Ferguson C, Whipp B J, Cathcart A J, Rossiter H B, Turner A P, Ward S A
Centre for Sport and Exercise Sciences, Institute of Membrane and Systems Biology, Worsley Bldg., Univ. of Leeds, Leeds, LS2 9JT, United Kingdom.
J Appl Physiol (1985). 2007 Sep;103(3):812-22. doi: 10.1152/japplphysiol.01410.2006. Epub 2007 May 31.
A recent bout of high-intensity exercise can alter the balance of aerobic and anaerobic energy provision during subsequent exercise above the lactate threshold (theta(L)). However, it remains uncertain whether such "priming" influences the tolerable duration of subsequent exercise through changes in the parameters of aerobic function [e.g., theta(L), maximum oxygen uptake (Vo(2max))] and/or the hyperbolic power-duration (P-t) relationship [critical power (CP) and the curvature constant (W')]. We therefore studied six men performing cycle ergometry to the limit of tolerance; gas exchange was measured breath-by-breath and arterialized capillary blood [lactate] was measured at designated intervals. On different days, each subject completed 1) an incremental test (15 W/min) for estimation of theta(L) and measurement of the functional gain (DeltaVo(2)/DeltaWR) and Vo(2peak) and 2) four constant-load tests at different work rates (WR) for estimation of CP, W', and Vo(2max). All tests were subsequently repeated with a preceding 6-min supra-CP priming bout and an intervening 2-min 20-W recovery. The hyperbolicity of the P-t relationship was retained postpriming, with no significant difference in CP (241 +/- 39 vs. 242 +/- 36 W, post- vs. prepriming), Vo(2max) (3.97 +/- 0.34 vs. 3.93 +/- 0.38 l/min), DeltaVo(2)/DeltaWR (10.7 +/- 0.3 vs. 11.1 +/- 0.4 ml.min(-1).W(-1)), or the fundamental Vo(2) time constant (25.6 +/- 3.5 vs. 28.3 +/- 5.4 s). W' (10.61 +/- 2.07 vs. 16.13 +/- 2.33 kJ) and the tolerable duration of supra-CP exercise (-33 +/- 11%) were each significantly reduced, despite a less-prominent Vo(2) slow component. These results suggest that, following supra-CP priming, there is either a reduced depletable energy resource or a residual fatigue-metabolite level that leads to the tolerable limit before this resource is fully depleted.
近期的高强度运动能够改变后续高于乳酸阈值(θ(L))运动期间有氧和无氧能量供应的平衡。然而,这种“预激活”是否通过有氧功能参数(如θ(L)、最大摄氧量(Vo(2max)))的变化和/或双曲线功率-持续时间(P-t)关系(临界功率(CP)和曲率常数(W'))的变化来影响后续运动的可耐受持续时间,仍不确定。因此,我们研究了六名男性,让他们进行自行车测力计运动直至耐受极限;逐次测量气体交换,并在指定间隔测量动脉化毛细血管血中的[乳酸]。在不同的日子里,每个受试者完成了1)递增测试(15 W/分钟)以估计θ(L)并测量功能增益(DeltaVo(2)/DeltaWR)和Vo(2peak),以及2)在不同工作率(WR)下进行的四次恒定负荷测试,以估计CP、W'和Vo(2max)。所有测试随后在进行6分钟高于CP的预激活运动回合并进行2分钟20 W的恢复后重复进行。预激活后P-t关系的双曲线特性得以保留,CP(预激活后241±39 W与预激活前242±36 W)、Vo(2max)(3.97±0.34与3.93±0.38 l/分钟)、DeltaVo(2)/DeltaWR(10.7±0.3与11.1±0.4 ml·min(-1)·W(-1))或基本Vo(2)时间常数(25.6±3.5与28.3±5.4秒)均无显著差异。尽管Vo(2)慢成分不那么明显,但W'(10.61±2.07与16.13±2.33 kJ)和高于CP运动的可耐受持续时间(-33±11%)均显著降低。这些结果表明,在高于CP的预激活之后,要么是可消耗能量资源减少,要么是残余疲劳代谢物水平导致在该资源完全耗尽之前达到可耐受极限。
