Selective REM sleep deprivation and compensation phenomena in the rat

The effects of flumazenil, Ro 154513 and beta-CCM on the behaviour of control and stressed mice in the staircase test

The effects of flumazenil, Ro 154513 and beta-CCM in the staircase test were studied in control and small platform (SP) stressed mice. SP stress was induced by placing mice on small platforms (3.5 cm in diameter) surrounded by water for 24 h. This model contains several factors of stress, such as rapid eye movement sleep deprivation, isolation, immobilization and falling into the water. The staircase test consisted of placing a mouse in an enclosed staircase with five steps and recording: (i) the number of rearings and (ii) steps made during 3 min. SP stress increased the exploratory activity of mice in the staircase test as demonstrated by an increase in the number of rearings and steps made. In control mice flumazenil (2.0 and 10.0 mg/kg), Ro 15-4513 (1.0 and 3.0 mg/kg) and beta-CCM (1.0 and 2.0 mg/kg) exerted an anxiogenic effect that was demonstrated by an increase in the number of rearings without significant changes in the number of steps. Similar to control mice, flumazenil induced an anxiogenic effect in SP stressed mice as demonstrated by an increase in the number of rearings. However, the sedative effect of flumazenil as demonstrated by a decrease in the number of steps made was more pronounced in SP stressed mice. In the SP stressed mice, the anxiogenic effect of Ro 15-4513 and beta-CCM was masked by their strong sedative effect and a decrease in both measures of exploratory activity (number of rearings and number of steps). These data suggest that SP stress induces hypersensitivity to the sedative effect of flumazenil, Ro 15-4513 and beta-CCM in the staircase test.

Lesions of the pedunculopontine tegmental nucleus reduce paradoxical sleep (PS) propensity: evidence from a short-term PS deprivation study in rats

Cholinergic neurons in the mesopontine tegmentum are thought to play a critical role in the generation of paradoxical sleep (PS). However, no study has yet examined whether lesions of these neurons cause deficits of PS in the rat. We describe here the effects of lesions of the pedunculopontine tegmental nucleus (PPT) on spontaneous PS and on PS propensity, expressed during and after a short period of PS deprivation. Lesions were induced by bilateral injections of ibotenate. PS deprivation was performed manually by gently waking rats each time they showed polygraphic signs of PS. Two weeks after lesions, an 8-h baseline recording was performed; the following day, rats were PS deprived for 6 h and polygraphic recordings were then continued for 2 h, to examine recovery sleep. The same protocol was repeated 1 week later. Compared with controls and with rats with limited PPT lesions, rats bearing > 60% NADPH-diaphorase-positive cell loss within the PPT showed unaffected PS under baseline conditions. However, they made fewer attempts to enter PS during deprivation and they exhibited an attenuated rebound increase in PS time after deprivation. The number of PS attempts and the magnitude of PS rebound were negatively correlated with the percent loss of diaphorase-positive neurons within the PPT. Thus, PS propensity that accumulated as a result of PS deprivation was reduced after extensive PPT lesions. In summary, although spontaneous PS was found to be unaltered, the PS deprivation procedure used in this study demonstrated the dysfunctioning of PS caused by PPT lesions.

The effect of baclofen on the locomotor activity of control and small-platform-stressed mice

The effect of baclofen on the locomotor activity of control and small-platform-stressed mice was studied. In the small platform technique, mice are forced to stay on small platforms (d= 3.5 cm) surrounded by water for 24 h. Small platform stress increased the locomotor activity of mice in the actometer. Baclofen administered at doses of 0.25, 0.5 and 1.0 mg kg(-1)(i.p.) had no effect on the locomotor activity of control mice. In small-platform-stressed mice, the locomotor depressant effect of baclofen was pronounced, being statistically significant at a dose of 1.0 mg kg(-1). These data suggest that small platform stress induces hypersensitivity of mice to the motor depressant effect of baclofen. On the basis of these data it could be proposed that small platform stress induces changes in the function of GABA(B)receptors and that GABA(B)receptors participate in the behavioural changes caused by small platform stress.

Sleep rebound in animals deprived of paradoxical sleep by the modified multiple platform method

The objective of the present study was to assess the sleep rebound of animals exposed to the modified multiple platform method (MMPM), in which cage-mate rats were placed onto narrow platforms (NP=6.5 cm in diameter), onto wide platforms (WP=14 cm in diameter) or onto a grid (GR). The last two groups were included as environmental controls for the deprivation method. Animals were implanted with bipolar electrodes in the cortex, hippocampus and neck muscle. Baseline sleep was recorded for 6 h, after which the animals were placed in one of the above-mentioned settings for 90 h and their sleep was again recorded. Comparison between baseline and post-GR recordings revealed no sleep differences in these animals. Placement of animals onto WP resulted in augmented sleep time (16%), time spent in PS (+99%), duration of PS episodes (+77%), sleep efficiency (+16%), and in reduced latency to PS (-84.8%). Finally, NP animals exhibited a dramatic increase in sleep time (+34.3%), time spent in PS (+184.7%), duration of PS episodes (+106%), and in sleep efficiency (+34.4%). Moreover, sleep latency (-52.2%) and time spent in SWS (-12.2%) were reduced. Based on the results of sleep rebound, the data indicated that placement of animals onto narrow platforms in the MMPM was an effective PS deprivation method and the grid should be considered as an adequate environmental control.

