Pathophysiological mechanisms of neurological disorders in experimental animals exposed to vibration

Abstract

The review presents an analysis of literature on the study of nervous system changes in experimental animals exposed to vibration. The hypoxic type of cellular metabolism against the background of vibration is the result of vascular mechanoreceptors stimulation and spasm of blood vessels as well as intravascular pressure phase fluctuations and impaired blood and lymph outflow. Hemodynamic disorders and microangiopathy in the central nervous system can reach the level of cerebral vascular impairment and capillary-trophic insufficiency of the brain. Changes in calcium homeostasis at the cellular and tissue levels is a key mechanism of neuronal destruction occurring alongside with impaired blood supply to the nervous tissue in patients with vibrational disease. Long-term exposure to vibration results in reduced tissue respiration in the brain structures of experimental animals, that is most pronounced in the cortex and leads to a pathological change of spontaneous electrical activity of brain structures. Acute vibration stress stimulated the synthesis and excretion of serotonin not only in the hippocampus and hypothalamus but also in the cerebellum, which explains the disturbances of the oculomotor reactions observed in vibration exposure in the control system of the vertical vestibular ocular reflex. A decrease in the total number of neurons as well as an increase in the number of astroglia cells against the background of paravascular tissue edema were revealed against the background of changes in neurotransmitters levels. An increase in the concentration of the biomarker of structural and functional damage to brain tissue specific protein S-100B accompanies the development of professional sensorineural hearing loss and dysfunction of cerebral level vegetative regulation.