Analysis and research on athlete biorhythm and sports injury

  • Qian Shi Physical Education Department, Anhui University of Finance and Economics, Bengbu 233041, China
  • Li'e He College of Physical Education, Yichun University, Yichun 336000, China
Keywords: biorhythm status; sports injury; circadian rhythm; physical strength rhythm
Article ID: 211

Abstract

There is a certain correlation between sports injury and biorhythm status. Finding out the specific stage of the biorhythm can help athletes reduce injuries during training. This paper analyzes the athlete’s biorhythm state through computational principles and biomolecular perspectives, and verifies the reliability of the relationship between the biorhythm state and sports injury. This article takes 132 samples of injured athletes from a university with complete sample records from the Google data analysis platform as the research object. According to the biological rhythm estimation method, the Google data analysis platform is used to calculate and analyze the relationship between the injury period and the biological rhythm of these samples. Then, the biorhythm state of the athlete is evaluated from the calculation principle of biorhythm and the level of biomolecules, and compared with the athlete’s injury situation, so as to guide the athlete’s sports training rhythm. The research results show that the relationship between the biological rhythm and sports injury obtained according to the biological rhythm calculation method has a large error. From the perspective of biomolecules, the rhythm regulator PPAR1 is regulated by unknown factors, and CLOCK is regulated by ribosylation. When the ratio of AMP/ATP is higher than 30%, liver kinase B phosphorylates AMP-activated protein kinase. At this time, the biological rhythm is in the climax period. At this time, people feel comfortable and energetic, and the incidence of sports injuries during training is low.

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Published
2024-09-04
How to Cite
Shi, Q., & He, L. (2024). Analysis and research on athlete biorhythm and sports injury. Molecular & Cellular Biomechanics, 21, 211. https://doi.org/10.62617/mcb.v21.211
Section
Article