Circadian and homeostatic control of rapid eye movement (REM) sleep: promotion of REM tendency by the suprachiasmatic nucleus

The daily timing of rapid eye movement (REM) sleep reflects an interaction between the circadian pacemaker located in the suprachiasmatic nucleus of the hypothalamus (SCN) and a homeostatic process that induces compensatory REM sleep in response to REM sleep loss. Whether the circadian variation in REM sleep propensity is caused by active promotion, inhibition, or passive gating of REM sleep homeostasis by the SCN is unknown. To investigate these possibilities, compensatory responses to 24 hr REM sleep deprivation (RSD) were compared between SCN-lesioned (SCNx) and sham-lesioned rats at different times of day in constant dark. The attempts to enter REM sleep (REM tendency) increased during RSD in all rats and were modulated by circadian phase in sham-lesioned, but not SCNx rats. REM sleep homeostasis interacted with circadian time, such that REM tendency doubled during the rest phase in sham-lesioned rats relative to SCNx rats (F((6,93)) = 17.9; p = 0.0001). However, REM tendency was indistinguishable between SCNx and sham-lesioned rats during the activity phase, suggesting the SCN does not inhibit REM tendency at this time. By contrast, the amount of compensatory REM sleep examined 2, 6, 12, or 24 hr after RSD did not depend on circadian phase. Thus, transitions into REM sleep are facilitated by the SCN during the rest phase, but the amount of REM sleep, once initiated, is determined primarily by homeostatic mechanisms. This work supports a role for the SCN in the active promotion of REM sleep at specific times of day.

Effects of sleep deprivation on free-operant avoidance

Two studies examined effects of sleep deprivation on free-operant avoidance by rats. In Experiment 1, a 5-s shock-shock (SS) interval and 20-s response-shock (RS) interval produced baseline performances, which were reestablished after each experimental manipulation. Once baselines were established, animals were exposed to 24, 48, or 96 hr of sleep deprivation and equivalent periods of home cage and food restriction as a control condition. Compared to baseline, sleep deprivation increased response rates by increasing the proportion of brief interresponse times (IRTs); response rates changed little in the control conditions. Percentage of shocks avoided did not systematically change across conditions. In Experiment 2, the RS interval was manipulated (10, 20, and 40 s), while the SS interval (5 s) and level of sleep deprivation (48 hr) were held constant. Across RS intervals, sleep deprivation increased response rates via a shift toward brief IRTs. In addition, sleep deprivation increased the percentage of shocks avoided as an inverse function of RS intervals.

Small platform stress attenuates the anxiogenic effect of diazepam withdrawal in the plus-maze test

The effect of stress on the behavioural changes caused by diazepam withdrawal was studied in mice. Diazepam (2.5 mg/kg) or vehicle was injected intraperitoneally twice a day for 2 weeks. When the last vehicle or diazepam injection had been administered to the mice, 12 h later, the mice were subjected to small platform stress exposure or left in their home cages. Small platform stress was induced by placing mice on small platforms (3.5 cm diameter) surrounded by water for 24 h. This experimental model contains several factors of stress like rapid eye movement (REM) sleep deprivation, isolation, immobilization and falling into the water. The plus-maze test was carried out with stressed mice as well as with mice not subjected to stress. Small platform stress induced an anxiolytic effect and diazepam withdrawal--an anxiogenic effect in the plus-maze test. Small platform stress also attenuated the anxiogenic effect of diazepam withdrawal. On the basis of this data it was proposed that small platform stress counteracts the anxiogenic effect of diazepam withdrawal in the plus-maze test. It was also proposed that the effect of stress on the signs of benzodiazepine withdrawal depends on the characteristics and duration of stress.

Sleep-waking discharge patterns of ventrolateral preoptic/anterior hypothalamic neurons in rats

Numerous lesion, stimulation and recording studies in experimental animals demonstrate the importance of neurons within the preoptic/anterior hypothalamic area (POA) in the regulation of sleep induction and sleep maintenance. Recently, a discrete cluster of cells in the ventrolateral POA (vlPOA) of rats was found to exhibit elevated c-fos gene expression during sleep, indicating that these neurons are strongly activated during nonREM and/or REM sleep stages. We examined neuronal discharge during wakefulness and sleep throughout the dorsal to ventral extent of the lateral POA in rats, using chronic microwire technique. We found that neurons with elevated discharge rates during sleep, compared to waking, were localized to the vlPOA. As a group, vlPOA neurons displayed elevated discharge rates during both nonREM and REM sleep. Discharge of vlPOA neurons reflected the depth of sleep, i.e., discharge rates increased significantly from light to deep nonREM sleep. During recovery sleep following 12-14 h of sleep deprivation, vlPOA neurons displayed increased sleep-related discharge, compared to baseline sleep. Neurons in the vlPOA displaying increased neuronal discharge during sleep were located in the same area where neurons exhibit increased c-fos gene expression during sleep. Such neurons are likely components of a rostral hypothalamic mechanism that regulates sleep onset and sleep maintenance.

