Early dynamics of O2 uptake and heart rate as affected by exercise work rate

Abstract

The kinetics of O2 uptake (.hivin.VO2) and heart rate (HR) in response to constant work rate exercise have been characterized as two phases, an immediate response as the result largely of abrupt hemodynamic changes and a slower response as the result of increases in both blood flow and arteriovenous O2 difference (avDO2). There are few data reported concerning .ovrhdot.VO2 and HR during phase I or the relationship between their kinetics and work rate or intensity. Because phase I responses depend on abrupt cardiovascular adjustments, it was hypothesized that phase I increases in .ovrhdot.VO2 and HR would be greater the more "fit" the subject and would be relatively independent of work rate. To test this, 10 normal subjects exercised from rest to each of five work rates ranging from unloaded cycling to 150 W. The phase I increases of .ovrhdot.VO2, HR, and .ovrhdot.VO2/HR had small but significant correlations with work rate but not with fitness. At very low work rates (unloaded cycling and 25 W), .ovrhdot.VO2 and HR often exceeded their steady-state levels in phase I. There was therefore no phase II increase for .ovrhdot.VO2 or HR at these work rates, the entire O2 requirement having been met by phase I circulatory adjustments. For all other work rates, mean response times for .ovrhdot.VO2 and HR were related to fitness and were slower than those for .ovrhdot.VO2/HR, suggesting that avDO2 reached a steady state before cardiac output did.