112 Chronic sleep restriction disrupts slow-wave sleep homeostatic regulation and damages monoaminergic structures in the rat brain

Abstract

\n \n \n The neurophysiological mechanisms underlying long-term neurological and cognitive disorders associated with chronic sleep restriction (CSR) are not fully understood. Here we evaluated how the sleep-wake cycle changes during and after a period of sleep restriction in rats, and whether CSR results in neurodegeneration in monoaminergic brain structures.\n \n \n \n For CSR, 7-8-month-old Wistar rats underwent cycles of 3 h of sleep deprivation (SD) and 1 h of sleep opportunity (SO) continuously for 5 days on the orbital shaker. Telemetric sleep recordings were made before, during, and after CSR. Neurodegeneration in brain monoaminergic structures was assessed immunohistochemically.\n \n \n \n During SD, wakefulness comprised 85% of the total registration time; the remaining time was represented by drowsiness with low EEG delta power. Rapid eye movement sleep (REMS) was absent. During CSR, slow-wave sleep (SWS) and REMS were reduced by 62% and 57%. Total SWS time during SO periods increased on the first CSR day, but decreased to the baseline by the fifth CSR day. SWS EEG delta power (a measure of sleep intensity) decreased gradually from the first to the fifth CSR day. REMS total time remained elevated during all SO periods. During the first recovery day after CSR, SWS did not change, but REMS increased by 30%. No changes in total sleep time were found on the second recovery day but sleep intensity was decreased. In 14 days after CSR, all sleep parameters returned to the baseline. We revealed a loss of 24% of noradrenergic locus coeruleus neurons, 29% and 17% of dopaminergic neurons in the substantia nigra, the ventral tegmental area as well as in their striatal terminals.\n \n \n \n We consider CSR as a damaging factor leading to a gradual suppression of homeostatic mechanisms governing sleep recovery. CSR can provoke neurodegeneration in monoaminergic structures involved in the regulation of emotional behavior, sleep, and autonomic functions.\n \n \n \n Ministry of Science and Higher Education of the Russian Federation grant (No. 075-15-2020-916 dated November 13, 2020) for the establishment and development of the Pavlovsky Center “Integrative Physiology for Medicine, High-Tech Healthcare and Stress Resilience Technologies”.\n