Selective and total sleep deprivation: effect on the sleep EEG in the rat

Although sleep deprivation is known to exert an antidepressant effect in depressed patients, the involvement of sleep regulation is still unknown. Selective sleep deprivation experiments were performed in the rat to investigate the interactions between non-REM sleep (NREMS) and REM sleep (REMS) in an animal model. A12-h total sleep deprivation (TD) period ending at lights on was followed by one of the following protocols: (1) recovery sleep (TD12); (2) 4-h total sleep deprivation (TD16); (3) 4-h slow-wave deprivation (SWD); (4) 4-h REMS deprivation (RD). In the SWD protocol, the reduction of EEG slow-wave activity (SWA; power density in the 0.75-4.0 Hz band) was obtained by curtailing NREMS episodes to 20 s. During RD the number of interventions required to prevent REMS increased during the first 2 h and then remained constant. While RD caused only a minor reduction of NREMS, it increasingly suppressed SWA in NREMS. The rebound of SWA occurred later and was less prominent after RD than after SWD. Whereas an REMS rebound occurred after all three 4-h sleep deprivation protocols, a persistent increase in the dark period was present only after TD16. It is concluded that (a) SWA in NREMS is inhibited by an increased level of REMS propensity; (b) the hypothesis that REMS propensity increases only during NREMS is not supported; and (c) the results are compatible with the hypothesis that the suppression of NREMS intensity is the common denominator of different antidepressive sleep manipulations in depressive patients.

Effects of the CLIP fragment ACTH 20-24 on the duration of REM sleep episodes

Substances acting upon rapid eye movement (REM) sleep or paradoxical sleep (PS) can affect the number and/or the duration of PS episodes. In the present study, we investigated the effects of the proopiomelanocortin-derived peptide CLIP (corticotropin-like intermediate lobe peptide, ACTH 18-39) and its N-terminal fragments ACTH 18-24 and ACTH 20-24 on the duration of PS episodes in rats. Intracerebroventricular injection of ACTH 20-24 caused a pronounced prolongation of PS episodes (up to 7 min duration, never seen under baseline conditions), whereas ACTH 18-24 acted in a similar way but without reaching statistical significance. We suggest that short N-terminal CLIP fragment(s) may represent endogenous hypnogenic factor(s) involved in the regulation of paradoxical sleep.

Is upregulation of benzodiazepine receptors a compensatory reaction to reduced GABAergic tone in the brain of stressed mice?

Effects of various forms of stress on the GABAA receptor-chloride ionophore complex in the brain of NMRI mice were investigated. Male albino mice were subjected to stress by placing them on small platforms (SP; 3.5 cm diameter) surrounded by water for 24 h. This experimental model contains several stress factors like rapid eye movement (REM) sleep deprivation, isolation, immobilization, falling into water and soaking. As additional stress control groups we used animals subjected to isolation, large platform (9.0 cm diameter) and repeated swimming stress. SP stress induced an increase in the number of cortical benzodiazepine (BDZ) receptors and a reduction in the GABA-stimulated 36Cl-uptake by brain microsacs, whereas none of these changes could be observed in animals exposed to isolation, swimming or large platform stresses. Furthermore, the amount of GABA-induced stimulation of [3H]flunitrazepam binding was reduced in cortical brain membranes of SP-stressed animals, an effect due to fact that these animals displayed an increase in the basal [3H]flunitrazepam binding, whereas the absolute level of maximally enhanced BDZ binding in the presence of GABA did not differ from those found in controls. Neither basal [3H]muscimol binding or thiopentone sodium-induced stimulation of [3H]flunitrazepam binding were changed in any group of stressed mice. It is proposed that the observed upregulation in the number (Bmax) of cortical BDZ receptors in SP-stressed mice may represent a compensatory response to a stress-induced attenuation of GABAergic neurotransmission.

Reduced inhibitory potency of serotonin reuptake blockers on central serotoninergic neurons in rats selectively deprived of rapid eye movement sleep

Previous studies showed that chronic deprivation of rapid eye movement (REM) sleep had the same behavioral effects as antidepressant drugs in helpless rats. Since long-term treatment with antidepressants is known to affect central serotoninergic neurotransmission, we investigated whether REM sleep deprivation also exerts an influence on the activity of serotoninergic neurons within the dorsal raphe nucleus (DRN) in rats. REM sleep deprivation was performed using the platform technique. Recording of serotoninergic neurons in the DRN revealed no difference in the basal firing rate, but a reduced inhibitory response to the selective serotonin (5-HT) reuptake blockers cericlamine and citalopram after repeated but not acute REM sleep deprivation. These observations suggest that REM sleep deprivation renders serotoninergic DRN neurons less sensitive to the inhibitory effect of 5-HT reuptake blockers, probably because of functional desensitization of somatodendritic 5-HT1A autoreceptors, like that previously reported after chronic treatment with several antidepressants. Accordingly, REM sleep deprivation might alleviate depression through neurophysiological mechanisms similar to those induced by antidepressants.

