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The influence of dietary carbohydrate on perceived recovery status differs at the group and individual level

evidence of nonergodicity among endurance athletes

##article.authors##

  • Jeffrey Rothschild Sports Performance Research Institute New Zealand https://orcid.org/0000-0003-0014-5878
  • Tom Stewart Sports Performance Research Institute New Zealand
  • Andrew Kilding Sports Performance Research Institute New Zealand
  • Daniel Plews Sports Performance Research Institute New Zealand

DOI:

https://doi.org/10.51224/SRXIV.196

Keywords:

intraindividual variability, monitoring, carbohydrate, training load monitoring, decision tree, machine learning

Abstract

Purpose: Research findings are typically reported at the group level but applied to individuals. However, an emerging issue in sports science concerns nonergodicity — whereby group-level data cannot be generalized to individuals. The purpose of this study was to determine if the relationship between daily carbohydrate intake and perceived recovery status displays nonergodicity.

 

Methods: Fifty-five endurance athletes recorded daily measures of self-selected dietary intake, training, sleep, and subjective wellbeing for 12 weeks. We constructed linear models to measure the influence of daily carbohydrate intake on perceived recovery status while accounting for training load, sleep duration, sleep quality, and muscle soreness. Using linear model coefficients for carbohydrate intake we tested whether the distributions (mean and SD) differed at the group and individual levels (indicating nonergodicity). Additionally, a decision tree was created to explore factors that could provide an indication of an individual athlete’s relationship between carbohydrate intake and perceived recovery status.

 

Results: Mean values were not different between group- and individual-level analyses, but SDs at the individual level were ~2.5 times larger than at the group level, indicating nonergodicity. Model coefficients for carbohydrate intake were negative for five participants, positive for four participants, and non-significant for 31 participants. The Kappa value measuring accuracy of the decision tree was 0.54, indicating moderate prediction accuracy.

 

Conclusion: For most individuals, carbohydrate intake did not influence recovery status. However, the influence of dietary carbohydrate intake on daily recovery differs at the group and individual level. Therefore, practical recommendations should be based on individual-level analysis.

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2022-09-12