Biceps femoris muscle-tendon strain during an entire overground sprint acceleration: a biomechanical explanation for hamstring injuries in the acceleration phase.

IF 2 3区医学 Q3 ENGINEERING, BIOMEDICAL Sports Biomechanics Pub Date : 2024-05-13 DOI:10.1080/14763141.2024.2353233

Andrea Astrella, Daniel Iordanov, Dario De Caro, Pedro Jiménez-Reyes, Jurdan Mendiguchia

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Abstract

The objectives of this study were to analyse the peak muscle-tendon (MT) strain of the hamstring during an entire acceleration sprint overground and examine their relationship with relative joint angles and segment orientation in the sagittal plane, which are the direct causes of MT strain. Kinematic data were recorded using a 3D inertial motion capture system in 21 male semi-professional soccer players during 40-metre overground sprint. Scaled musculoskeletal models were used to estimate peak MT strain in the hamstring over 16 steps. Biceps femoris long head (BF^LH) exhibited the largest peaks in MT strain compared to semitendinosus (ST) and semimembranosus (SM) muscles across all the steps, with its overall strain decreased as the number of steps and maximum speed increased. Hip flexion angle was found to be a strong predictor (p < 0.001) of joint angles, being the orientation of the pelvis in the sagittal plane of the segment with the greatest influence (p < 0.001) on the peak MT strain of BF^LH during sprinting. The current study provides a biomechanical explanation for the high proportion of hamstring injuries in the acceleration phase of sprinting.

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整个地面冲刺加速过程中的股二头肌肌腱拉伤：加速阶段腿筋受伤的生物力学解释。

本研究的目的是分析腘绳肌在整个地面加速冲刺过程中的肌肉-肌腱（MT）应变峰值，并研究其与矢状面上相对关节角度和节段方向的关系，因为它们是造成MT应变的直接原因。使用三维惯性运动捕捉系统记录了 21 名半职业男子足球运动员在 40 米地面冲刺时的运动数据。使用比例肌肉骨骼模型估算了腘绳肌在 16 个步骤中的峰值 MT 应变。与半腱肌（ST）和半膜肌（SM）相比，股二头肌长头肌（BFLH）在所有步数中表现出最大的MT应变峰值，其整体应变随着步数和最大速度的增加而降低。研究发现，在短跑过程中，髋关节屈曲角是一个很强的预测因子（p p LH）。本研究从生物力学角度解释了短跑加速阶段腿筋受伤比例较高的原因。

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来源期刊

Sports Biomechanics 医学-工程：生物医学

CiteScore

5.70

自引率

9.10%

发文量

135

审稿时长

>12 weeks

期刊介绍： Sports Biomechanics is the Thomson Reuters listed scientific journal of the International Society of Biomechanics in Sports (ISBS). The journal sets out to generate knowledge to improve human performance and reduce the incidence of injury, and to communicate this knowledge to scientists, coaches, clinicians, teachers, and participants. The target performance realms include not only the conventional areas of sports and exercise, but also fundamental motor skills and other highly specialized human movements such as dance (both sport and artistic). Sports Biomechanics is unique in its emphasis on a broad biomechanical spectrum of human performance including, but not limited to, technique, skill acquisition, training, strength and conditioning, exercise, coaching, teaching, equipment, modeling and simulation, measurement, and injury prevention and rehabilitation. As well as maintaining scientific rigour, there is a strong editorial emphasis on ''reader friendliness''. By emphasising the practical implications and applications of research, the journal seeks to benefit practitioners directly. Sports Biomechanics publishes papers in four sections: Original Research, Reviews, Teaching, and Methods and Theoretical Perspectives.