Atropine increases pilocarpine-induced yawning behavior in paradoxical sleep deprived rats

Paradoxical sleep (PS) deprivation has been suggested to induce supersensitivity of postsynaptic dopamine (DA) receptors and subsensitivity of acetylcholine (ACh) receptors. Yawning behavior is reduced after PS deprivation and is believed to result from an interaction between ACh and DA systems. Concomitant treatment of PS deprived animals with DA agonists reverses PS deprivation effects on stereotypy and aggressiveness. To examine this possibility on yawning behavior, rats were treated, during the deprivation period, with atropine, methamphetamine, haloperidol or distilled water. Following PS deprivation, rats were injected with apomorphine or pilocarpine and number of yawns was recorded. Atropine increased yawning of PS deprived rats induced by pilocarpine, but not by apomorphine. Treatment with methamphetamine and haloperidol did not change PS deprivation effect on pilocarpine- and apomorphine-induced yawning. The data suggest that reversal of PS deprivation-induced yawning inhibition is mediated distinctly by both acetylcholine and dopamine systems.

REM sleep deprivation alters dopamine D2 receptor binding in the rat frontal cortex

REM sleep deprivation (RSD) of rats results in facilitation of dopaminergic behavior and an increase in striatal D2 receptor density. To determine whether RSD results in changes in D2 receptor in other brain regions, receptor affinity (Kd) and density (Bmax) were measured in the anteromediofrontal (AM), cingulate (CN), and sulcal cortex (SL) in four groups of rats: 1), RSD96 group (RSD for 96 h; small pedestal/water tank method), 2) RSD24 group (large pedestals for 72 h then small pedestals for 24 h), 3) tank control group (TC; large pedestals for 96 h), and 4) cage control group. In separate groups, ambulation was recorded for 30 min following treatments. Group RSD96 showed an increase in activity compared to TC, and TC was increased compared to CC (p < 0.05 for all). In group RSD24, the AM showed an increase in Bmax and Kd (p < 0.05), but there were no effects by RSD96. In the CN, Bmax and Kd were decreased by RSD96 (p < 0.05) but not RSD24. In the SL, Bmax was increased by RSD96, but not RSD24, whereas Kd was increased in both RSD groups (p < 0.05).

The effects of drugs acting at GABA-benzodiazepine-barbiturate receptor complex on the behaviour of sleep-deprived mice

The effects of the benzodiazepine receptor agonist diazepam, the benzodiazepine receptor antagonist flumazenil and the benzodiazepine receptor inverse agonist ethyl-8-azido-5,6-dihydro-5-methyl-6-oxo-4H-imidazo-[1,5-a][1-4] benzodiazepine-3-carboxylate (RO 15-4513) on the locomotor activity and the behaviour of animals in the plus-maze test were studied in sleep-deprived mice. The effects of convulsants acting at GABA-benzodiazepine-barbiturate receptor complex-bicuculline, picrotoxin and pentylenetetrazole, were also studied. Sleep deprivation of mice for 24 hr using the platform technique caused behavioural excitation that was reflected by an increase in the locomotor activity. Administration of diazepam (0.5 and 2.0 mg/kg), flumazenil (5.0 and 10.0 mg/kg) and RO 15-4513 (1.0, 2.0 and 3.0 mg/kg) either did not affect (in low doses) or inhibited (in high doses) locomotions of control animals. The inhibition of locomotor activity by these drugs was greater in sleep-deprived animals. In the plus-maze test, diazepam in a dose of 2.5 mg/kg had an anxiolytic effect in control mice that was reflected by an increase in the percentage of entries onto and the percentage of time spent on the open arms of the plus-maze. In contrast, in sleep-deprived animals, diazepam did not induce anxiolytic action at any dose tested. In the highest dose (2.5 mg/kg) diazepam produced a sedative effect that was reflected by a decrease in the total number of entries made onto the open and into the closed arms of the plus-maze.(ABSTRACT TRUNCATED AT 250 WORDS)

Dissociated paradoxical sleep deprivation effects on inhibitory avoidance and conditioned fear

Rats were submitted to paradoxical sleep deprivation (PSD) for 24, 72, or 96 h and were trained on a double aversively motivated task, encompassing a step-through inhibitory avoidance and a classical conditioning of fear to a brief tone serving as conditional stimulus. Retention test of the inhibitory avoidance was performed at the same apparatus of training (without tone presentation). Retention of conditioned fear was assessed in an open field apparatus, where the freezing reaction to the tone was measured. PSD for 24 and 72 h preceding the training session had no effect on either task. However, PSD during the 96 h preceding the training session impaired acquisition of inhibitory avoidance, but had no effect on classically conditioned fear. It is concluded that PSD had differential effects on the two tasks, both aversively motivated and trained at the same time and conditions.

The effect of REM sleep deprivation on histamine concentrations in different brain areas

Rats were deprived of REM sleep (REMS) for 72 h with the platform method and decapitated in the morning immediately after the deprivation or in the afternoon after having been allowed 5 hours of rebound sleep. The histamine concentrations of the anterior and posterior hypothalamus, the cortex, the hippocampus and the pineal gland were measured, as well as the tele-methylhistamine concentrations of the anterior and posterior hypothalamus. Histamine concentrations were no different after REMS deprivation compared to large platform or dry cage controls, but in the anterior hypothalamus histamine levels increased during rebound sleep only in the REMS deprived rats. tele-Methylhistamine/histamine ratios were higher after 72 h of both REMS deprivation and the large platform treatment compared to dry cage controls, indicating increased histamine utilization during the platform treatment procedure.

