经颅磁刺激-脑电图对脑卒中后上肢运动功能的生物标志物研究。

Transcranial Magnetic Stimulation-EEG Biomarkers of Poststroke Upper-Limb Motor Function.

机构信息

Innovation, Implementation and Clinical Translation in Health (IIMPACT), Division of Health Sciences, University of South Australia, Adelaide, Australia.

The Robinson Research Institute, Adelaide Medical School, The University of Adelaide, Adelaide, Australia.

出版信息

J Stroke Cerebrovasc Dis. 2019 Dec;28(12):104452. doi: 10.1016/j.jstrokecerebrovasdis.2019.104452. Epub 2019 Oct 19.

DOI:10.1016/j.jstrokecerebrovasdis.2019.104452

PMID:31635964

Abstract

BACKGROUND

Motor evoked potentials obtained with transcranial magnetic stimulation (TMS) can provide valuable information to inform stroke neurophysiology and recovery but are difficult to obtain in all stroke survivors due to high stimulation thresholds.

OBJECTIVE

To determine whether transcranial magnetic stimulation evoked potentials (TEPs) evoked using a lower stimulus intensity, below that necessary for recording motor evoked potentials, could serve as a marker of poststroke upper-limb motor function and were different compared to healthy adults.

METHODS

Eight chronic stroke survivors (66 ± 21 years) and 15 healthy adults (53 ± 10 years) performed a motor function task using a customized grip-lift manipulandum. TMS was applied to the lesioned motor cortex, with TEPs recorded using simultaneous high-definition electroencephalography (EEG).

RESULTS

Stroke participants demonstrated greater hold ratio with the manipulandum. Cluster-based statistics revealed larger P30 amplitude in stroke participants, with significant clusters over frontal (P = .016) and parietal-occipital electrodes (P = .023). There was a negative correlation between the N45 peak amplitude and hold ratio in stroke participants (r = -.83, P = .02), but not controls.

CONCLUSIONS

TEPs can be recorded using lower stimulus intensities in chronic stroke. The global P30 TEP response differed between stroke participants and healthy controls, with results suggesting that the TEP can be used as a biomarker of upper-limb behavior.

摘要

背景

经颅磁刺激（TMS）获得的运动诱发电位可以为脑卒中神经生理学和恢复提供有价值的信息，但由于刺激阈值较高，并非所有脑卒中幸存者都能获得。

目的

确定使用低于记录运动诱发电位所需强度的刺激来诱发经颅磁刺激诱发电位（TEP）是否可以作为脑卒中后上肢运动功能的标志物，并且与健康成年人有所不同。

方法

8 名慢性脑卒中幸存者（66 ± 21 岁）和 15 名健康成年人（53 ± 10 岁）使用定制的握力提升操作杆进行了一项运动功能任务。TMS 应用于受损的运动皮层，同时使用高清晰度脑电图（EEG）记录 TEPs。

结果

脑卒中参与者在操作杆上表现出更高的保持比例。基于聚类的统计学分析显示，脑卒中参与者的 P30 振幅更大，在额部（P = .016）和顶枕部电极（P = .023）有显著的集群。脑卒中参与者的 N45 峰值振幅与保持比例呈负相关（r = -.83，P = .02），而对照组则没有。

结论

在慢性脑卒中患者中可以使用较低的刺激强度记录 TEPs。脑卒中参与者和健康对照组之间的全局 P30 TEP 反应存在差异，结果表明 TEP 可以作为上肢行为的生物标志物。

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经颅磁刺激-脑电图对脑卒中后上肢运动功能的生物标志物研究。

Transcranial Magnetic Stimulation-EEG Biomarkers of Poststroke Upper-Limb Motor Function.

机构信息

出版信息

BACKGROUND

OBJECTIVE

METHODS

RESULTS

CONCLUSIONS

背景

目的

方法

结果

结论

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