用可穿戴式超声剪切波弹性测量法跟踪抓握过程中的肌肉刚度

IF 2.2 Q3 ENGINEERING, ELECTRICAL & ELECTRONIC

IEEE Sensors Letters Pub Date : 2025-07-31 DOI:10.1109/LSENS.2025.3594215

Shane Steinberg;Yuu Ono;Sreeraman Rajan

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引用次数: 0

摘要

这封信介绍了一种可穿戴超声剪切波弹性测量（wUS-SWEM）设备，并展示了其跟踪时间和深度分辨肌肉僵硬的能力，使用握力作为肌肉激活的参考。剪切波由微型驱动器产生，并使用两个集成在紧凑可穿戴外形中的非聚焦超声换能器进行检测。该装置用于监测循环握力-放松任务中的前臂屈肌，得到与任务时间一致的时空剪切模量模式。在浅屈肌区域，剪切模量与握力表现出很强的线性相关性（$\text{r} = 0.82\text{—}0.86$,$\text{p}< 0.001$），支持其作为肌肉力量的无创预测指标。这些结果证明了使用wUS-SWEM在上臂功能活动期间跟踪剪切模量的可行性，并突出了其在神经肌肉评估和人机界面方面的潜力。

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Tracking Muscle Stiffness During Gripping With Wearable Ultrasound Shear-Wave Elastometry

This letter presents a wearable ultrasound shear-wave elastometry (wUS-SWEM) device and demonstrates its capability to track time- and depth-resolved muscle stiffness, using grip force as a reference for muscle activation.Shear waves were generated by a miniature actuator and detected using two unfocused ultrasound transducers integrated into a compact, wearable form factor. The device was applied to monitor the forearm flexor muscles during a cyclic grip–relax task, yielding spatiotemporal shear modulus patterns aligned with task timing. In the superficial flexors region, shear modulus exhibited a strong linear correlation with grip force (

$\text{r} = 0.82\text{--}0.86$

$\text{p}< 0.001$

), supporting its use as a noninvasive predictor of muscle force. These results demonstrate the feasibility of shear modulus tracking during functional activity of the upper arm using wUS-SWEM and highlight its potential for neuromuscular assessment and human–machine interfacing.

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来源期刊

IEEE Sensors Letters Engineering-Electrical and Electronic Engineering

CiteScore

3.50

自引率

7.10%

发文量

194