Suppression of eltoprazine-induced REM sleep rebound by scopolamine

Previous studies have demonstrated that REM sleep suppression produced by the serotonin1 agonist eltoprazine (1 mg/kg b.i.d., administered i.p.) is followed by a dramatic rebound in REM sleep. In the present study, cats were treated with scopolamine (2 mg/kg b.i.d.) after 3 days of eltoprazine-induced REM sleep suppression. During scopolamine treatment, the percentage of REM sleep (9.9 +/- 3.5%) was well below baseline levels (13.7 +/- 1.6%; P < 0.05). Even after the 3-day scopolamine treatment ended, the subsequent REM sleep rebound after the combined eltoprazine-scopolamine treatment (16.8 +/- 2.8% REM sleep during 3-day rebound; P < 0.10 compared to baseline) was less than a third of the rebound normally seen after eltoprazine. These results provide evidence for the reciprocal relationship between acetylcholine and serotonin and suggest a new set-point model for the mechanism of REM sleep regulation and rebound.

REM sleep deprivation decreases apomorphine-induced stimulation of locomotor activity but not stereotyped behavior in mice

1. Effects of rapid eye movement (REM) sleep deprivation on central dopaminergic system were investigated by testing the behavioral responses to apomorphine and brain dopamine metabolism in mice. 2. REM sleep deprivation for 48 hr significantly suppressed apomorphine.HCl (3.0 and 6.0 mg/kg, i.p.)-stimulated spontaneous locomotor activity without affecting the intensity of stereotyped behavior. 3. Neither the latency of nociceptive response in a hot-plate test nor the duration of pentobarbital-induced sleep was changed by REM sleep deprivation. 4. Dopamine turnover in the striatum and the nucleus accumbens of REM sleep-deprived mice was significantly higher than that of control animals. 5. These results suggest that REM sleep deprivation may decrease the function of postsynaptic dopamine receptor in the mesolimbic but not nigrostriatal dopaminergic system.

Prenatal stress and emotional response of adult offspring

Pregnant dams were subjected to REM sleep deprivation during different stages of pregnancy. Pups were reared by their biological mothers and tested as adults for susceptibility to PTZ-induced convulsions, and ambulation and defecation in an open-field arena. Adrenal weights were taken at this time. Those animals whose mothers had been stressed during the first trimester showed a reduction in ambulatory behavior measured in the open field, and a reduction in adrenal weight after open-field exposure. Subjects exposed to prenatal stress (PNS) during the 2nd trimester showed an increased susceptibility to PTZ-induced clonic convulsions, and a reduction in adrenal weight after PTZ administration and open-field exposure. Finally, subjects exposed to PNS during the third trimester showed a reduction in susceptibility to PTZ compared with 2nd week PNS pups. The results showed different patterns of prenatal stress-induced behavioral and physiological changes, depending on the developmental stage in which the stress was applied.

Paradoxical sleep-promoting effects of brain extract from paradoxical sleep-deprived rats

Brain extract was obtained from whole brains of donor rats following four days of paradoxical sleep deprivation (PSD). Intraperitoneal injection of this brain extract in normal (i.e., not pretreated) recipient rats led to a significant increase of paradoxical sleep (PS) which was beginning at the third hour postinjection and still present on the day after treatment. Both PS episode number and PS episode duration were increased by the PSD extract, whereas slow-wave sleep was not influenced. Brain extract of nondeprived control rats, on the other hand, had no significant effects. In the present experiments, an extract volume obtained from two donor brains was transferred to one recipient. Compared to our earlier investigations (one donor brain/one recipient) this higher "dose" of PSD extract exerted a more pronounced and prolonged effect. These results support the idea that some PS-inducing factor(s) accumulating in the brain during PS deprivation may be involved in the regulation of paradoxical sleep.

Behavioral evaluation of the stress induced by the platform method for short-term paradoxical sleep deprivation in rats

To evaluate whether the results of short-term PSD (Paradoxical Sleep Deprivation) using the platform method can be influenced by stress, changes in body weight and in behavioral indices (food and water intake and ambulation and defecation in an open field) were measured in rats after each of four 5-hour sessions of confinement to small or large platforms. The animals of the two platform groups when compared to animals kept in home cages showed a similar decrease in body weight which was significant only after the first day of treatment, while no changes in the other measures were observed. It is concluded that 1) the effects of stress induced by short-term confinement to platforms do not seem to be a remarkable confounding factor in short-term PSD studies and 2) large platforms can be used both as an adequate stress control for small platforms and as a means of adapting the animals to the method.

[Comparative analysis of brain neurite-stimulating protein and nerve growth factor by using a culture of chick embryo sensory neurons]

The effect of brain neurite-stimulating protein (BNSP) on growth and differentiation of nerve cells was studied in cultured chick embryo neurons BNSP stimulated axon growth. Its chemical characteristics were different from those of neurotrophic factor (NGF). The effect of NGF antiserum was not blocked by the BNSP action. The neurite-stimulating effect of BNSP can be used for stimulation of regenerating processes in the nervous tissue.

