Differences in Movement Preparation under Hyperthermic Conditions: Self-Initiated vs. Externally-Cued Movements.

Medicine & Science in Sports & Exercise Pub Date : 2025-04-23 DOI:10.1249/mss.0000000000003740

Manabu Shibasaki,Hiroki Nakata,Shigehiko Ogoh

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Abstract

INTRODUCTION Excessive increases in body temperature impair voluntary force production and neuromuscular function, but the underlying central mechanisms remain unclear. PURPOSE We investigated the effect of hyperthermia on neural activity associated with motor preparation using electroencephalographic event-related potentials (EEG-ERPs). METHODS Two stimulus presentation methods were used: movement-related cortical potentials (MRCP) induced by self-initiated movement, and contingent negative variation (CNV) induced by externally-cued movement. The exercise intensity that elicited MRCP and CNV was set at 20% maximum voluntary contraction. Healthy young volunteers performed trials before and during whole-body heat stress on separate days. RESULTS Heat stress increased esophageal temperature by 1.5 ± 0.1 °C during the MRCP trial and 1.5 ± 0.2 °C during the CNV trial. Consistent with previous studies, the results of the Go/No-go tasks showed that the hyperthermia-induced impairment of brain activity was associated with executive and inhibitory processing during heat stress in both trials. In the MRCP trial, the amplitude of Bereitschaftspotential and the negative slope remained unchanged across all electrodes. However, CNV amplitudes in the middle and late phases were significantly reduced at Cz and Pz (both phases, P < 0.005), and C4 (late phase, P < 0.05), while early phase amplitudes were unchanged. CONCLUSIONS These findings indicate that neural activity for self-initiated movements is preserved under heat stress, whereas neural activity for externally-cued movements may be inhibited due to hyperthermia-induced central fatigue, potentially involving brain regions such as the prefrontal cortex. This alteration in the central mechanisms may contribute to the attenuated exercise performance under heat stress.

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高温条件下运动准备的差异：自我启动与外部提示的运动。

体温的过度升高损害自发力的产生和神经肌肉功能，但潜在的中枢机制尚不清楚。目的：利用脑电图事件相关电位（EEG-ERPs）研究热疗对运动准备相关神经活动的影响。方法采用两种刺激呈现方法：自体运动诱发的运动相关皮质电位（MRCP）和外源运动诱发的偶然负变异（CNV）。引起MRCP和CNV的运动强度设定为20%最大自愿收缩。健康的年轻志愿者在全身热应激之前和期间分别进行了试验。结果热应激使MRCP组和CNV组的食管温度分别升高1.5±0.1°C和1.5±0.2°C。与之前的研究一致，Go/No-go任务的结果表明，在两个试验中，高温诱导的大脑活动损伤与热应激期间的执行和抑制加工有关。在MRCP试验中，在所有电极上，bereitschaftpotential的振幅和负斜率保持不变。而在Cz和Pz（两期，P < 0.005）和C4（晚期，P < 0.05）时，CNV中后期振幅显著降低，而早期振幅不变。这些研究结果表明，在热应激下，自发运动的神经活动得以保留，而外部提示运动的神经活动可能由于高温引起的中枢疲劳而受到抑制，可能涉及前额叶皮质等大脑区域。这种中枢机制的改变可能导致热应激下运动表现的减弱。

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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Medicine & Science in Sports & Exercise

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