Investigating the Brain Mechanisms of Externally Cued Sit-to-Stand Movement in Parkinson's Disease.

IF 7.4 1区医学 Q1 CLINICAL NEUROLOGY Movement Disorders Pub Date : 2024-07-10 DOI:10.1002/mds.29889

Magda Mustile, Dimitrios Kourtis, Simon Ladouce, Martin G Edwards, Daniele Volpe, Manuela Pilleri, Elisa Pelosin, David I Donaldson, Magdalena Ietswaart

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Abstract

Background: One of the more challenging daily-life actions for Parkinson's disease patients is starting to stand from a sitting position. Parkinson's disease patients are known to have difficulty with self-initiated movements and benefit from external cues. However, the brain processes underlying external cueing as an aid remain unknown. The advent of mobile electroencephalography (EEG) now enables the investigation of these processes in dynamic sit-to-stand movements.

Objective: To identify cortical correlates of the mechanisms underlying auditory cued sit-to-stand movement in Parkinson's disease.

Methods: Twenty-two Parkinson's disease patients and 24 healthy age-matched participants performed self-initiated and externally cued sit-to-stand movements while cortical activity was recorded through 32-channel mobile EEG.

Results: Overall impaired integration of sensory and motor information can be seen in the Parkinson's disease patients exhibiting less modulation in the θ band during movement compared to healthy age-matched controls. How Parkinson's disease patients use external cueing of sit-to-stand movements can be seen in larger high β power over sensorimotor brain areas compared to healthy controls, signaling sensory integration supporting the maintenance of motor output. This appears to require changes in cognitive processing to update the motor plan, reflected in frontal θ power increases in Parkinson's disease patients when cued.

Conclusion: These findings provide the first neural evidence for why and how cueing improves motor function in sit-to-stand movement in Parkinson's disease. The Parkinson's disease patients' neural correlates indicate that cueing induces greater activation of motor cortical areas supporting the maintenance of a more stable motor output, but involves the use of cognitive resources to update the motor plan. © 2024 International Parkinson and Movement Disorder Society.

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研究帕金森病患者外部诱导坐立运动的大脑机制。

背景：帕金森病患者日常生活中较具挑战性的动作之一是从坐姿开始站立。众所周知，帕金森病患者在自我启动动作时会遇到困难，因此需要外部提示来帮助他们。然而，外部提示作为一种辅助手段的大脑过程仍不为人知。现在，移动脑电图（EEG）的出现使得研究坐立动态运动中的这些过程成为可能：目的：确定帕金森病患者听觉提示坐立运动的大脑皮层相关机制：22名帕金森病患者和24名年龄匹配的健康参与者在通过32通道移动脑电图记录大脑皮层活动的同时，进行了自我启动和外部提示的坐立运动：结果：与年龄匹配的健康对照组相比，帕金森病患者在运动过程中表现出的θ波段调制较少，这表明帕金森病患者的感觉和运动信息整合能力整体受损。与健康对照组相比，帕金森病患者感觉运动脑区的θ功率较高，这表明感觉整合支持运动输出的维持。这似乎需要认知处理的变化来更新运动计划，帕金森病患者在受到提示时额叶θ功率的增加反映了这一点：这些研究结果首次提供了神经证据，说明为什么以及如何通过提示改善帕金森病患者坐立运动的运动功能。帕金森病患者的神经相关性表明，提示会诱发运动皮质区域的更大激活，支持维持更稳定的运动输出，但需要使用认知资源来更新运动计划。© 2024 国际帕金森病和运动障碍学会。

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

Movement Disorders 医学-临床神经学

CiteScore

13.30

自引率

8.10%

发文量

371

审稿时长

12 months

期刊介绍： Movement Disorders publishes a variety of content types including Reviews, Viewpoints, Full Length Articles, Historical Reports, Brief Reports, and Letters. The journal considers original manuscripts on topics related to the diagnosis, therapeutics, pharmacology, biochemistry, physiology, etiology, genetics, and epidemiology of movement disorders. Appropriate topics include Parkinsonism, Chorea, Tremors, Dystonia, Myoclonus, Tics, Tardive Dyskinesia, Spasticity, and Ataxia.