Reversal of the increase in apomorphine-induced stereotypy and aggression in REM sleep deprived rats by dopamine agonist pretreatments

REM sleep deprivation (REMSD) induces augmented responses to dopaminergic agonists. Prolonged administration of neuroleptics induces a similar state, probably by the production of supersensitivity of dopaminergic receptors. Such a supersensitive state could be induced by REMSD as a result of impairment of dopamine neurotransmission. In order to test this hypothesis, bromocriptine, nomifensine, amphetamine, L-dopa, imipramine and electroconvulsive shock (ECS) were administered to rats during REMSD, and aggressive and stereotyped behaviors were measured. Amphetamine and L-dopa pretreatment attenuated the increases in apomorphine-induced stereotypy and aggression in REMSD rats, but ECS selectively reduced apomorphine-induced aggression. The other drugs tested were ineffective on both behavioral tests. Such a selective action may reflect different effects of ECS on different dopaminergic systems such as those involved with stereotypy and aggression. The results suggest that REMSD induces an increase in dopaminergic sensitivity which may be reversed by pretreatment with some dopaminergic agonists.

Stress-induced insomnia: opioid-dopamine interactions

REM sleep deprivation induced by means of the platform technique (72 h) was followed by a period of latency to sleep characterized by a marked excitement in rats. The administration of naloxone at the end of the REM deprivation period reduced this latency to sleep while morphine, beta-endorphin and DADLE prolonged it. The dopamine D1 receptor antagonist SCH 23390 was extremely potent (0.003 mg/kg) to reduce the latency to sleep and the excitement while the D1 agonist SKF 38393 induced an opposite effect. The dopamine D2 receptor antagonist L-sulpiride was inactive up to a dose of 25 mg/kg. These data suggest that hyperactivity of the opioid and dopamine systems (specifically mediated through D1 receptors) is involved in such behaviour.

Rapid eye movement sleep deprivation affects sleep similarly in castrated and noncastrated rats

Twenty-four-hour recordings of electrophysiological correlates of the sleep-waking cycle in castrated and noncastrated Wistar rats were performed to validate the cuff pedestal technique in the deprivation of rapid eye movement sleep. An undisturbed pattern of sleep was found in both castrated and noncastrated rats when the cuffs were in the raised position. The lowering of the cuff for 4 days virtually abolished REMs in both groups of rats. During neither the dark nor the light period was there any difference between the castrated and noncastrated rats in the total amount of REMs rebound. The results accord with the data obtained by the conventional flowerpot procedure and show that castration does not influence the amount of REMs before, during, and after REMs deprivation in the rat. It is suggested that testicular testosterone, contrary to growth hormone, is not essential for the triggering of REMs sleep, although both have anabolic actions.

The effects of buspirone on sleep in the rat

Buspirone is a novel anxiolytic compound that does not produce the sedation often associated with the use of benzodiazepines. The present study evaluated the effects of this anxiolytic on sleep in rats surgically prepared for long-term recordings. Buspirone, at a dose of 3 mg/kg i.p., produced a significant increase in total wake time (P less than 0.05) compared with drug-free controls. At a dose of 10 mg/kg i.p., rats displayed altered sleep patterns with the most significant effects observed in the first third of recording period. These animals displayed increased wakefulness (P less than 0.001), decreased non-REM sleep (P less than 0.001), and an obliteration of REM sleep (P less than 0.02). These data support the suggestion that the clinically useful anxiolytic buspirone, unlike the benzodiazepines, does not induce sleep.

REM sleep deprivation induces a decrease in norepinephrine-stimulated 3H-cyclic AMP accumulation in slices from rat brain

Beta adrenergic sites in rat brain are reduced after repeated treatment with antidepressant drugs, with REM sleep deprivation (REMSd) having the same effect. This paper reports the effects of REMSd in the production of 3H-cyclic AMP in frontal cortical slices by NE challenge. Data presented in this paper report a marked decrease in 3H-cyclic AMP synthesis after REMSd, which is in accordance with previous results showing adrenergic receptor down-regulation following REMSd. Results are discussed in view of possible interaction with dopaminergic systems and depression management.

Effects of paradoxical sleep deprivation in the rabbit

The effects of nonpharmacologically-induced deprivation of paradoxical sleep for a 24 hour period were studied in rabbits. Response characteristics commonly associated with the deprivation procedure in other species were observed, as well as features apparently peculiar to the rabbit. Like other mammals, rabbits: (1) show increased attempts to experience PS during the deprivation procedure relative to the baseline occurrence of PS; (2) become increasingly difficult to arouse from PS as the deprivation period progresses; (3) show increased amounts of PS (rebound) in post-deprivation recordings relative to baseline; and (4) compensate for only one-third of the PS deficit incurred during deprivation. Rabbits' response to PS deprivation differs from other mammals in the following ways: (1) the deprivation procedure is truly selective, significantly affecting only amounts of PS and not total sleep time or other sleep stages; (2) the rebound response is restricted to the light phase of the light-dark cycle on the first recovery day; and (3) as indexed by eye movement density, phasic activity during PS is not enhanced during the recovery period. Given that the crucial factor in the PS deprivation-compensation phenomenon is thought to be the deprivation and subsequent enhanced occurrence of phasic events, and considering that events within the oculomotor system have been emphasized in this regard, the results of this investigation suggest the existence of species differences regarding the nature and form of the compensatory response to PS deprivation.

