脉冲电磁场可减轻肱二头肌偏心收缩引起的人体肌皮神经损伤。

IF 1.8 3区生物学 Q3 BIOLOGY

Bioelectromagnetics Pub Date : 2024-09-24 DOI:10.1002/bem.22525

Karina Kouzaki, Koichi Nakazato

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引用次数: 0

摘要

脉冲电磁场疗法（PEMF）是一种非侵入性治疗方法，在减轻神经损伤方面前景看好。然而，不习惯的运动，如偏心收缩（ECC），会同时损伤肌肉和神经组织。本研究调查了使用 PEMF 的磁刺激（MS）是否有助于肘部屈肌偏心收缩后的神经恢复。20 名参与者被随机分配到对照组（CNT）或 MS 组。ECC后，我们测量了肌皮神经M波的潜伏期，作为神经功能的指标。此外，我们还对肌肉功能的等长扭矩、活动范围和肌肉疼痛进行了评估。有趣的是，只有 CNT 组的潜伏期在第 2 天有显著增加（p

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Pulsed electromagnetic fields attenuate human musculocutaneous nerve damage induced by biceps eccentric contractions.

Pulsed electromagnetic field (PEMF) therapy, a noninvasive treatment, has shown promise in mitigating nerve damage. However, unaccustomed exercises, such as eccentric contractions (ECCs), can damage both muscle and nerve tissue. This study investigated whether magnetic stimulation (MS) with PEMF could aid in nerve recovery after ECCs in the elbow flexors. Twenty participants were randomly assigned to either a control (CNT) or an MS group. Following ECCs, we measured the latency of the M-wave in the musculocutaneous nerve as an indicator of nerve function. Additionally, isometric torque, range of motion, and muscle pain were assessed for muscle function. Interestingly, only the CNT group exhibited a significant increase in latency on Day 2 (p < 0.05). The MS group, on the other hand, displayed an earlier recovery trend in isometric torque, range of motion, and muscle soreness. Notably, muscle soreness significantly decreased immediately after MS treatment compared to pretreatment levels. These findings suggest that MS treatment can effectively attenuate nerve damage induced by ECCs exercise.

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来源期刊

Bioelectromagnetics 生物-生物物理

CiteScore

4.60

自引率

0.00%

发文量

审稿时长

6-12 weeks

期刊介绍： Bioelectromagnetics is published by Wiley-Liss, Inc., for the Bioelectromagnetics Society and is the official journal of the Bioelectromagnetics Society and the European Bioelectromagnetics Association. It is a peer-reviewed, internationally circulated scientific journal that specializes in reporting original data on biological effects and applications of electromagnetic fields that range in frequency from zero hertz (static fields) to the terahertz undulations and visible light. Both experimental and clinical data are of interest to the journal''s readers as are theoretical papers or reviews that offer novel insights into or criticism of contemporary concepts and theories of field-body interactions. The Bioelectromagnetics Society, which sponsors the journal, also welcomes experimental or clinical papers on the domains of sonic and ultrasonic radiation.