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Publication Abstracts

Rat Growth, Body Composition, and Renal Function During 30 Days Increased Ambient CO₂ Exposure

Charles E. Wade, Ph.D., Tommy J. Wang, M.S., Kevin C. Lang, B.A., Barbara J. Corbin, B.S., and Marianne K. Steele, Ph.D.
Aviat Space Environ Med 2000; 71:599-609

Abstract

Background: In experiments using rodents onboard orbiting spacecraft, specimens may be exposed to an increase in ambient CO₂. Hypothesis: Many of the physiological changes reported in rats (and humans) for spaceflight are similar to those observed with increased CO₂, raising the question whether the observed changes are due to spaceflight or more specifically, the elevated ambient CO₂. Methods: To evaluate the effects of increased CO₂, at levels similar to those experienced during spaceflight, three groups of adult male rats (n = 10) were exposed to ambient CO₂ concentrations of 0.3, 0.7 and 2.0% for 30 d. Control rats were exposed to atmospheric conditions (0.03% CO₂) for each group. Results: There were alterations in water turnover, food intake, and renal function with increased CO₂. Blood pH, total CO₂, and plasma concentrations of Na⁺, Ca²⁺, and corticosterone were significantly elevated at the 2.0% exposure, while plasma PO₄^3- was reduced. At the 0.3% and 0.7% CO₂ exposures, many of these changes were not significant. Animals exposed to 0.3% CO₂ showed a significant increase in total body Na+. Urinary Ca²⁺, K⁺, creatinine, corticosterone, and total CO₂ excretion were higher at 2.0%, but only Ca²⁺ and CO₂ excretion were significantly elevated at 0.7%, and there was no significant alteration in renal function at 0.3%. Conclusion: Chronic increased ambient CO₂ levels, similar to those observed on the Space Shuttle and proposed for the International Space Station, elicit compensatory responses in rats which may affect interpretation of experiments designed to evaluate the effects of exposure to microgravity.

Keywords: hypercapnia, respiratory acidosis, acid-base balance, electrolyte excretion.

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Table of Contents for Volume 71, Number 6 of the ASME journal.