A Two-test Protocol for the Precise Determination of the Maximal Lactate Steady State

The purpose of this study was to determine the efficacy of a two-test method for precisely identifying the Maximal Lactate Steady State (MLSS). Eight male competitive cyclists performed two bouts on a cycle ergometer. Following a maximal oxygen consumption (V̇O(2max)) test (66.91 ± 5.29 mL·kg(−1)·min(−1)) we identified the lactate deflection point using the visual deflection (T(Vis)), Log-Log (T(Log)), D(max) (T(Dmax)), RER = 1.00 (T(RER)), ventilatory threshold (T(Vent)), and the 1.0 mmol·L(−1) increase above baseline (T(+1)) methods. The second incremental test (SIT) consisted of 6–7 stages (5 min each) starting 20–30 W below to 20–30 W above the predetermined deflection point, in 10 W increments. Comparison of the two tests yielded different threshold estimates (range 11–46W) for all methods (P = 0.001–0.019) except the T(Log) (P = 0.194) and T(RER) (P = 0.100). The SIT resulted in significantly (P = 0.007) more narrow range of thresholds (27.5 ± 11.01W) compared to the V̇O(2max) test (70 ± 42.51W). The T(Vis) from the SIT was identified as the MLSS and was verified using three 45-minute steady-state exercise bouts at 95%, 100%, and 105% of MLSS intensity (average increment 12.8 W). Blood lactate and V̇O(2) were recorded every 5 minutes and differed between the three intensities at every time point (P < 0.001). V̇O(2) increased from the 5(th) to the 45(th) minute by 7.02 mL·kg(−1)·min(−1) (100% MLSS), 3.63 mL·kg(−1)·min(−1) (95% MLSS) and 7.5 mL·kg(−1)·min(−1) (105% MLSS, to the 30(th) minute). These results indicate that the MLSS was identified correctly by the SIT, the single incremental test overestimated the MLSS intensity, and the T(Vis) provides a very accurate determination of the lactate breakpoint. The use of a second submaximal test is required for a precise identification of MLSS.