ABSTRACT
Head-down tilting of primates (HOT) is a universal method of studying the hypokinetic syndrome effects on functionality of various body systems. Clinical biochemical blood assay was performed in a 25-day HDT experiment (-5 degrees) with 11 Macaca rhesus. One group of animals was kept tilted all the time through, whereas the other was periodically returned into the orthostatic position for 30 to 120 minutes 4-5 times a week. Dry chemistry was employed in biochemical analysis of blood serum and enzyme immunodetection (EID) in measuring blood hormones. As a rule, the biochemical parameters of primates' serum were within the physiological norm range. Shifts in protein, carbohydrate and mineral metabolism were sought for and enzymic activity in blood serum and hormone concentrations were determined. HDT did not produce noteworthy changes in blood concentrations of somatotropic hormone, thyrotrophic hormone (TTH), triiodothyronine (T3), thyroxine (T4) or cortisol. Animals of both groups showed statistically reliable decrease in blood osteocalcine. The preventive complex did not contribute materially to the control of metabolic homeostasis and endocrine function of the primates adapting to the 25-day HDT.
Subject(s)
Gravitation , Periodicity , Animals , Biomarkers , Macaca mulatta , Male , Time FactorsABSTRACT
Biochemical parameters of protein, carbohydrate, and fluid-electrolyte metabolism were measured in the blood of Bion 11 rhesus monkeys. The 14-day flight induced changes in total protein, BUN, and calcium, which were also seen in humans during long-duration space missions. It was concluded that protein and calcium metabolism changed while carbohydrate metabolism remained unaltered.
Subject(s)
Blood Glucose/metabolism , Blood Proteins/metabolism , Calcium/metabolism , Space Flight , Weightlessness , Adaptation, Physiological , Animals , Blood Urea Nitrogen , Calcium/blood , Macaca mulatta , Male , Serum Albumin , Water-Electrolyte Balance/physiologyABSTRACT
High-molecular polymers apt to directly influence flow microstructure were tested as a fundamentally new method for correcting microhemodynamics in microgravity. Pressure in the mesenteric arterial microvessels was measured two weeks in rats adapted to the head-down suspension. Intravenous polyethylene oxide (Polyox WSR-301, end-concentration in the order of 2.10(-7) g/ml), reduced the microvascular pressure by 26%, whereas in the control pressure was reduced by only 15%. Systemic arterial pressure showed an equal drop in the groups (by 10 to 11%). These results suggest that the biomechanical agent weakens resistance to the blood flow in the body region where blood supply is impaired by microgravity.