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Journal of Applied Physiology, Vol 67, Issue 3 1106-1112, Copyright © 1989 by American Physiological Society
ARTICLES |
R. Casaburi, J. Daly, J. E. Hansen and R. M. Effros
Division of Respiratory and Critical Care Physiology and Medicine, Harbor-UCLA Medical Center, Torrance 90509.
It has been assumed that increases in both O2 uptake and ventilation occurring within the first few seconds after the onset of exercise cannot be the result of changes in blood gas composition reaching the central circulation because of the circulatory delay from the exercising limbs (A. Krogh and J. Lindhard, J. Physiol. Lond. 42: 112-136, 1913). We sought to validate this assumption by measuring the time course of pulmonary arterial blood gases during the transition from rest to exercise. Six healthy men underwent pulmonary arterial catheterization and then performed transitions from rest to moderate cycle ergometer exercise. An anaerobic sampling manifold withdrew 19 samples of blood during the rest-to-exercise transition; sampling interval was usually 4 s. Blood gas analysis showed that, on average, from rest-to-steady-state exercise, O2 saturation (Svo2) fell from 71 to 41% and mixed venous PCO2 (PvCO2) rose from 42 to 59 Torr. Contrary to our expectations, Svo2 decreased and PvCO2 increased with no discernible latency after exercise onset (by 10% and 2 Torr, respectively, within 6 s). The half time for the Svo2 decrease was 32 s, whereas for the PvCO2 increase it was 80 s. The time course of superior vena cava blood gas composition was determined in several experiments; no rapid changes after exercise onset were found. We conclude that at exercise onset there is a rapid fall in Svo2 and rise in PvCO2 well in advance of arrival of blood produced by exercising legs.(ABSTRACT TRUNCATED AT 250 WORDS)
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