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Hamstring muscle architecture and viscoelastic properties: Reliability and retrospective comparison between previously injured and uninjured athletes
Citation
Nin, D. Z., Pain, M. T. G., Lim, Y. H., & Kong, P. W. (2021). Hamstring muscle architecture and viscoelastic properties: Reliability and retrospective comparison between previously injured and uninjured athletes. Journal of Mechanics in Medicine and Biology, 21(1), Article 2150007. https://doi.org/10.1142/S021951942150007X
Abstract
The architecture of the biceps femoris (BF) and stiffness of the hamstrings have been found to be associated with injury risk. However, less is known about the architecture of the equally voluminous semitendinosus (ST) and viscoelastic properties of both muscles in individuals with a prior injury. Methods: BF and ST of 15 athletes (previously injured, n=5; control, n=10) were assessed using ultrasonography and myotonometry. Mean architecture (muscle thickness (MT), pennation angle (PA) and fascicle length (FL)) and viscoelastic measures (stiffness, oscillation frequency and decrement) were compared between the previously injured and contralateral uninjured limb, and between the previously injured and control limbs (mean of both limbs of the control group). Control group participants returned for a duplicate measurement. Findings: Both muscles exhibited high reliability between sessions (intraclass correlation coefficient (ICC)=0.89−0.98) for architecture. BF PA was larger in the previously injured than both uninjured (+1.1∘,d=0.65) and control (+1.51∘,d=0.71). BF fascicles were shorter in the previously injured limb compared to the uninjured (−0.4cm,d=0.65) and control (−0.6cm,d=0.67). BF was stiffer in the previously injured compared to uninjured (+9.2Nm−1,d=1.28). ST architecture and viscoelasticity were similar across limbs. Conclusion: A prior hamstring strain injury is associated with a stiffer BF characterized by larger PAs and shorter fascicles.
Date Issued
2021
DOI
10.1142/S021951942150007X
Dataset
https://doi.org/10.25340/R4/A1ELGS
Description
This is the final draft, after peer-review, of a manuscript published in Journal of Mechanics in Medicine and Biology. The published version is available online at https://doi.org/10.1142/S021951942150007X
Grant ID
NIE Academic Research Fund (NIE AcRF)
Funding Agency
National Institute of Education, Singapore