Pulmonary gas exchange and its determinants during sustained microgravity on spacelabs sls-1 and sls-2. Prisk, G. Kim, Ann R. Elliott, Harold J. B. Guy, Janelle M. Kosonen, and John B. West. Department of Medicine, University of California, San Diego, La Jolla, CA 92093-0931
APStracts 2:0260A, 1995.
We measured resting pulmonary gas exchange in 8 subjects exposed to 9 or 14 days of microgravity ([mu]G) during two Spacelab flights. Compared with preflight standing measurements, [mu]G resulted in a significant reduction of tidal volume (15%) but an increase in respiratory frequency (9%). The increased frequency was chiefly caused by a reduction in expiratory time (10%) with a smaller decrease in inspiratory time (4%). Anatomic deadspace (VDA) in [mu]G was between preflight standing and supine values, consistent with the known changes in FRC. Physiologic deadspace (VDB) decreased in [mu]G, and alveolar deadspace (VDB -VDA ) was significantly less in [mu]G than preflight standing (-30%) or supine (-15%), consistent with a more uniform topographical distribution of blood flow. The net result was that although total ventilation fell, alveolar ventilation was unchanged in [mu]G compared with standing 1-G. Expired vital capacity was increased (6%) compared with standing but only after the first few days of exposure to [mu]G. There were no significant changes in O2 uptake, CO2 output, or end-tidal PO2 in [mu]G compared with standing 1-G. End-tidal PCO2 was unchanged on the 9 day flight, but increased by 4.5 Torr on the 14 day flight where the PCO2 of the spacecraft atmosphere increased by 1 to 3 Torr. Cardiogenic oscillations in expired O2 and CO2 demonstrated the presence of residual ventilation-perfusion ratio (V.A/Q. ) inequality . In addition, the change in intra-breath V.A/Q. during phase 3 of a long expiration was the same in [mu]G as preflight standing indicating persisting V.A/Q. inequality, and suggesting that during this portion of a prolonged exhalation the inequality in 1-G was not predominately on a gravitationally-induced topographical basis. However the changes in PCO2 and V.A/Q. at the end of expiration following airway closure were consistent with a more uniform topographical distribution of gas exchange. 

Received 19 December 1994; accepted in final form 12 May 1995.
APS Manuscript Number A1283-4.
Article publication pending Journal of Applied Physiology.
ISSN 1080-4757 Copyright 1995 The American Physiological Society.
Published in APStracts on  6 July 1995.