A probabilistic model for the ultradian timing of REM sleep in mice

A salient feature of mammalian sleep is the alternation between rapid eye movement (REM) and non-REM (NREM) sleep. However, how these two sleep stages influence each other and thereby regulate the timing of REM sleep episodes is still largely unresolved. Here, we developed a statistical model that specifies the relationship between REM and subsequent NREM sleep to quantify how REM sleep affects the following NREM sleep duration and its electrophysiological features in mice. We show that a lognormal mixture model well describes how the preceding REM sleep duration influences the amount of NREM sleep till the next REM sleep episode. The model supports the existence of two different types of sleep cycles: Short cycles form closely interspaced sequences of REM sleep episodes, whereas during long cycles, REM sleep is first followed by an interval of NREM sleep during which transitions to REM sleep are extremely unlikely. This refractory period is characterized by low power in the theta and sigma range of the electroencephalogram (EEG), low spindle rate and frequent microarousals, and its duration proportionally increases with the preceding REM sleep duration. Using our model, we estimated the propensity for REM sleep at the transition from NREM to REM sleep and found that entering REM sleep with higher propensity resulted in longer REM sleep episodes with reduced EEG power. Compared with the light phase, the buildup of REM sleep propensity was slower during the dark phase. Our data-driven modeling approach uncovered basic principles underlying the timing and duration of REM sleep episodes in mice and provides a flexible framework to describe the ultradian regulation of REM sleep in health and disease.     

Early Onset and Accumulation of Rem Sleep in Depression: A Study of the Phase-Advance Hypothesis

–Twenty-two depressed subjects who met criteria for major depressive disorder were grouped according to their initial REM latency. Subjects with short (≥ 60 min) initial REM latency were separated from those with normal (< 60 min) initial REM latency. Subjects with short initial REM latency were found to have earlier onsets to at least two subsequent REM periods. The number of minutes of REM sleep accumulated were also plotted against elapsed time after sleep onset. The short-latency group accumulated REM sleep earlier than, but at about the same rate as, the normal latency group. These data support the phase-advance hypothesis of REM sleep in depression.     

Influence of fear conditioning on elicited ponto-geniculo-occipital waves and rapid eye movement sleep

The amygdala plays a central role in fear conditioning, a model of anticipatory anxiety. It has massive projections to brainstem regions involved in rapid eye movement sleep (REM) and ponto-geniculo-occipital (PGO) wave generation. PGO waves occur spontaneously in REM or in response to stimuli. Electrical stimulation of the central nucleus of the amygdala enhances spontaneous PGO wave activity during REM and the amplitude of both the acoustic startle response and the elicited PGO wave (PGOE), a neural marker of alerting. This study examined the effects of fear conditioning on REM and on PGOE. On conditioning days, the number of REM episodes, the average REM duration and the REM percentage were decreased while REM latency was increased. The presentation of auditory stimuli in the presence of a light conditioned stimulus produced PGOE of greater amplitudes. The results suggest that fear, most likely involving the amygdala, can influence REM and brainstem alerting mechanisms.     

Selective REM sleep deprivation during daytime I. Time course of interventions and recovery sleep

Although repeated selective rapid eye movement (REM) sleep deprivation by awakenings during nighttime has shown that the number of sleep interruptions required to prevent REM sleep increases within and across consecutive nights, the underlying regulatory processes remained unspecified. To assess the role of circadian and homeostatic factors in REM sleep regulation, REM sleep was selectively deprived in healthy young adult males during a daytime sleep episode (7-15 h) after a night without sleep. Circadian REM sleep propensity is known to be high in the early morning. The number of interventions required to prevent REM sleep increased from the first to the third 2-h interval by a factor of two and then leveled off. Only a minor REM sleep rebound (11.6%) occurred in the following undisturbed recovery night. It is concluded that the limited rise of interventions during selective daytime REM sleep deprivation may be due to the declining circadian REM sleep propensity, which may partly offset the homeostatic drive and the sleep-dependent disinhibition of REM sleep.     

