A dynamic model of the bi-exponential reconstitution and expenditure of W' in trained cyclists.

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS

ACS Applied Bio Materials Pub Date : 2023-12-01 Epub Date: 2023-07-30 DOI:10.1080/17461391.2023.2238679

Alan Chorley, Simon Marwood, Kevin L Lamb

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引用次数: 0

Abstract

ABSTRACTThe aim of this study was to investigate the effects of different recovery power outputs on the reconstitution of W' and to develop a dynamic bi-exponential model of W' during depletion and reconstitution. Ten trained cyclists (mass 71.7 ± 8.4 kg; V̇O_2max 60.0 ± 6.3 ml·kg^-1·min^-1) completed three incremental ramps (20 W·min^-1) to the limit of tolerance on each of six occasions with recovery durations of 30 and 240 s. Recovery power outputs varied between 50 W (LOW); 60% of critical power (CP) (MOD) and 85% of CP (HVY). W' reconstitution was measured following each recovery and fitted to a bi-exponential model. Amplitude and time constant (τ) parameters were then determined via regression analysis accounting for relative intensity and duration to produce a dynamic model of W'. W' reconstitution slowed disproportionately as recovery power output increased (p < 0.001) and increased with recovery duration (p < 0.001). The amplitudes of each recovery component were strongly correlated to W' reconstitution after 240 s at HVY (r = 0.95), whilst τ parameters were found to be related to the fractional difference between recovery power and CP. The predictive capacity of the resultant model was assessed against experimental data with no differences found between predicted and experimental values of W' reconstitution (p > 0.05). The dynamic bi-exponential model of W' accounting for varying recovery intensities closely described W' kinetics in trained cyclists facilitating real-time decisions about pacing and tactics during competition. The model can be customised for individuals from known CP and W' and a single additional test session.HighlightsA dynamic bi-exponential model of W' accounting for both varying power output and duration.Individual customisation of the model can be achieved with a single specific test session.W' reconstitution slows disproportionally with increasing intensity after repeated bouts.

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训练自行车运动员双指数重构和W′消耗的动态模型。

摘要本研究旨在探讨不同的回收功率输出对W'的重建的影响，并建立W'在耗竭和重建过程中的动态双指数模型。10名训练有素的自行车手(体重71.7±8.4 kg;V (O2max) 60.0±6.3 ml·kg-1·min-1)在6次试验中分别完成了3次(20 W·min-1)达到耐受极限的增量坡道，恢复时间分别为30和240 s。恢复功率输出在50w (LOW)之间变化;60%的临界功率(CP) (MOD)和85%的CP (HVY)。在每次恢复后测量W'重构，并拟合到双指数模型。然后通过考虑相对强度和持续时间的回归分析确定振幅和时间常数(τ)参数，以产生W'的动态模型。W'重构随着恢复功率输出的增加而不成比例地减慢(p pr = 0.95)，而τ参数与恢复功率和CP之间的分数差有关。根据实验数据评估所得模型的预测能力，W'重构的预测值和实验值之间没有差异(p > 0.05)。考虑不同恢复强度的W'动态双指数模型密切描述了训练自行车手的W'动力学，促进了比赛中节奏和战术的实时决策。该模型可以定制个人从已知的CP和W'和一个额外的测试会话。重点介绍了W'的动态双指数模型，该模型考虑了功率输出和持续时间的变化。模型的个性化定制可以通过单个特定的测试会话来实现。反复发作后，随着强度的增加，W的重建不成比例地减慢。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

ACS Applied Bio Materials Chemistry-Chemistry (all)

CiteScore

9.40

自引率

2.10%

发文量

464