Immersible ergocycle prescription as a function of relative exercise intensity

Purpose: The purpose of this study was to establish the relationship between various expressions of relative exercise intensity percentage of maximal oxygen uptake(%VO), percentage of maximal heart rate(%HR), %VOreserve(%VOR), and %HR reserve(%HRR)) in order to obtain the more appropriate method for exercise intensity prescription when using an immersible ergocycle(IE) and to propose a prediction equation to estimate oxygen consumption(VO) based on IE pedaling rate(rpm) for an individualized exercise training prescription.Methods: Thirty-three healthy participants performed incremental exercise tests on IE and dryland ergocycle(DE) at equal external power output(Pext). Exercise on IE began at 40 rpm and was increased by 10 rpm until exhaustion. Exercise on DE began with an initial load of 25 W and increased by 25 W/min until exhaustion. VOwas measured with a portable gas analyzer(COSMED K4b~2) during both incremental tests. On IE and DE, %VOR, %HRmax, and %HRR at equal Pext did not differ(p > 0.05).Results: The %HRR vs. %VOR regression for both IE and DE did not differ from the identity line %VOR IE = 0.99 × HRR IE(%) + 0.01(r~2= 0.91, SEE = 11%); %VOR DE = 0.94 × HRR DE(%) + 0.01(r~2= 0.94, SEE = 8%). Similar mean values for %HRmax, %VOR, and %HRR at equal Pext were observed on IE and DE. Predicted VOobtained according to rpm on IE is represented by: VO(L/min) = 0.000542 × rpm2-0.026 × rpm + 0.739(r = 0.91, SEE = 0.319 L/min).Conclusion: The %HRR–%VOR relationship appears to be the most accurate for exercise training prescription on IE. This study offers new tools to better prescribe, control, and individualize exercise intensity on IE.