Sleep and hypometabolism

Abstract

Metabolic rate (MR) of endotherms is lower during sleep than quiet wakefulness (W), largely as a result of a regulated lowering of body temperature (T_b) during slow-wave sleep (SWS). In mammals this decrease in regulated T_b is evidenced by a lowered hypothalamic thermosensitivity. In avian thermoregulatory systems spinal thermosensitivity is lower in SWS than in W. In rapid eye movement sleep (REMS) there is a severe inhibition of the thermoregulatory systems. Hypothalamic cells that are thermosensitive during W become less so during SWS and become totally insensitive to temperature during REMS. The adjustments in thermoregulatory systems of endotherms that result in lower T_b and MR during SWS have been shaped by natural selection in different species to produce a variety of adaptations for energy conservation. Bouts of torpor, hibernation, or nocturnal hypothermia consist mostly of SWS, and these states involve a downward resetting of hypothalamic thermosensitivity in mammals and spinal thermosensitivity in birds. A physiological mechanism underlying this change in regulation of T_b may be related to the regulation of breathing and acid–base balance. Retention of CO₂ occurs at the onset of sleep, shallow torpor, and hibernation and release of excess CO₂ occurs when these states are reversed by arousal. Increased plasma CO₂ may have a direct effect on hypothalamic neurons involved in thermoregulation, resulting in a decline in regulated T_b.