An ether stressor increases REM sleep in rats: possible role of prolactin

Sleep alterations after a 1-min exposure to ether vapor were studied in rats to determine if this stressor increases rapid eye-movement (REM) sleep as does an immobilization stressor. Ether exposure before light onset or dark onset was followed by significant increases in REM sleep starting approximately 3-4 h later and lasting for several hours. Non-REM (NREM) sleep and electroencephalographic slow-wave activity during NREM sleep were not altered. Exposure to ether vapor elicited prolactin (Prl) secretion. REM sleep was not promoted after ether exposure in hypophysectomized rats. If the hypophysectomy was partial and the rats secreted Prl after ether exposure, then increases in REM sleep were observed. Intracerebroventricular administration of an antiserum to Prl decreased spontaneous REM sleep and inhibited ether exposure-induced REM sleep. The results indicate that a brief exposure to ether vapor is followed by increases in REM sleep if the Prl response associated with stress is unimpaired. This suggests that Prl, which is a previously documented REM sleep-promoting hormone, may contribute to the stimulation of REM sleep after ether exposure.     

Effect of sleep stage on breathing in children with central hypoventilation.

The early literature suggests that hypoventilation in infants with congenital central hypoventilation syndrome (CHS) is less severe during rapid eye movement (REM) than during non-REM (NREM) sleep. However, this supposition has not been rigorously tested, and subjects older than infancy have not been studied. Given the differences in anatomy, physiology, and REM sleep distribution between infants and older children, and the reduced number of limb movements during REM sleep, we hypothesized that older subjects with CHS would have more severe hypoventilation during REM than NREM sleep. Nine subjects with CHS, aged (mean +/- SD) 13 +/- 7 yr, were studied. Spontaneous ventilation was evaluated by briefly disconnecting the ventilator under controlled circumstances. Arousal was common, occurring in 46% of REM vs. 38% of NREM trials [not significant (NS)]. Central apnea occurred during 31% of REM and 54% of NREM trials (NS). Although minute ventilation declined precipitously during both REM and NREM trials, hypoventilation was less severe during REM (drop in minute ventilation of 65 +/- 23%) than NREM (drop of 87 +/- 16%, P = 0.036). Despite large changes in gas exchange during trials, there was no significant change in heart rate during either REM or NREM sleep. We conclude that older patients with CHS frequently have arousal and central apnea, in addition to hypoventilation, when breathing spontaneously during sleep. The hypoventilation in CHS is more severe during NREM than REM sleep. We speculate that this may be due to increased excitatory inputs to the respiratory system during REM sleep.     

