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| The Experimental Study of Effect of Simulated Weightlessness on Electrical Impedance Spectroscopy of Rat Blood |
| Ningbo University School of Medicine, Ningbo 315211,China |
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Abstract The aim of this work is to explain the mechanisms of electrophysiological changes in rat blood cell by using RC equivalent circuit model under simulated weightlessness. Simulating weightlessness model was established by rat tail suspension. Electrical impedance spectroscopy of rat blood on the control and tail suspension group was performed using Aligent 4294A impedance analyzer. Electrical parameters (resistivity and capacitance) of blood were compared between the control and tail suspension through numerical calculation of equivalent circuit model and curve fitting analysis. After 60 days post simulating weightlessness, decrease in the hematocrit (Hct) and resistivity of the erythrocyte membrane were compared with that of normal group. Experimental reuslts showed that the decrease in extracellular and intracellular resistivity was 16.44% and 1.54% respectively, the cell membrane and intracellular capacitance decreased by 4.66% and 0.83% respectively, but extracellular capacitance remained unchanged. The rat blood hematocrit (Hct) and erythrocyte membrane resistivity were significantly reduced in the simulating weightlessness model, which led to reduction in electrical impedance of the extracellular fluid and whole blood, thus gave rise to electrical conductivity. The electrical impedance spectroscopy moved to low resistance direction.
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