Capelli C, Schena F, Zamparo P, Monte A D, Faina M, di Prampero P E
Dipartimento di Scienze e Tecnologie Biomediche, Sezione di Fisiologia, School of Medicine, Udine, Italy.
Med Sci Sports Exerc. 1998 Apr;30(4):614-24. doi: 10.1097/00005768-199804000-00021.
VO2max and best performance times (BPTs) obtained during maximal voluntary trials over 1, 2, 5, and 10 km from a stationary start were assessed in 10 elite cyclists. Steady-state VO2 and peak blood lactate concentration ([La]b) were also determined in the same subjects pedaling on a track at constant submaximal speeds. The energy cost of cycling (Cc, J.m-1) was calculated as the ratio of VO2, corrected for glycolytic energy production and expressed in W, to v (m.s-1). Individual relationships between Cc and v were described by: Cc = Ccrr + k1 v2 where Ccrr is the energy spent against friction and k1 v2 is that spent against drag. Overall energy cost of cycling (Cctot) was obtained, adding to Cc the energy spent to accelerate the total moving mass from a stationary start. Individual theoretical BPTs were then calculated and compared with the actual ones as follows. The maximal metabolic power sustained at a constant level by a given subject (Emax, W) is a known function of the exhaustion time (te). It depends on his VO2max and maximal anaerobic capacity; it was obtained from individual VO2max and [La]b values. The metabolic power (Ec, W) necessary to cover any given distance (d) is a known function of the performance time over d (td); it is given by Ec = Cctot v = Cctot d td. For all subjects and distances, the t values solving the equalities Emax F(te) = Ec F(td) were calculated and assumed to yield theoretical BPTs. Calculations showed a fairly good agreement between actual and calculated BPTs with an average ratio of 1.035 +/- 0.058.
对10名精英自行车运动员进行了评估,测定了他们从静止出发,在1公里、2公里、5公里和10公里最大自愿性骑行试验中获得的最大摄氧量(VO2max)和最佳成绩时间(BPTs)。还测定了同一批受试者在赛道上以恒定的次最大速度骑行时的稳态VO2和血乳酸峰值浓度([La]b)。骑行的能量消耗(Cc,焦耳·米⁻¹)通过以下方式计算:将经糖酵解能量产生校正并以瓦特表示的VO2与速度v(米·秒⁻¹)的比值。Cc与v之间的个体关系用以下公式描述:Cc = Ccrr + k1 v²,其中Ccrr是克服摩擦力消耗的能量,k1 v²是克服阻力消耗的能量。通过将Cc加上从静止出发加速总移动质量所消耗的能量,得出骑行的总能量消耗(Cctot)。然后计算个体理论BPTs,并与实际BPTs进行如下比较。给定受试者在恒定水平下维持的最大代谢功率(Emax,瓦特)是疲劳时间(te)的已知函数。它取决于其VO2max和最大无氧能力;它是从个体VO2max和[La]b值中获得的。覆盖任何给定距离(d)所需的代谢功率(Ec,瓦特)是d距离上成绩时间(td)的已知函数;它由Ec = Cctot v = Cctot d / td给出。对于所有受试者和距离,计算求解等式Emax F(te) = Ec F(td)的t值,并假定其得出理论BPTs。计算结果表明,实际BPTs与计算得出的BPTs之间具有相当好的一致性,平均比值为1.035±0.058。