Minireview. Catecholamines and the sleep-wake cycle. II. REM sleep

The exact role of catecholamines (CA) on REM sleep is still controversial. Lesion studies suggest that norepinephrine plays a neuromodulatory role in REM sleep. Support for this view is provided by pharmacological studies in which noradrenergic neurons are activated or inhibited. Thus, disturbances in the dynamic balance between neurochemical systems may alter the conditions under which optimal REM sleep takes place. Discrete radiofrequency lesions to the pontine giganto-cellular tegmental field (which includes the nuclei reticularis pontis oralis and caudalis and where cholinergic and cholinoceptive neurons have been described), result in the elimination of REM sleep. Circumscribed, electrolytic lesions of the locus coeruleus (IC) area, which only minimally extend beyond it, eliminate atonia and reduce PGO activity in REM sleep. Selective destruction of the LC or ascending noradrenergic axons with 6-hydroxydopamine does not result in significant changes of tonic or phasic components of desynchronized sleep. These results indicate that noradrenergic neurons are not necessary for the initiation and maintenance of REM sleep. Most probably, many of the effects attributed to noradrenergic structures are due to destruction of non-noradrenergic neurons and fibers of passage in the lesioned area.Inhibition of CA synthesis with α-methyl-p-tyrosine has resulted in conflicting effects on REM sleep, which could be related to factors other than NE depletion. Systemic administration of dopamine-β-hydroxylase inhibitors (disulfiram, diethyldithiocarbamate, FLA-63, fusaric acid) produced consistent reductions of REM sleep. However, the simultaneous increase of 5-HT and DA levels complicates the interpretation of these results. Selective pharmacological stimulation of presynaptic α-adrenergic (α2) receptors with clonidine, xylazine or α-methyl-dopa decreases REM sleep. Specific blockade of α 2-receptors with yohimbine, piperoxane or tolazoline also reduces desynchronized sleep, but increases wakefulness. In contrast, drugs with similar affinity for pre and postsynaptic (α1) adrenoceptors (phentolamine) markedly increase REM sleep. Compounds Compounds with agonistic activity at postsynaptic α-adrenergic sites (methoxamine) consistently reduce REM sleep, while derivatives with inhibitory activity restricted to these receptors (thymoxamine, prazosin) produce REM sleep increments. Results from studies where propranolol and isoproterenol were administered to laboratory animals point to an involvement of β-adrenergic mechanisms in REM sleep modulation.Although there is no direct evidence to support a dopaminergic influence upon REM sleep executive mechanisms, indirect pharmacological data suggests a neuromodulatory role for dopaminergic neurons. Direct dopaminergic agonists and antagonists show biphasic effects on REM sleep. Low dosages of apomorphine increase, while large doses decrease, REM sleep. Opposite effects are observed after the dopaminergic antagonist pimozide. These dose-dependent effects seem to be related to the activation or blockade of different receptors.     

Sequential analysis of the brain's transfer properties during consecutive REM episodes

Classical analysis of the spontaneous sleep EEG has revealed alterations of REM sleep in psychiatric diseases and under the influence of drugs. In order to elucidate possible functional differences between different REM episodes even in healthy subjects we investigated in 10 volunteers the transfer properties of the brain by measuring auditory (AEP) and visual evoked potentials (VEP) from scalp positions F_z, C_z and P_z during the night. According to linear system theory we computed the so-called amplitude-frequency characteristics (AFC) from averaged AEPs and VEPs during the first and each of the following 3 REM episodes. These functions describe the relationship between the input and output of the investigated system. A 3-factorial analysis of variances with the independent factors frequency band, REM episode and electrode position revealed a statistically significant main effect for the factor REM episode under auditory stimulation (P = 0.05), whereas no significant main effect for REM episode was found under visual stimulation (P = 0.88). Applying a 2-factorial analysis of variance with the independent factors REM episode and electrode position in the case of auditory stimulation we could demonstrate a statistically significant main effect (P = 0.029) for the factor REM episode in the beta range (12.5–20 Hz). A subsequent analysis of contrasts revealed that the first REM episodes could be differentiated from each other. For auditory stimulation the beta resonance during the first REM episode appears enhanced compared to each of the later REM episodes. These findings point to a functional difference of the brain's transfer functions between the first and the 3 following REM episodes, indicating different information processing during consecutive paradoxical sleep.     

Vasotocin, melatonin and narcolepsy: Possible involvement of the pineal gland in its patho-physiological mechanism

Both the pineal nonapeptide hormone arginine vasotocin (AVT) (2.5 μg) administered intra-nasally and the pineal indole melatonin (50 mg) administered intravenously to three male narcoleptics (two with auxiliary symptoms and one with sleep attacks only), dramatically increased the amount of REM sleep and decreased REM sleep latency. The duration of the sleep onset REM periods in the two narcoleptics with auxiliary symptoms increased by more than 100 percent after AVT and melatonin administration. In the narcoleptic with sleep attacks only both AVT and melatonin induced REM periods at sleep onset. The hypothesis is advanced that narcolepsy represents an impairment of the melatonin-AVT control in the induction and circadian organization of REM sleep associated with an immaturity of REM triggering centers.     

