提高觉醒和警戒。Hypocretin神经元分泌兴奋性神经递质hypocretin 1和hypocretin 2 ,投射到参与睡眠 觉醒机制的脑干 ,脑干的这些结构各有自己主要的神经递质 (如缝核的 5 羟色胺、蓝斑的去甲肾上腺素、背侧被盖的乙酰胆碱、乳头结节核的组胺、内侧隔核与斜角带核的γ …     

侧脑室注射促甲状腺激素释放激素对大鼠睡眠—觉醒的影响

采用多导睡眠描记术研究了例脑室注射促甲状腺激素释放激素(TRH)对正常大鼠和去甲状腺大鼠睡眠-觉醒的影响。在正常大鼠,TRH引起觉醒增加,浅慢波睡眠(SWS_1)、深慢波睡眠(SWS_2)和总睡眠时间(TST)均减少,异相睡眠(PS)消失,SWS_1、SWS_2和PS的潜伏期均显著延长,给药后立即产生效应并在1h内达高峰。去甲状腺对大鼠的睡眠-觉醒无明显影响,注射TRH后引起的效应与正常大鼠相似。结果提示TRH有促进大鼠觉醒的作用,对各睡眠时相均有抑制作用,其作用部位可能在下丘脑以外的中枢结构。     

膝状体间小叶调节睡眠-觉醒节律

膝状体间小叶(intergeniculate leaflet,IGL)是丘脑内的一条状狭窄核团,核团富含γ-氨基丁酸(gamma-aminobutyric acid,GABA)、神经肽Y(neuropeptide Y,NPY)及脑啡肽(enkephalin,ENK)等神经递质,主要参与哺乳动物的生物节律,光信号和非光信号在IGL的整合突出了其在生物节律的重要地位。以往诸多研究发现IGL与昼夜节律调节核团之间形成广泛的纤维投射,是外界授时因子调节哺乳动物生物节律的重要一环,同时该核团与睡眠觉醒和视觉运动系统相关核团也存在广泛的信号传导。本文结合IGL的相关国内外研究,分析IGL核团解剖特点,从睡眠-觉醒角度探讨昼夜节律核团IGL在睡眠生理活动中的调节作用。     

腹侧被盖区DA神经元调节睡眠—觉醒机制的探讨

本实验观察了微量注射γ－氨基丁酸（ＧＡＢＡ）和５－羟色胺（５－ＨＴ）于大鼠中脑腹侧被盖区（ＶＴＡ）对该部位多巴胺神经元活动的调节及其对睡眠觉醒的影响。实验观察到：ＶＴＡ注射ＧＡＢＡ（２５μｇ）和５－ＨＴ（２μｇ）,伏隔核（Ａｃｂ）内多巴胺（ＤＡ）代谢产物－双羟苯乙酸（ＤＯＰＡＣ）分别降低到注射前的６８．２％（Ｐ〈０．０１）和升高到１３６．１％（Ｐ〈０．０１）,并相应减少和增加觉醒。双侧Ａｃｂ注射Ｄ     

Ciclograma: a tool for detection of rhythmicities in sleep/wake cycles

The Fourier spectral analysis of binary time series (or rectangular signals) causes methodological problems, due to the fact that it is based on sinusoidal functions. We propose a new tool for the detection of periodicities in binary time series, focusing on sleep/wake cycles. This methodology is based on a weighted histogram of cycle durations. In this paper, we compare our methodology with the Fourier spectral analysis on the basis of simulated and real binary data sets of various lengths. We also provide an approach to statistical validation of the periodicities determined with our methodology. Furthermore, we analyze the discriminating power of both methods in terms of standard deviation. Our results indicate that the Ciclograma is much more powerful than Fourier analysis when applied on this type of time series.     

