Shear wave elastography characterizes passive and active mechanical properties of biceps brachii muscle in vivo.

Manuela Zimmer, Benedict Kleiser, J. Marquetand, F. Ates
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引用次数: 8

Abstract

Mechanical characterization of individual muscles in their in vivo environment is not well studied. Shear wave elastography (SWE) as a non-invasive technique was shown to be promising in quantifying the local mechanical properties of skeletal muscles. This study aimed to investigate the mechanics of the biceps brachii muscle (BB) derived from SWE in relation to elbow joint position and contraction intensity during isometric contraction. 14 healthy, young subjects participated in the study and five different joint positions (60°-180° elbow angle) were investigated. Shear elastic modulus and surface electromyography (sEMG) of the BB and elbow torque were measured simultaneously, both in passive (i.e., resting) and active states during slow, sub-maximal isometric ramp contractions up to 25%, 50%, and 75% of the maximum voluntary contraction. At passive state, the shear elastic modulus of the BB increased with increasing elbow angle (p < 0.001). Maximum elbow flexion torque was produced at 60° and it decreased with increasing elbow angle (p = 0.001). During sub-maximal contractions, both elbow angle (p < 0.001) and contraction intensity (p < 0.001) had significant effects on the shear elastic modulus but only contraction intensity (p < 0.001) affected sEMG amplitude of the BB. Although torque was decreased at extended elbow positions (150°, 180°), higher active shear elastic modulus of BB muscle was found compared to flexed positions (60°, 90°). Linear regression of the BB sEMG amplitude over elbow torque showed good agreement for all joint positions (R2 between 0.69 and 0.89) while the linear agreement between shear elastic modulus of BB and elbow torque differed between flexed (R2 = 0.70 at 60° and R2 = 0.79 at 90°) and extended positions (with the lowest R2 = 0.57 at 150°). We conclude that using SWE, we can detect length-dependent mechanical changes of BB both in passive and active states. More importantly, SWE can be used to characterize active muscle properties in vivo. The present findings have critical importance for developing muscle stiffness as a measure of individual muscle force to validate muscle models and using SWE in clinical diagnostics.
剪切波弹性成像表征了体内肱二头肌的被动和主动力学特性。
个体肌肉在其体内环境中的力学特性没有得到很好的研究。剪切波弹性成像(SWE)作为一种非侵入性技术,在量化骨骼肌局部力学性能方面被证明是有前途的。本研究旨在研究SWE衍生的肱二头肌(BB)在等长收缩过程中与肘关节位置和收缩强度的关系。14名健康的年轻受试者参与了这项研究,并对五种不同的关节位置(60°-180°肘角)进行了调查。BB和肘部扭矩的剪切弹性模量和表面肌电图(sEMG)在被动(即休息)和主动状态下同时测量,在缓慢、亚最大等长斜坡收缩期间,分别达到最大自主收缩的25%、50%和75%。在被动状态下,BB的剪切弹性模量随着肘角的增加而增加(p<0.001)。最大肘关节屈曲力矩在60°时产生,并随着肘角增加而减小(p=0.001)。在亚最大收缩期间,肘角(p<0.001)和收缩强度(p<001)对BB的剪切弹性模量都有显著影响,但只有收缩强度(p<0.001)影响BB的sEMG振幅。尽管在伸展肘位置(150°、180°)扭矩降低,但与弯曲位置(60°、90°)相比,BB肌的主动剪切弹性模量更高。BB sEMG振幅与肘部扭矩的线性回归在所有关节位置都显示出良好的一致性(R2在0.69和0.89之间),而BB的剪切弹性模量与肘部扭矩之间的线性一致性在弯曲位置(60°时R2=0.70,90°时R2=0.79)和伸展位置(150°时最低R2=0.57)之间不同。我们的结论是,使用SWE,我们可以检测BB在被动和主动状态下的长度相关的机械变化。更重要的是,SWE可用于表征体内活性肌肉的特性。目前的研究结果对于开发肌肉硬度作为个体肌肉力量的衡量标准以验证肌肉模型以及在临床诊断中使用SWE具有至关重要的意义。
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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