Abstract
PURPOSE: Understanding physiological determinants of lactate threshold 2 (LT2) is crucial for tracking adaptations and deriving individualized training recommendations in cycling. Therefore, the study investigated: 1. the accuracy of modeling power output at LT2 in young athletes of both sexes using maximal oxygen uptake ( V˙O2peak ), fractional utilization of V˙O2peak (% V˙O2peak ), and oxygen cost of cycling (Cc); 2. the influence of Cc determination on the model accuracy; 3. the influence of the model predictors and inclusion of maximal lactate accumulation rate ( c˙Lamax ) on power at LT2 depending on sex. METHODS: Eighty-three cyclists and triathletes (22 females, 61 males; age [median and IQR]: 14.6 [13.8-17.6] years, V˙O2peak [mean ± SD]: 59.2 ± 6.5 mL⋅kg(-1)⋅min(-1)) performed an incremental test to determine power at LT2, V˙O2peak, % V˙O2peak at LT2, and Cc (assessed at 3 W⋅kg(-1), 75% V˙O2peak, and 90% LT2). RESULTS: Modeled and experimentally determined power at LT2 demonstrated excellent agreement for all, male and female athletes (ICC ≥ 0.961), with Cc at 90% LT2 providing the highest accuracy (ICC ≥ 0.986). The three physiological determinants explained ≥ 98% of the variance in power at LT2, with the largest unique contribution from V˙O2peak (62 and 67% of total R2 ), followed by Cc (8 and 34%) and % V˙O2peak at LT2 (5 and 12%) in males and females, respectively, while c˙Lamax did not improve the regression. CONCLUSION: V˙O2peak, % V˙O2peak at LT2 and Cc accurately predict power at LT2 in young cycling athletes independent of sex, with determination of Cc at 90% LT2 providing the highest accuracy. While V˙O2peak contributes most to LT2 in both sexes, Cc appears more important in young females.