Uncovering physiologic mechanisms of circadian rhythms and sleep/wake regulation through mathematical modeling

Mathematical models of neurobehavioral function are useful both for understanding the underlying physiology and for predicting the effects of rest-activity-work schedules and interventions on neurobehavioral function. In a symposium titled "Modeling Human Neurobehavioral Performance I: Uncovering Physiologic Mechanisms" at the 2006 Society for Industrial and Applied Mathematics/Society for Mathematical Biology (SIAM/SMB) Conference on the Life Sciences, different approaches to modeling the physiology of human circadian rhythms, sleep, and neurobehavioral performance and their usefulness in understanding the underlying physiology were examined. The topics included key elements of the physiology that should be included in mathematical models, a computational model developed within a cognitive architecture that has begun to include the effects of extended wake on information-processing mechanisms that influence neurobehavioral function, how to deal with interindividual differences in the prediction of neurobehavioral function, the applications of systems biology and control theory to the study of circadian rhythms, and comparisons of these methods in approaching the overarching questions of the underlying physiology and mathematical models of circadian rhythms and neurobehavioral function. A unifying theme was that it is important to have strong collaborative ties between experimental investigators and mathematical modelers, both for the design and conduct of experiments and for continued development of the models.     

Expression of clock genes in human peripheral blood mononuclear cells throughout the sleep/wake and circadian cycles

The rhythmic expression of circadian clock genes in the neurons of the suprachiasmatic nucleus (SCN) underlies the manifestation of endogenous circadian rhythmicity in behavior and physiology. Recent evidence demonstrating rhythmic clock gene expression in non-SCN tissues suggests that functional clocks exist outside the central circadian pacemaker of the brain. In this investigation, the nature of an oscillator in peripheral blood mononuclear cells (PBMCs) is evaluated by assessing clock gene expression throughout both a typical sleep/wake cycle (LD) and during a constant routine (CR). Six healthy men and women aged (mean±SEM) 23.7±1.6 yrs participated in this five-day investigation in temporal isolation. Core body temperature and plasma melatonin concentration were measured as markers of the central circadian pacemaker. The expression of HPER1, HPER2, and HBMAL1 was quantified in PBMCs sampled throughout an uninterrupted 72 h period. The core body temperature minimum and the midpoint of melatonin concentration measured during the CR occurred 2:17±0:20 and 3:24 ±0:09 h before habitual awakening, respectively, and were well aligned to the sleep/wake cycle. HPER1 and HPER2 expression in PBMCs demonstrated significant circadian rhythmicity that peaked early after wake-time and was comparable under LD and CR conditions. HBMAL1 expression was more variable, and peaked in the middle of the wake period under LD conditions and during the habitual sleep period under CR conditions. For the first time, bi-hourly sampling over three consecutive days is used to compare clock gene expression in a human peripheral oscillator under different sleep/wake conditions.     

Infradian rhythmicity in sleep/wake ratio in developing infants

Although there are several reports on ultradian and circadian rhythms in newborns, we found only one report in which infradian periodicities are described for heart-rate measurements in the early stages of human development. Here, we report infradian rhythms in the monthly range in the sleep/wake cycle of four infants studied along 24 consecutive weeks. Our procedure was applied to sleep diary records from four healthy newborns. The data were arranged in binary time series representing sleep (-1) or wake (1) states. These time series were integrated in order to obtain the cumulative sleep/wake time. A measure of the sleep/wake ratio (SWR) was obtained by computing the average slope of the cumulative sleep/wake time. To extract periodicities we applied the Fourier periodogram to the temporal course of the SWR. We found a notorious difference in the SWR pattern among infants. In two infants the SWR showed a marked linear decay, spending more time asleep than awake, while in the two other infants oscillated near zero. We found robust oscillations in all children. In all cases the Fourier periodogram results present significant power in the infradian range. From these results, we suggest that sleep and wake durations are probably modulated by some internal stimuli.     

A mathematical model of the sleep/wake cycle

We present a biologically-based mathematical model that accounts for several features of the human sleep/wake cycle. These features include the timing of sleep and wakefulness under normal and sleep-deprived conditions, ultradian rhythms, more frequent switching between sleep and wakefulness due to the loss of orexin and the circadian dependence of several sleep measures. The model demonstrates how these features depend on interactions between a circadian pacemaker and a sleep homeostat and provides a biological basis for the two-process model for sleep regulation. The model is based on previous “flip–flop” conceptual models for sleep/wake and REM/NREM and we explore whether the neuronal components in these flip–flop models, with the inclusion of a sleep-homeostatic process and the circadian pacemaker, are sufficient to account for the features of the sleep/wake cycle listed above. The model is minimal in the sense that, besides the sleep homeostat and constant cortical drives, the model includes only those nuclei described in the flip–flop models. Each of the cell groups is modeled by at most two differential equations for the evolution of the total population activity, and the synaptic connections are consistent with those described in the flip–flop models. A detailed analysis of the model leads to an understanding of the mathematical mechanisms, as well as insights into the biological mechanisms, underlying sleep/wake dynamics.     

