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European Journal of Applied Physiology
Published in: European Journal of Applied Physiology 3/2006

01-02-2006 | Original Article

Validity of the two-parameter model in estimating the anaerobic work capacity

Authors: J. Dekerle, G. Brickley, A. J. P. Hammond, J. S. M. Pringle, H. Carter

Published in: European Journal of Applied Physiology | Issue 3/2006

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Abstract

The curvature of the power–time (Pt) relationship (W′) has been suggested to be constant when exercising above critical power (CP) and to represent the anaerobic work capacity (AWC). The aim of this study was to compare W′ to (1) the total amount of work performed above CP (W 90s′) and (2) the AWC, both determined from a 90s all-out fixed cadence test. Fourteen participants (age 30.5±6.5 years; body mass 67.8±10.3 kg), following an incremental VO2max ramp protocol, performed three constant load exhaustion tests set at 103±3, 97±3 and 90±2% P-VO2max to calculate W′ from the Pt relationship. Two 90s all-out efforts were also undertaken to determine W 90s′ (power output—time integral above CP) and AWC (power output—time integral above the power output expected from the measured VO2). W′ (13.6±1.3 kJ) and W 90s′ (13.9±1.1 kJ; P=0.96) were not significantly different but were lower than AWC (15.9±1.2 kJ) by 24% (P=0.03) and 17%, respectively (P=0.04). All these variables were correlated (P<0.001) but great extents of disagreement were reported (0.2±6.4 kJ between W′ and W 90s′, 2.3±7.2 kJ between W′ and AWC, and 2.1±4.3 kJ between W 90s′ and AWC). The underestimation of AWC from both W′ and W 90s′ can be explained by the aerobic inertia not taking into consideration when determining the two latter variables. The low extents of agreement between W′, W 90s′ and AWC mean the terms should not be used interchangeably.
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Metadata
Title
Validity of the two-parameter model in estimating the anaerobic work capacity
Authors
J. Dekerle
G. Brickley
A. J. P. Hammond
J. S. M. Pringle
H. Carter
Publication date
01-02-2006
Publisher
Springer-Verlag
Published in
European Journal of Applied Physiology / Issue 3/2006
Print ISSN: 1439-6319
Electronic ISSN: 1439-6327
DOI
https://doi.org/10.1007/s00421-005-0074-8

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