The effect of motion sickness on the sleep–wake cycle in rats exposed to prenatal hypoxia

This study is a follow-up to our previous research of the phenomenology and mechanisms of motion sickness (MS) and its relationship with changes in the sleep–wake cycle (SWC). We report data on the effect of MS on the SWC in 30-day-old intact rats and those exposed to prenatal hypoxia on days 13 and 19 of gestation. In all animal groups, MS was shown to decrease significantly the waking time and increase that of paradoxical sleep (PS). A link between hypothalamic MS and SWC regulatory mechanisms was revealed, and the role of this teamwork in the development of the sopite syndrome, which may be a sole manifestation of MS in some animals and man, was suggested. It was established that hypoxic exposure on day 19 of gestation had a greater damaging effect on the thalamocortical sleep-regulating structures than that on day 13, when it is only the hypothalamic-hippocampal slow-sleep regulatory systems that were found to be affected. Against this background, MS appreciably suppresses the brain excitatory systems that maintain wakefulness (supposed to be the ascending reticular activating system) and enhances those activating systems that regulate PS. It is exactly prenatal hypoxic exposure of rats on day 19 of gestation that enabled demonstrating the role of the evolutionarily young thalamocortical system in PS control.