脑电对 TMS 反应的大脑起源：严重皮质病变的启示。

On the cerebral origin of EEG responses to TMS: insights from severe cortical lesions.

机构信息

Coma Science Group, Cyclotron Research Center and Neurology Department, University and University Hospital of Liège, Liège, Belgium; Postle Laboratory and Center for Sleep and Consciousness, Department of Psychiatry and Psychology, University of Wisconsin, Madison, WI, USA.

Department of Biomedical and Clinical Sciences "Luigi Sacco", University of Milan, Milan, Italy.

出版信息

Brain Stimul. 2015 Jan-Feb;8(1):142-9. doi: 10.1016/j.brs.2014.10.008. Epub 2014 Oct 18.

DOI:10.1016/j.brs.2014.10.008

PMID:25481074

Abstract

BACKGROUND

Transcranial magnetic stimulation combined with electroencephalography (TMS/EEG) represents a valuable tool to probe cortical excitability and connectivity. Although several procedures have been devised to abolish TMS-related artifacts, direct evidence that it is possible to record TMS-evoked potentials (TEPs) that purely reflect cortical responses to TMS are still lacking.

OBJECTIVE

To demonstrate that when TMS is delivered on a human head with intact nerves, scalp and ocular muscles, TEPs are present only if a functional portion of cortex is targeted and is absent otherwise.

METHODS

We performed extensive navigated TMS/EEG mappings in three vegetative state patients and in eight healthy controls. Patients were selected based on the extension of their cortical lesions as revealed by structural/functional imaging: the cerebral cortex was globally damaged in Patient 1 due to cerebral anoxia, Patient 2 showed a traumatic damage affecting one cerebral hemisphere, while Patient 3 was characterized by one left sided and one right-sided focal ischemic lesion.

RESULTS

In Patient 1, TMS performed at any targeted cortical site did not elicit statistically significant TEPs. In Patient 2, TEPs were absent when the damaged hemisphere was targeted, while were present over the healthy side. In Patient 3, significant TEPs were absent when cortical lesions were targeted and present otherwise. Significant TEPs were always present in healthy controls.

CONCLUSIONS

These findings suggest that, provided that appropriate experimental procedures are employed, TEPs are genuine cortical responses detectable only when preserved cortical tissue is stimulated. Hence, a dependable assessment of cortical excitability and connectivity in brain-injured patients requires the use of neuronavigated TMS.

摘要

背景

经颅磁刺激结合脑电图（TMS/EEG）代表了一种有价值的工具，可以探测皮质兴奋性和连通性。尽管已经设计了几种程序来消除 TMS 相关的伪影，但仍然缺乏直接证据表明可以记录到纯粹反映 TMS 对皮质反应的 TMS 诱发电位（TEPs）。

目的

证明当 TMS 在具有完整神经、头皮和眼肌的人头头上施加时，如果目标是皮质的功能部分，则存在 TEPs，否则不存在。

方法

我们在三名植物状态患者和八名健康对照者中进行了广泛的导航 TMS/EEG 映射。患者是根据结构/功能成像显示的皮质病变范围选择的：由于脑缺氧，患者 1 的大脑皮质全部受损；患者 2 表现出影响一侧大脑半球的创伤性损伤；而患者 3 的特征是一侧和另一侧的局灶性缺血性病变。

结果

在患者 1 中，在任何目标皮质部位进行的 TMS 均未引起统计学上显著的 TEPs。在患者 2 中，当靶向受损半球时，TEPs 不存在，而在健康侧存在。在患者 3 中，当靶向皮质病变时，不存在显著的 TEPs，而在其他情况下存在。在健康对照组中，总是存在显著的 TEPs。

结论

这些发现表明，只要采用适当的实验程序，TEPs 就是仅在存在保存的皮质组织刺激时才能检测到的真正皮质反应。因此，对脑损伤患者的皮质兴奋性和连通性进行可靠评估需要使用神经导航 TMS。

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脑电对 TMS 反应的大脑起源：严重皮质病变的启示。

On the cerebral origin of EEG responses to TMS: insights from severe cortical lesions.

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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