The pulmonary oxygen uptake (VO₂) response to incremental-ramp cycle ergometry typically demonstrates lagged-linear first-order kinetics with a slope of ~10-11 ml·min^-1·W^-1, both above and below the lactate threshold (θ_L), i.e. there is no discernible VO₂ slow component (or “excess” VO₂) above θ_L. We were interested in determining whether a reverse ramp profile would yield the same response dynamics. Ten healthy males performed a maximum incremental -ramp (15-30 W·min^-1, depending on fitness). On another day, the work rate (WR) was increased abruptly to the incremental maximum and then decremented at the same rate of 15-30 W.min^-1 (step-decremental ramp). Five subjects also performed a sub-maximal ramp-decremental test from 90% of θ_L. VO₂ was determined breath-by-breath from continuous monitoring of respired volumes (turbine) and gas concentrations (mass spectrometer). The incremental-ramp VO₂-WR slope was 10.3 ± 0.7 ml·min^-1·W^-1, whereas that of the descending limb of the decremental ramp was 14.2 ± 1.1 ml·min^-1·W^-1 (p < 0.005). The sub-maximal decremental-ramp slope, however, was only 9. 8 ± 0.9 ml·min^-1·W^-1: not significantly different from that of the incremental-ramp. This suggests that the VO₂ response in the supra-θ_L domain of incremental-ramp exercise manifest not actual, but pseudo, first-order kinetics.

• The slope of the decremental-ramp response is appreciably greater than that of the incremental.

• The response dynamics in supra-θ domain of the incremental-ramp appear not to manifest actual first-order kinetics.

• The mechanisms underlying the different dynamic response behaviour for incremental and decremental ramps are presently unclear.