Effects of Protein Malnutrition on Vigilance States and their Circadian Rhythms in 30-Day-Old Rats Submitted Total Sleep Deprivation

Prenatal protein malnutrition induces a phase shift advance of the spontaneous locomotor rhythm and alters the rest/activity ratio in adult rats

Evidence is accumulating for significant structural and functional changes within the central nervous system (CNS) following prenatal protein malnutrition. Included among the structures that are likely to be affected are the suprachiasmatic nuclei (SCN) involved in the regulation of locomotor activity, sleep-wake cycle, and drinking behavior. To determine the effects of prenatal protein malnutrition on the spontaneous activity rhythm, 24 h radiotelemetric measurements were recorded over an 8-day period. Male offspring of rats provided with protein-deficient (6% casein) or adequate (25% casein) diets for 5 weeks prior to mating and throughout pregnancy were studied. Well nourished rats displayed a rise in activity level during the first hour of the 12h light phase, whereas prenatally malnourished rats displayed this increase during the 12h dark phase, approximately 50 min before lights on, reflecting a significant phase advance in this group. In addition, cosinor analysis revealed that the alpha/rho relationship was affected in the previously malnourished group, the activity phase being shorter than in the well-nourished animals. These findings suggest changes in the regulatory systems controlling the locomotor activity rhythm as a consequence of prenatal protein malnutrition. Alterations in entrainment to the light-dark cycle, and/or in the coupling force of the circadian oscillators are all candidate mechanisms.

Prenatal malnutrition and sleep states in adult rats: effects of restraint stress

Independently, prenatal malnutrition and psychological/physical stress have been shown to affect sleep architecture in adult rats. As malnutrition and stress commonly co-exist in malnourished human populations, the objective of the present study was to ascertain the combined effects of these two insults by examining sleep-wake parameters following a brief restraint stress in prenatally protein malnourished rats. The male offspring of rats provided with a protein deficient diet (6% casein) for 5 weeks prior to mating and throughout pregnancy were implanted with recording electrodes beginning at postnatal day 90. Polygraph recordings were obtained to quantify sleep states during the first 4 h of the dark phase of the cycle on 2 consecutive days. The first followed a 24-h habituation session to the recording chamber (baseline). The second occurred at the same time of day but followed 20 min of restraint stress in a Plexiglas tube. During baseline, prenatally malnourished rats spent more time in rapid eye movement sleep (REMS) in the first 2 h after "lights off" (block 1), and greater amounts of wakefulness (W) with a corresponding reduction in slow wave sleep (SWS) in the second two hours (block 2), as compared with controls. Following stress, the sleep architecture of both groups of rats remained unaltered in block 1 relative to their baseline day. In block 2, both groups exhibited significant reductions in SWS and REMS with significantly greater reductions being expressed in the prenatally malnourished group (most dramatically, REMS was completely eliminated). These findings suggest that sleep disturbances may be more severe in those malnourished human populations subjected to acutely stressful experiences.

Circadian rhythms of occipital-cortex temperature and motor activity in young and old rats under chronic protein malnutrition

The circadian rhythm of cortical temperature registered in the right occipital cortex and the circadian rhythm of motor activity were studied in young and old rats submitted to a chronic malnutrition paradigm. Circadian rhythms of cortical temperature and motor activity in Control (25% casein) and Malnourished (6% casein) Sprague-Dawley male rats were registered by telemetry along different lighting conditions. Results indicate that: (1) there are masking effects of light upon the period of cortical temperature in malnourished-old rats, (2) cortical temperature and motor-activity rhythms, show endogenous periods different from 24-h under free-running conditions, (3) protein malnutrition increases the amplitude and the mean value of cortical-temperature rhythm in malnourished-young rats, (4) aging decreases the amplitude and mean value of the motor-activity rhythm, (5) the acrophase of cortical temperature is delayed in malnourished-old rats, and (6) the temporal relationship between cortical temperature and motor-activity circadian rhythms is altered in malnourished-young and old rats. Therefore, this study provides evidence that protein malnutrition produces long-lasting alterations in the architecture of the circadian system, particularly affecting cortical-temperature oscillation. These changes might indicate thermoregulatory differences in the brain of malnourished rats that could be related to metabolic and behavioral alterations due to protein malnutrition.

Pre- and post-natal protein malnutrition alters the effect of rapid eye movements sleep-deprivation by the platform-technique upon the electrocorticogram of the circadian sleep-wake cycle and its frequency bands in the rat

Selective deprivation of paradoxical (or rapid eye movements) sleep (REMS) in protein malnourished young male rats, results in circadian and homeostatic alterations. By means of electrocorticographic recordings, we have examined the sleep-wake cycle as a functional maturity index, and its circadian and homeostatic mechanisms in prenatal (PM) and chronically (CM) protein malnourished young male rats. The effects of rapid eye movements sleep-deprivation (REMS-D), by the platform technique in a "conflict experiment" (i.e. recovery from REMS-D begun during the circadian phase of activity), revealed that in PM animals, wake (WAK) was increased significantly during recovery days 1 and 2 (RD1, RD2); and slow wave sleep (SWS) was reduced significantly during these days. Prenatal protein-malnutrition altered the phase of WAK and REMS rhythms, and the amplitude of SWS rhythm was decreased. The REMS compensatory increase after REMS-D (REMS rebound) was confined to the first 4-h block of the activity phase in all experimental groups and 24 h later another REMS rebound was displayed in PM animals. The paradoxical sleep-rebound in CM animals was significantly higher than control and PM rats and it was only shown at the first 4-h block after REMS-D. Before and after REMS-D the circadian distribution of both sleep states, and the electrocortical frequency bands showed different circadian phases at the same day-time in control, PM and CM rats. The aforementioned indicates that protein malnutrition exerts important effects on the circadian and homeostatic mechanisms driving sleep. Therefore, the temporal structure of the malnourished rats may not allow proper synchronization of some sleep parameters, particularly REMS, to the environmental time cues.