Delayed muscle fatigue during electrical stimulation of the proximal nerve using asymmetric random high-frequency carrier pulse cluster.

IF 5.2 2区医学 Q1 ENGINEERING, BIOMEDICAL

Journal of NeuroEngineering and Rehabilitation Pub Date : 2025-06-02 DOI:10.1186/s12984-025-01658-0

Rui Yuan, Yang Zheng, Henry Shin, Guanghua Xu, Shengnuo Fan, Zhanhong Du

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引用次数: 0

Abstract

Background: Transcutaneous peripheral nerve electrical stimulation using high-frequency pulse clusters has been shown to relieve muscle fatigue, though its efficacy remains limited. Furthermore, this approach tends to exacerbate pain during stimulation, which constrains its clinical applications. This paper proposed a novel stimulation waveform to reduce muscle fatigue and the discomfort associated with high-frequency electrical stimulation, and compares it with previously reported high-frequency pulsed cluster stimulation.

Methods: We evaluated our waveform experimentally and through model simulations. During the experiment, two distinct high-frequency narrow pulse clusters were applied to the proximal segment of the median/ulnar nerve bundles: asymmetric random (aSymR) and previously reported symmetric (Sym) stimulation, both with a carrier frequency of 10 kHz. The two stimulation modes aimed to elicit the same contraction level and were maintained for 5 min to induce muscle fatigue. Finger force, high-density electromyographic (EMG) signals of the flexor muscles and the pain score were recorded. In addition, we developed a finite element model of the upper arm and a motor fiber model to simulate motor axon activation of the peripheral nerve induced by the two electrical stimulation modes.

Results: Compared with the Sym stimulation, the aSymR stimulation resulted in less pain and a significant reduction of muscle fatigue rate, which was characterized by slower force decay rate, less absolute force decay, greater plateau force, and ultimately greater force output. In addition, the simulation results showed that the delay for different fibers to reach the threshold was increased by the aSymR mode. Consistent with this, the experiment study showed that the EMG amplitude under the aSymR stimulation condition was smaller before fatigue onset, indicating the less synchronized activation of different muscle fibers.

Conclusions: Compared with the Sym stimulation, the aSymR stimulation can significantly relieve muscle fatigue possibly by reducing the synchronous activation across different fibers. This proposed aSymR stimulation mode not only reduces fatigue but also relieves pain, potentially contributing to the wide application of electrical stimulation in motor function rehabilitation for people with stroke.

Trial registration: Ethics committee of the Medical College of Xi'an Jiaotong University, 2021 - 1550. Registered 4 November 2021.

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非对称随机高频载波脉冲簇电刺激近端神经时延迟性肌肉疲劳。

背景：使用高频脉冲簇经皮周围神经电刺激已被证明可以缓解肌肉疲劳，尽管其效果仍然有限。此外，这种方法容易加剧刺激时的疼痛，这限制了它的临床应用。本文提出了一种新的刺激波形来减轻肌肉疲劳和与高频电刺激相关的不适，并将其与先前报道的高频脉冲簇刺激进行了比较。方法：通过实验和模型模拟对波形进行评估。在实验中，两种不同的高频窄脉冲簇应用于正中/尺神经束近端：非对称随机（aSymR）和先前报道的对称（Sym）刺激，两者的载波频率均为10 kHz。两种刺激方式的目的是引起相同的收缩水平，并保持5分钟，以诱导肌肉疲劳。记录手指用力、屈肌高密度肌电图信号及疼痛评分。此外，我们建立了上臂的有限元模型和运动纤维模型来模拟两种电刺激模式下周围神经的运动轴突激活。结果：与Sym刺激相比，aSymR刺激疼痛减轻，肌肉疲劳率明显降低，其特点是力衰减速度慢，绝对力衰减小，平台力大，最终力输出大。此外，仿真结果表明，aSymR模式增加了不同光纤到达阈值的延迟。与此相一致的是，实验研究表明，在aSymR刺激条件下，疲劳开始前的肌电波幅较小，说明不同肌肉纤维的同步激活较少。结论：与Sym刺激相比，aSymR刺激可能通过减少不同纤维间的同步激活来显著缓解肌肉疲劳。提出的aSymR刺激模式不仅能减轻疲劳，还能减轻疼痛，可能有助于电刺激在脑卒中患者运动功能康复中的广泛应用。试验注册：西安交通大学医学院伦理委员会，2021 - 1550。注册于2021年11月4日。

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 NeuroEngineering and Rehabilitation 工程技术-工程：生物医学

CiteScore

9.60

自引率

3.90%

发文量

122

审稿时长

24 months

期刊介绍： Journal of NeuroEngineering and Rehabilitation considers manuscripts on all aspects of research that result from cross-fertilization of the fields of neuroscience, biomedical engineering, and physical medicine & rehabilitation.