Prediction of uphill time-trial bicycling performance in humans with a scaling-derived protocol.

Abstract

The present study sought to create a scaling-derived cycle ergometer protocol (SDP) that was derived theoretically and would correlate highly with actual uphill time-trial (TT) cycling performance. Local competitive cyclists each completed the SDP (an incremental test to exhaustion) using their own bicycle mounted on a stationary trainer, together with either a short (6.2 km, 2.9% grade; n = 8 men and 5 women) or long-course (12.5 km, 2.7% grade; n = 8 men) uphill TT. Maximal power output (Wmax) and power at the ventilatory threshold (WVT) were determined from the SDP results, as well as maximal oxygen uptake (VO2max), using standard indirect calorimetry procedures. Actual TT speed correlated very highly with both SDP completion time (r = 0.97-0.98) and relative Wmax (watts per kilogram; r = 0.92-0.97) for both uphill TT races. Correlations between TT speed and more demanding measurements (VO2max, WVT) (VO2max, WVT) were generally lower and more variable (r = 0.54-0.97). These results would indicate that two non-laboratory dependent measurements (SDP completion time and relative Wmax) derived from the SDP are valid markers for predicting actual uphill TT performance. This protocol may be useful to cycling coaches and athletes in identifying talented cyclists or for tracking changes in cycling performance outside of the sports science laboratory environment.