The effect of long-term nitrazepam administration on sleep cycles in rats]

Single and chronic administration of a low dose of nitrazepam (1 mg/kg) had no effect on sleep cycles in rats. A single injection of a high dose (10 mg/kg) of nitrazepam resulted in prolongation of the total duration of synchronized sleep with a corresponding shortening of desynchronized (paradoxical) sleep. The number of sleep cycles was reduced. Chronic injections of nitrazepam (for 7-14 days) in a dose of 10 mg/kg evoked a gradual prolongation of the duration of paradoxical sleep and an increase in number of sleep cycles. After discontinuance of a long-term administration of nitrazepam (1 mg/kg or 10 mg/kg) prolongation of desynchronized sleep and an increase in the number of sleep cycles were more pronounced in comparison with the last day of chronic administration of the drug.     

Individual differences in the sleep/wake cycle of Arctic flexitime workers

Daytime workers tend to have shorter sleep duration and earlier sleep onset during work days than on days off. Large individual differences in sleep onset and sleep duration may be observed on work days, but work usually synchronizes sleep offset to a similar time. The present study describes individual differences in sleep behaviour of 48 daytime workers (25 men, aged 20–58 years) from an iron ore mine in Northern Sweden. The aim of the study was to determine whether differences in sleep patterns during work days were associated with the outcomes of sleepiness and sleep complaints. Cluster analysis was used to group workers into two categories of sleep onset and sleep duration. The “Late Sleep Onset” cluster comprised workers who slept 1.30 h later than the “Early Sleep Onset” cluster (p < 0.0001 for all weekdays). The “Long Sleep Duration” cluster slept 1.10 h longer than the “Short Sleep Duration” cluster (p < 0.0002 for work nights). The “Late Sleep Onset” cluster reported less refreshing sleep (p < 0.01) and had lower sufficient sleep scores (p < 0.01) than the “Early Sleep Onset” cluster. The “Short Sleep Duration” cluster also reported lower scores for sufficient sleep (p < 0.04) than the “Long Sleep Duration” cluster. For combined characteristics (phase and duration), workers with a late phase and short sleep duration reported greater sleep debt and sleepiness than workers with an early phase and short sleep duration (p < 0.02). Work schedule and commuting time modulate both sleep phase and sleep duration independently. Workers, classified as having an intermediate sleep phase preference, can organize their sleep time in order to minimize sleep debt and sleepiness symptoms. Individual differences in sleep phase and duration should be considered when promoting well-being at work even among groups with similar sleep needs. In order to minimize sleep debt and sleepiness symptoms, successful sleep behaviour could be promoted involving extend use of flexitime arrangement (i.e. later starting times) and reduce use of alarm clocks.     

Newly developed waist actigraphy and its sleep/wake scoring algorithm

The purpose of this study was to formulate an algorithm for assessing sleep/waking from activity intensities measured with a waist-worn actigraphy, the Lifecorder PLUS (LC; Suzuken Co. Ltd., Nagoya, Japan), and to test the validity of the algorithm. The study consisted of 31 healthy subjects (M/F = 20/11, mean age 31.7 years) who underwent one night of simultaneous measurement of activity intensity by LC and polysomnography (PSG). A sleep(S)/wake(W) scoring algorithm based on a linear model was determined through discriminant analysis of activity intensities measured by LC over a total of 235 h and 56 min and the corresponding PSG-based S/W data. The formulated S/W scoring algorithm was then used to score S/W during the monitoring epochs (2 min each, 7078 epochs in total) for each subject. The mean agreement rate with the corresponding PSG-based S/W data was 86.9%, with a mean sensitivity (sleep detection) of 89.4% and mean specificity (wakefulness detection) of 58.2%. The agreement rates for the individual stages of sleep were 60.6% for Stage 1, 89.3% for Stage 2, 99.2% for Stage 3 + 4, and 90.1% for Stage REM. These results demonstrate that sleep/wake activity in young to middle-aged healthy subjects can be assessed with a reliability comparable to that of conventional actigraphy through LC waist actigraphy and the optimal S/W scoring algorithm.