Vastus lateralis muscle architecture, quality, and stiffness are determinants of maximal performance in athletes?

IF 2.4 3区医学 Q3 BIOPHYSICS

Journal of biomechanics Pub Date : 2025-02-01 Epub Date: 2025-01-02 DOI:10.1016/j.jbiomech.2025.112491

Fábio Juner Lanferdini, Heinrich Leon Souza Viera, Lucas Gidiel-Machado, Tiago Dutra Leite-Nunes, Isadora Miotto Soldatelli, Lauren Benetti Porporatti, Silvana Correa Matheus, Daniela Lopes Dos Santos, Michele Forgiarini Saccol, Luiz Fernando Freire Royes

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Abstract

Understanding intrinsic muscular adaptations more deeply can help clarify their relationships with sports performance. Therefore, the aim of this study was to determine if vastus lateralis muscle architecture, quality and stiffness can explain knee extensor maximal torque and countermovement and squat jump performance of athletes. One hundred and two athletes were evaluated based on the architecture, quality and stiffness of the vastus lateralis at rest. Furthermore, the knee extensor maximal voluntary isometric contraction and maximal concentric contraction at 60°/s and vertical jumps countermovement and squat jump performance were measured. Stepwise linear regression showed vastus lateralis echo intensity and muscle thickness determine knee extensor maximal voluntary isometric contraction (r² = 0.435) and knee extensor maximal concentric contraction at 60°/s (r² = 0.400) in athletes. Moreover, vastus lateralis echo intensity, muscle thickness and pennation angle can determine athletes' performance during countermovement (r² = 0.439-0.578) and squat-jump (r² = 0.459-0.570). The findings emphasize that vastus lateralis muscle architecture and quality is an important determinant of maximal knee extensor torque (40-44 %) and countermovement (44-58 %) and squat-jump (46-57 %) performance. Our results demonstrate that the muscle architecture and quality of the vastus lateralis are important determinants of torque and power output performance across various sports disciplines.

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股外侧肌的结构、质量和僵硬度是运动员最大表现的决定因素。

更深入地了解内在的肌肉适应可以帮助阐明它们与运动表现的关系。因此，本研究的目的是确定股外侧肌的结构、质量和刚度是否可以解释运动员的膝关节伸肌最大扭矩、反动作和深蹲跳表现。根据静止时股外侧肌的结构、质量和刚度对102名运动员进行了评估。此外，还测量了膝关节伸肌在60°/s的最大自主等距收缩和最大同心收缩，以及垂直跳跃、反动作和深蹲跳的表现。逐步线性回归显示，运动员股外侧肌回声强度和肌肉厚度决定膝关节伸肌最大自主等距收缩（r2 = 0.435）和60°/s时膝关节伸肌最大同心圆收缩（r2 = 0.400）。此外，股外侧肌回声强度、肌肉厚度和笔角对运动员在反动作（r2 = 0.439 ~ 0.578）和深蹲跳（r2 = 0.459 ~ 0.570）中的表现有影响。研究结果强调，股外侧肌的结构和质量是最大膝关节伸肌扭矩（40- 44%）、反向运动（44- 58%）和深蹲跳（46- 57%）表现的重要决定因素。我们的研究结果表明，在各种运动项目中，股外侧肌的肌肉结构和质量是扭矩和功率输出性能的重要决定因素。

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

Journal of biomechanics 生物-工程：生物医学

CiteScore

5.10

自引率

4.20%

发文量

345

审稿时长

1 months

期刊介绍： The Journal of Biomechanics publishes reports of original and substantial findings using the principles of mechanics to explore biological problems. Analytical, as well as experimental papers may be submitted, and the journal accepts original articles, surveys and perspective articles (usually by Editorial invitation only), book reviews and letters to the Editor. The criteria for acceptance of manuscripts include excellence, novelty, significance, clarity, conciseness and interest to the readership. Papers published in the journal may cover a wide range of topics in biomechanics, including, but not limited to: -Fundamental Topics - Biomechanics of the musculoskeletal, cardiovascular, and respiratory systems, mechanics of hard and soft tissues, biofluid mechanics, mechanics of prostheses and implant-tissue interfaces, mechanics of cells. -Cardiovascular and Respiratory Biomechanics - Mechanics of blood-flow, air-flow, mechanics of the soft tissues, flow-tissue or flow-prosthesis interactions. -Cell Biomechanics - Biomechanic analyses of cells, membranes and sub-cellular structures; the relationship of the mechanical environment to cell and tissue response. -Dental Biomechanics - Design and analysis of dental tissues and prostheses, mechanics of chewing. -Functional Tissue Engineering - The role of biomechanical factors in engineered tissue replacements and regenerative medicine. -Injury Biomechanics - Mechanics of impact and trauma, dynamics of man-machine interaction. -Molecular Biomechanics - Mechanical analyses of biomolecules. -Orthopedic Biomechanics - Mechanics of fracture and fracture fixation, mechanics of implants and implant fixation, mechanics of bones and joints, wear of natural and artificial joints. -Rehabilitation Biomechanics - Analyses of gait, mechanics of prosthetics and orthotics. -Sports Biomechanics - Mechanical analyses of sports performance.