Vasotocin, melatonin and narcolepsy: Possible involvement of the pineal gland in its patho-physiological mechanism

Both the pineal nonapeptide hormone arginine vasotocin (AVT) (2.5 μg) administered intra-nasally and the pineal indole melatonin (50 mg) administered intravenously to three male narcoleptics (two with auxiliary symptoms and one with sleep attacks only), dramatically increased the amount of REM sleep and decreased REM sleep latency. The duration of the sleep onset REM periods in the two narcoleptics with auxiliary symptoms increased by more than 100 percent after AVT and melatonin administration. In the narcoleptic with sleep attacks only both AVT and melatonin induced REM periods at sleep onset. The hypothesis is advanced that narcolepsy represents an impairment of the melatonin-AVT control in the induction and circadian organization of REM sleep associated with an immaturity of REM triggering centers.     

Light-Dark Difference in Arterial Pressure Variability During REM Sleep in the Rat

We have observed mean arterial pressure (MAP) variability during rapid eye movement (REM) sleep and brain temperature (Tb) in the rat during both light and dark periods over 24 h. MAP was measured using a telemetric device with a computer data capture and analysis system. As markers of MAP variability, the maximum and coefficient of variation (CV%) of MAP during REM sleep were determined. The following results were obtained: (a) there was a light-dark difference in MAP during non-REM (NREM) sleep and Tb during both NREM and REM sleep; (b) the increase of MAP in going from NREM to REM sleep in the light period was greater than that in the dark period, whereas the increase of Tb in the light period was not different from that in the dark period; (c) the maximum and CV% for MAP during REM sleep in the light period were greater than those in the dark period; (d) there was a negative correlation between the average Tb and MAP CV% during REM sleep. We suggest that phasic fluctuation of MAP during REM sleep may be influenced, in part, by a factor independent of sleep mechanisms.     

Microinjection of glutamate into the pedunculopontine tegmentum induces REM sleep and wakefulness in the rat

The aim of this study was to test the hypothesis that the cells in the brain stem pedunculopontine tegmentum (PPT) are critically involved in the normal regulation of wakefulness and rapid eye movement (REM) sleep. To test this hypothesis, one of four different doses of the excitatory amino acid L-glutamate (15, 30, 60, and 90 ng) or saline (control vehicle) was microinjected unilaterally into the PPT while the effects on wakefulness and sleep were quantified in freely moving chronically instrumented rats. All microinjections were made during wakefulness and were followed by 6 h of polygraphic recording. Microinjection of 15- ng (0.08 nmol) and 30-ng (0.16 nmol) doses of L-glutamate into the PPT increased the total amount of REM sleep. Both doses of L-glutamate increased REM sleep at the expense of slow-wave sleep (SWS) but not wakefulness. Interestingly, the 60-ng (0.32 nmol) dose of L-glutamate increased both REM sleep and wakefulness. The total increase in REM sleep after the 60-ng dose of L-glutamate was significantly less than the increase from the 30-ng dose. The 90-ng (0.48 nmol) dose of L-glutamate kept animals awake for 2-3 h by eliminating both SWS and REM sleep. These results show that the L-glutamate microinjection into the PPT can increase wakefulness and/or REM sleep depending on the dosage. These findings support the hypothesis that excitation of the PPT cells is causal to the generation of wakefulness and REM sleep in the rat. In addition, the results of this study led to the identification of the PPT dosage of L-glutamate that optimally induces wakefulness and REM sleep. The knowledge of this optimal dose will be useful in future studies investigating the second messenger systems involved in the regulation of wakefulness and REM sleep.     

