The Relationship Between Neuromuscular Function and the W′ in Elite Cyclists

in International Journal of Sports Physiology and Performance

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Mehdi Kordi
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Len Parker Simpson
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Kevin Thomas
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Stuart Goodall
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Tom Maden-Wilkinson
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Campbell Menzies
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Glyn Howatson
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DOI:
https://doi.org/10.1123/ijspp.2020-0861
Keywords:
elite athletes; power–duration; muscle strength; critical power
First Published Online:
19 Apr 2021
In Print:
Volume 16: Issue 11
Page Range:
1656–1662
Restricted access

Purpose: To assess the association between the W′ and measures of neuromuscular function relating to the capacity of skeletal muscle to produce force in a group of elite cyclists. Methods: Twenty-two athletes specializing in a range of disciplines and competing internationally volunteered to participate. Athletes completed assessments of maximum voluntary torque (MVT), voluntary activation, and isometric maximum voluntary contraction to measure rate of torque development (RTD). This was followed by assessment of peak power output (PPO) and 3-, 5-, and 12-minute time trials to determine critical power. Pearson correlation was used to examine associations with critical power and W′. Goodness of fit was calculated, and significant relationships were included in a linear stepwise regression model. Results: Significant positive relationships were evident between W′ and MVT (r = .82), PPO (r = .70), and RTD at 200 milliseconds (r = .59) but not with RTD at 50 milliseconds and voluntary activation. Correlations were also observed between critical power and RTD at 200 milliseconds and MVT (r = .54 and r = .51, respectively) but not with PPO, voluntary activation, or RTD at 50 milliseconds. The regression analysis found that 87% of the variability in W′ (F1,18 = 68.75; P < .001) was explained by 2 variables: MVT (81%) and PPO (6%). Conclusions: It is likely that muscle size and strength, as opposed to neural factors, contribute meaningfully to W′. These data can be used to establish training methods to enhance W′ to improve cycling performance in well-trained athletes.

Kordi, Thomas, Goodall, and Howatson are with the Dept of Sport, Exercise and Rehabilitation, Northumbria University, Newcastle, United Kingdom. Kordi is also with the Royal Dutch Cycling Federation (KNWU), Arnhem, The Netherlands. Parker Simpson is with the School of Sport and Exercise Sciences, University of Kent, Kent, United Kingdom; and the High Performance Centre of Japan Cycling, Izu-shi, Japan. Maden-Wilkinson is with the Physical Activity, Public Health and Wellness Research Group, Sheffield Hallam University, Sheffield, United Kingdom. Menzies is with the Centre for Sport, Exercise and Life Sciences, Coventry University, Coventry, United Kingdom. Howatson is also with the Water Research Group, North-West University, Potchefstroom, South Africa.

Howatson (glyn.howatson@northumbria.ac.uk) is corresponding author.
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