Non-invasive brain imaging to advance the understanding of human balance

IF 4.7 3区工程技术 Q2 ENGINEERING, BIOMEDICAL Current Opinion in Biomedical Engineering Pub Date : 2023-09-16 DOI:10.1016/j.cobme.2023.100505

Helen J. Huang , Daniel P. Ferris

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Abstract

Humans depend on mobility for social interaction, cognitive development, and health maintenance. Successful mobility requires maintaining balance, which integrates sensory feedback, internal cognitive models of body dynamics, and musculoskeletal actions. There have been great strides in understanding these components of balance control in the last 20 years, but balance deficits persist in a large percentage of the population. We propose that combining non-invasive brain imaging using high-density electroencephalography (EEG) with behavioral and biomechanical measures could reveal unique insights about balance control. Source separation and localization of brain electrical activity during mobile tasks have improved with advancements in electrodes and motion artifact removal. This enables studying naturally occurring balance tasks with and without perturbations to identify the timing, magnitude, and quality of brain processing during balance. Along with efforts toward more inclusive EEG research and open resources, this approach could help diagnose and treat poor balance ability among more people.

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无创大脑成像促进对人类平衡的理解

人类依靠流动性进行社交、认知发展和健康维护。成功的行动需要保持平衡，平衡包括感觉反馈、身体动力学的内部认知模型和肌肉骨骼动作。在过去的20年里，在理解平衡控制的这些组成部分方面取得了长足的进步，但平衡赤字在很大一部分人口中仍然存在。我们提出，将使用高密度脑电图（EEG）的非侵入性脑成像与行为和生物力学测量相结合，可以揭示关于平衡控制的独特见解。随着电极和运动伪影去除的进步，移动任务中大脑电活动的源分离和定位得到了改善。这使得能够在有扰动和无扰动的情况下研究自然发生的平衡任务，以确定平衡过程中大脑处理的时间、幅度和质量。随着对更具包容性的脑电图研究和开放资源的努力，这种方法可以帮助诊断和治疗更多人的平衡能力差。

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