Light-Dark Difference in Arterial Pressure Variability During REM Sleep in the Rat

We have observed mean arterial pressure (MAP) variability during rapid eye movement (REM) sleep and brain temperature (Tb) in the rat during both light and dark periods over 24 h. MAP was measured using a telemetric device with a computer data capture and analysis system. As markers of MAP variability, the maximum and coefficient of variation (CV%) of MAP during REM sleep were determined. The following results were obtained: (a) there was a light-dark difference in MAP during non-REM (NREM) sleep and Tb during both NREM and REM sleep; (b) the increase of MAP in going from NREM to REM sleep in the light period was greater than that in the dark period, whereas the increase of Tb in the light period was not different from that in the dark period; (c) the maximum and CV% for MAP during REM sleep in the light period were greater than those in the dark period; (d) there was a negative correlation between the average Tb and MAP CV% during REM sleep. We suggest that phasic fluctuation of MAP during REM sleep may be influenced, in part, by a factor independent of sleep mechanisms.     

Ventilation during early and late rapid-eye-movement sleep in normal humans.

Because successive rapid-eye-movement (REM) sleep periods in the night are longer in duration and have more phasic events, ventilation during late REM sleep might be more affected than in earlier episodes. Despite the increase in eye movement density (EMD) in late REM sleep, average minute ventilation was, however, not reduced compared with that in early REM sleep. Decreases in rib cage motion (mean inspiratory flow of the rib cage) in association with increasing EMD were offset by increments in respiratory frequency. Apart from expiratory time, there were no significant changes in the slopes of the relationships between EMD and specific ventilatory components, from early to late REM sleep periods. However, there was an increase in the number of episodes when ventilation was reduced during late REM sleep. Changes in ventilatory pattern during late REM sleep are due to changes in the underlying nature of REM sleep. The ventilatory response during eye movements is, however, subject specific. Some subjects exhibit large decrements in mean inspiratory flow of the rib cage and increments in respiratory frequency during bursts of eye movement, whereas other individuals demonstrate only small changes in these ventilatory parameters.     

Fragment replica-exchange method for efficient protein conformation sampling

The native structure of proteins corresponds to the global minimum of the free energy. The replica-exchange method (REM) has been recently used to search for the energy minimum in a wide protein conformation space. For large systems, however, applying REM can be costly because the number of replicas required for conformational sampling increases. We have developed a variant of REM called fragment REM, which is based on the existence of correlations between the local amino acid sequence and the local structure. Equilibrium distributions for two peptides were computed by conventional molecular dynamics, REM and the proposed REM simulations. We found that the modified REM successfully reduces the number of replicas needed for the simulation.     

The influence of prior wakefulness on REM sleep

Data from studies of naps and of shifted sleep were used to determine the relationship between two measures of rapid eye movement (REM) sleep (percentage of REM in the first 2 hr of sleep and REM latency) and prior wakefulness. For each sample, we calculated the difference between the observed value and that predicted by a cosine function that estimated the circadian rhythm of REM sleep propensity. The difference values were found to correlate reliably with hours and log hours of prior wakefulness. We conclude that while REM sleep is regulated in part by an endogenous circadian oscillator, it is also influenced by the duration of prior wakefulness.     

Some indices of the activity of the brain in "rapid" sleep preceeded or not preceeded by delta-sleep]

In order to study the functional interaction between the delta sleep and the REM sleep some psychophysiological features of REM sleep were examined in REM-onset (without any preceding delta sleep--"early REM period") and in the REM period (REMP) terminating the normal sleep cycle (with the preceding delta sleep) of 92 daytime sleep attacks in 10 narcoleptic patients. Under these conditions the significant differences exist in the characteristics of the dream reports and in subjective estimations of sleep quality and duration. Sleep was evaluated as "superficial" and underestimations of sleep duration took place after an early REMP. Correct estimations of sleep duration and evaluations of sleep as "deep" dominated after REMP enging sleep cycles. The results obtained indicate the functional interaction between the delta sleep and REM sleep existing in the sleep cycle and largely determining the psychic content of the brain activity in the REM sleep.