Electrophysiological evaluation of three paradoxical sleep deprivation techniques in rats

Three different techniques were used to study the effects of 72 hr deprivation of paradoxical sleep on percentages total sleep, light slow wave sleep, deep slow wave sleep and paradoxical sleep during deprivation and recovery periods in rats. The paradoxical sleep deprivation methods used were the classical platform, the pendulum and the multiple platform techniques. The different groups were continuously recorded over a base-line day, three deprivation days and four recovery days. All three groups showed clear suppression of paradoxical sleep throughout the deprivation period, although small differences between the pendulum and the multiple platform technique emerged. The distribution of sleep across the day and the amount of deep slow wave sleep were affected differently. Besides an exception immediately after deprivation, no important differences were detected on the recovery days. The recovery is characterized by an immediate rebound of paradoxical sleep, completed within two days, as well as rapid re-normalization of sleep percentages. A small rebound of deep slow wave sleep was recorded at the end of the dark period during the first three recovery days. Various sleep and non-sleep related variables of the PS deprivation techniques are discussed. It is improbable that the platform-pendulum controversy is due to differences in the amount of PS deprivation or the other sleep parameters measured here. Rather it looks as though non-specific platform effects override the effects of PS deprivation.

Episodic excitation and changes in aggressive behavior induced by apomorphine in rats subjected to rem sleep deprivation

Behavioral changes induced by apomorphine in normal, pseudodeprived (control) and REM sleep-deprived AM-2/TOR inbred rats were investigated. Deprived rats exhibited aggressive behavior for nearly 30 min in the absence of administration of drug, this effect not being observed in normal or control rats. The administration of apomorphine (1, 2 and 5 mg/kg) 5 min before the test elicited short periods of aggressive behavior in normal and control rats, but decreased the total duration of aggressive behavior in deprived rats. However, the deprived rats exhibited a more intense aggressive behavior, since the frequency of real fighting events was enhanced. The administration of apomorphine to deprived rats elicited stereotyped behavior. Enhancement of stereotyped behavior by increasing the dose was correlated with a reduction in the duration of aggressive behavior. Apomorphine also induced short episodes of intense excitability, manifested by increased locomotor activity, jumping and vocalization. This behavioral response was termed "episodic excitation". Deprived rats were significantly more sensitive to apomorphine-induced episodic excitation than normal and control rats. The episodic excitation, stereotyped and aggressive behavior displayed by deprived rats, injected with apomorphine, alternated with time. The results demonstrate increased responsiveness to apomorphine after deprivation of REM sleep. The possible mechanism for such interaction is discussed.

Presence of a paradoxical sleep (PS) factor in the cerebrospinal fluid of PS-deprived rats

The lack of paradoxical sleep (PS) observed in rats after pharmacological blockade of the noradrenergic beta-receptors was reversed by intraventricular infusion of cerebrospinal fluid (CSF) from PS-deprived donor rats. The PS restoration in recipient animals was proportional to the duration of the deprivation in donors. It is concluded that some PS-inducing factor progressively accumulates in the CSF during deprivation. This factor acts beyond the noradrenergic step in the regulation of PS.

Dopamine metabolism and receptor sensitivity in rat brain after REM sleep deprivation

Different dopaminergic mechanisms that could explain behavioral supersensitivity to amphetamine or apomorphine in REM-deprived rats were examined. Four days of REM sleep deprivation induced a highly significant elevation in striatal DOPAC relative to normal controls, but not to stress controls. DOPAC levels in frontal cortex were not affected in any of the groups. Post synaptic D2 receptor number (Bmax) and affinity (Kd) were unchanged in both terminal regions. Similarly, no changes in pre-synaptic receptor sensitivity (apomorphine-induced inhibition of tyrosine hydroxylase) occurred in striatum. A stress control group exhibited no changes in any of the biochemical measures in comparison with either the REM deprived group or unstressed controls. Thus, the enhanced response to dopamine agonists reported previously is not due to altered dopamine receptor sensitivity. Alternative hypotheses to explain enhanced responses to direct and indirect acting dopamine agonists are discussed.

Disruption of passive avoidance memory by REM sleep deprivation: methodological and pharmacological considerations

The present experiments were designed to examine more closely the variables responsible for the disruption of passive avoidance memory produced by REM sleep deprivation. In the pharmacological study it was found that imipramine could reverse the memory disruption exhibited by rats maintained on large platforms (presumably not REM-deprived) while both imipramine and physostigmine were required to reverse the memory disruption exhibited by rats maintained on small platforms. In the methodological study it was found that those animals maintained on the smallest platforms and therefore having the largest weight to area ratio exhibited the greatest degree of memory disruption. It is concluded that further modification and verification of the platform techniques of REM deprivation is required before firm conclusions about its neurochemical basis and behavioural functions can be made.

Sleep patterns during rearing under different environmental conditions in juvenile rats

Male Wistar rats were chronically implanted at weaning with electrodes for recording EEG amd EMG. From one month of age, they were randomly assigned to either 24 h or 2 h daily 'enriched' (EC), 'standard' (SC) or 'isolated' (IC) rearing conditions. The 24 h-EC group showed the following changes with respect to both the SC and the IC groups: (a) more quiet sleep time; (b) more active sleep time, and (c) shorter active sleep latency. These differences were evident by the third week of environmental conditioning, became statistically significant by 4 weeks, and continued to increase throughout the rest of the enrichment period. None of the sleep parameters showed any significant differences between the SC and the IC groups. The 2 h-EC rats showed an increase in both quiet sleep and active sleep time during the experimental period, whereas the controls showed the expected decline. Morphological investigations at 3 months of age revealed a significant weight increase in the cerebral cortex, and even more so in the hypothalamus as compared with the control group in the 2 h-EC rats.

