Abstract
The purpose of the present study was to examine the reproducibility of laboratory-based 40-km cycle time-trial performance on a stationary wind-trainer. Each week, for three consecutive weeks, and on different days, forty-three highly trained male cyclists (x¯ ± SD; age = 25 ± 6 y; mass = 75 ± 7 kg; peak oxygen uptake [V·O2peak] = 64.8 ± 5.2 ml × kg-1 × min-1) performed: 1) a V·O2peak test, and 2) a 40-km time-trial on their own racing bicycle mounted to a stationary wind-trainer (Cateye - Cyclosimulator). Data from all tests were compared using a one-way analysis of variance. Performance on the second and third 40-km time-trials were highly related (r = 0.96; p < 0.001), not significantly different (57 : 21 ± 2 : 57 vs. 57 : 12 ± 3 : 14 min:s), and displayed a low coefficient of variation (CV) = 0.9 ± 0.7 %. Although the first 40-km time-trial (58 : 43 ± 3 : 17 min:s) was not significantly different from the second and third tests (p = 0.06), inclusion of the first test in the assessment of reliability increased within-subject CV to 3.0 ± 2.9 %. 40-km time-trial speed (km × h-1) was significantly (p < 0.001) related to peak power output (W; r = 0.75), V·O2peak (l × min-1; r = 0.53), and the second ventilatory turnpoint (l × min-1; r = 0.68) measured during the progressive exercise tests. These data demonstrate that the assessment of 40-km cycle time-trial performance in well-trained endurance cyclists on a stationary wind-trainer is reproducible, provided the athletes perform a familiarization trial.
Key words
Peak oxygen uptake - reliability - ventilatory threshold
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P. B. Laursen
School of Human Movement of Sport Sciences · The University of Ballarat
Ballarat · Victoria · Australia ·
Phone: +61-3-5327-9658
Fax: +61-3-5327-9478
Email: p.laursen@ballarat.edu.au
