Deprivation Motor

Motion deprivation is a condition when a person cannot move freely, for example, due to space limitations, lack of gravity or other factors. Movement deprivation can be caused by various reasons, such as injury, illness, surgery, stroke, etc.

Movement deprivation can lead to various health problems such as poor circulation, decreased muscle strength, poor coordination, as well as psychological problems such as depression, anxiety and insomnia.

To prevent movement deprivation, it is necessary to engage in regular physical activity, especially stretching and muscle strengthening exercises. It is also important to monitor your diet and lifestyle to maintain a healthy weight and avoid obesity.

If movement deprivation occurs, you should consult a doctor for diagnosis and treatment. In some cases, special exercises or orthopedic devices may be required to restore motor function.

Movement deprivation is a violation of the ability to move as a result of restriction of human movements in conditions of space flight or ultra-small artificial space objects. Deficiency of motor activity in weightlessness can cause autonomic, neuroendocrine, metabolic and neuropsychiatric effects. Due to weightlessness, a number of tissue microtraumas, metabolic, circulatory and trophic disorders occur. In addition, the deprived vestibular apparatus has increased tone, venous outflow of blood decreases and the volume of circulating blood decreases, and lymphatic drainage is also impaired. Finally, hypokinesia, due to changes in the coupling of breathing and blood circulation, causes hypercapnia, tachycardia, hypotension, degenerative processes of organs and disruption of their functioning.

The experimental requirements for the SPVC (space filtering bicycle ergometer) include: multisystem adaptive neuroregulation through hemorheological hemosynaptics (through the central nervous system with specific control of the blood-brain barrier), hypoxic hypercapnic hypoxia and stress, interstitial hypoxia, hypobaric hypoxia. KFVK models in a living organism the spatiotemporal factors of the combined action of intense physical exercise (dynamic) with simultaneous forced breathing, which makes it possible to include a high-energy process of using the chemical resources of cells for enhanced neuromyofibrillar adaptation to the conditions of depressurization and ground-space tests of space flight, by analogy with increasing loads on BVK in terrestrial living conditions. The oxygen transport system is trained, physical and mental readiness for space flight is trained, and nasal breathing function is restored. The resulting component of O2 gas exchange per unit time affects the vessels of the brain and other specific systems of the body and forms an adaptive state necessary to accelerate the processes of adaptation and desynchronization of cardiocentral hypoxia during depressurization.