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左侧下顶叶和左侧颞叶过度活跃会缩短精神分裂症静息 EEG 微状态。

Hyperactivation of left inferior parietal lobule and left temporal gyri shortens resting EEG microstate in schizophrenia.

机构信息

Stress and Cognitive Electroimaging Laboratory, Department of Physiology, All India Institute of Medical Sciences, New Delhi, India.

Department of Psychiatry, All India Institute of Medical Sciences, New Delhi, India.

出版信息

Schizophr Res. 2018 Nov;201:204-207. doi: 10.1016/j.schres.2018.06.020. Epub 2018 Jun 18.

DOI:10.1016/j.schres.2018.06.020
PMID:29925477
Abstract

OBJECTIVE

The momentary spatial configuration of the brain electric field at the scalp reflects quasi-stable "functional microstates" caused by activity of different intracranial generators. There is paucity in literature on the intracranial generators of resting state EEG microstate alterations in stable patients with schizophrenia. The present study aimed to investigate resting state microstate alterations and their neural generators in patients with schizophrenia and their first-degree relatives as compared to healthy controls in an attempt to establish state and trait marker.

METHOD

Thirty-four patients with schizophrenia (DSM-5 criteria), 29 first-degree relatives and 25 matched healthy controls participated in the study. Brain activity during eyes closed condition was recorded using 128 channel electroencephalography. Microstates were clustered into 5 maps across groups according to their topography. Microstate map parameters and their cortical sources were compared among groups.

RESULTS

Map 5 mean duration (χ(2) = 7.617, p = 0.022) was significantly lower in patients compared to controls (U = 256, p = 0.010). Maximum activation was seen in left inferior parietal lobule (MNI coordinates: -65, -35, 25, Log-F = 0.748). Suprathreshold cortical voxels with increased activations were found localized at left temporal gyri.

CONCLUSION

Hyperactivation in left inferior parietal lobule and temporal gyri might have shortened Map 5 duration at rest in patients with schizophrenia. This could imply microstate alterations as the potential state marker of schizophrenia.

摘要

目的

头皮脑电场的瞬间空间构型反映了由不同颅内发生器活动引起的准稳定“功能微状态”。关于稳定精神分裂症患者静息状态 EEG 微状态改变的颅内发生器,文献甚少。本研究旨在探讨精神分裂症患者及其一级亲属与健康对照者在静息状态下微状态改变及其神经发生器的差异,试图建立状态和特征性标记。

方法

34 名符合 DSM-5 标准的精神分裂症患者、29 名一级亲属和 25 名匹配的健康对照者参加了研究。使用 128 通道脑电图记录闭眼状态下的脑活动。根据地形将微状态聚类为 5 个图谱,在组间进行比较。比较各组微状态图谱参数及其皮质源。

结果

与对照组相比,患者组的 5 号图谱平均持续时间(χ(2) = 7.617,p = 0.022)显著降低(U = 256,p = 0.010)。最大激活出现在左顶下小叶(MNI 坐标:-65,-35,25,Log-F = 0.748)。发现左颞叶有增加激活的皮质阈下体素。

结论

左顶下小叶和颞叶的过度激活可能导致精神分裂症患者静息时 5 号图谱持续时间缩短。这可能意味着微状态改变是精神分裂症的潜在状态标志物。

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