Quantitative analysis of short term deprivation and recovery of desynchronized sleep in cats

A quantitative analysis of desynchronized sleep (DS) deprivation (exposure to low ambient temperature) and recovery was carried out in unrestrained cats. The results show that: (1) the circadian obligate quota of DS is precisely regulated by a control mechanism paying by the 24th h the DS debt induced by up to 14 h of total DS deprivation, if recovery occurs during the rest phase of circadian photoperiodicity (CP); (2) during static rebound DS hourly duration is increased by 40 +/- 4 sec/h of total deprivation (mean and S.E.) and there is a statistically significant increase in the hourly frequency and in the duration of DS episodes, with respect to control values; (3) the hourly obligate and facultative quotas of DS amount to 409 +/- 82 and 229 +/- 140 sec/h (mean and S.D.), respectively. (4) preoptic heating during deprivation at low ambient temperature decreases the DS static rebound during recovery at control ambient temperature by an amount corresponding to the cumulative duration of DS episodes elicited by the preoptic treatment; (5) preoptic temperature decreases the more markedly the shorter the duration of exposure to low ambient temperature and regains control values the sooner the smaller the DS debt incurred during deprivation; (6) DS debt cumulation is a continuous process which develops at a steady rate during day and night, whereas DS debt payment is a discontinuous process (ultradian rhythm of DS) which develops at a variable rate depending on the DS debt and on the phase of CP.

Behavior-dependent evoked potentials in the hippocampal CA1 region of the rat. I. Correlation with behavior and EEG

As an alternative approach to the study of hippocampal function in relation to behavior, the averaged evoked potentials (AEPs) evoked by electrical stimulation of the Schaffer collaterals (SCH), the alveus and the contralateral hippocampus were recorded at various depths in the hippocampal CA1 region of freely moving rats with chronically implanted electrodes. Significant correlations between AEPs, behavior and EEG were found. At one end of the continuum of AEPs were those recorded during large irregular activity (LIA), an EEG pattern associated with slow-wave sleep or awake-immobility. These AEPs had large early peak and low-amplitude late peaks. At the order end of the continuum, during high frequency theta EEG associated with behaviors such as walking, postural change or phasic paradoxical sleep. AEPs had a smaller early peak, increased later peak(s) and appeared oscillatory. The evoked population spike, a synchronous postsynaptic firing of CA1 neurons, was smaller during behaviors associated with theta than during those associated with LIA. It is postulated that a recurrent inhibitory circuit within the hippocampus can account for the change of the AEPs with EEG and behavior and with stimulus intensity. During theta EEG, the negative feedback may increase such that the evoked population excitatory postsynaptic potential and the evoked population spike decrease and ascillatory response is more readily elecited. The excitability state of hippocampal CA1 may be described by the negative feedback gain in this model.

Elimination of REM sleep rebound in rats by alpha-adrenoreceptor blockers, phentolamine and phenoxybenzamine

Two alpha-adrenoreceptor blocking agents, phentolamine (5 mg/kg, IP) and phenoxybenzamine (10 mg/kg IP) were administered to rats deprived of rapid eye movement (REM) sleep for 24 hours to test the hypothesis that reduced noradrenergic transmission may abolish REM sleep rebound. The hypothesis was based on results from our previous studies which showed that administration to rats of diethyldithiocarbamate (DDC), a dopamine beta hydroxylase inhibitor, decreased the concentration of brain norepinephrine and reduced REM sleep permanently without the subsequent appearance of REM sleep rebound. Present results show that administration of both alpha-adrenoreceptor blockers abolished REM sleep rebound. At the time of maximum reduction of REM sleep, the concentration of 3-methoxy-4-hydroxyphenylethyleneglycol sulfate (MOPEGSO4), a final product of norepinephrine metabolism in the brain, was found increased in the whole brains of rats suggesting that the selected doses of the drugs were sufficient to produce effective central alpha-adrenergic receptor blockade. These data indicate that the action of both alpha-adrenoreceptor blocking agents in noradrenergic system was paralleled by the permanent loss of REM sleep and support the hypothesis implicating reduced noradrenergic transmission in elimination of REM sleep rebound.

Selective deprivation of paradoxical sleep and consolidation of shuttle-box avoidance

Investigated whether paradoxical sleep is implicated in the storage of information acquired during shuttle-box avoidance. Wistar rats were given 5 brief training sessions distributed over the light period of the diurnal cycle. During the intervals between sessions the animals were selectively deprived of paradoxical sleep by awakening them every time they showed this type of sleep. The onset of paradoxical sleep was identified when hippocampal theta rhythm occurred during behavioural sleep. Yoked control animals got the same treatment irrespective of their sleep-waking behaviour, whereas free sleep rats were allowed to sleep undisturbed. In spite of large differences in the amount of paradoxical sleep during the intersession intervals no differences in learning performances were found among the groups. A tendency toward more intertrial crossings was noted in the paradoxical sleep deprived group at the end of training. It is concluded that storage of information acquired during distributed shuttle-box avoidance is not dependent on the presence of paradoxical sleep immediately following learning. Some possibilities are considered that paradoxical sleep may still be involved in memory storage processes.