Guo Yongjian, Zhao Xumeng, Liu Xiaoyang, Liu Jiayi, Li Yan, Yue Lirong, Yuan Fulai, Zhu Yifei, Sheng Xiaona, Yu Dahua, Yuan Kai
School of Life Science and Technology, Xidian University, Xi'an, Shaanxi, China.
Department of Psychosomatic Medicine, The Second Hospital of Hebei Medical University, Shijiazhuang, China.
Gen Psychiatr. 2023 Dec 22;36(6):e101171. doi: 10.1136/gpsych-2023-101171. eCollection 2023.
Insomnia disorder (ID) is one of the most common mental disorders. Research on ID focuses on exploring its mechanism of disease, novel treatments and treatment outcome prediction. An emerging technique in this field is the use of electroencephalography (EEG) microstates, which offer a new method of EEG feature extraction that incorporates information from both temporal and spatial dimensions.
To explore the electrophysiological mechanisms of repetitive transcranial magnetic stimulation (rTMS) for ID treatment and use baseline microstate metrics for the prediction of its efficacy.
This study included 60 patients with ID and 40 age-matched and gender-matched good sleep controls (GSC). Their resting-state EEG microstates were analysed, and the Pittsburgh Sleep Quality Index (PSQI) and polysomnography (PSG) were collected to assess sleep quality. The 60 patients with ID were equally divided into active and sham groups to receive rTMS for 20 days to test whether rTMS had a moderating effect on abnormal microstates in patients with ID. Furthermore, in an independent group of 90 patients with ID who received rTMS treatment, patients were divided into optimal and suboptimal groups based on their median PSQI reduction rate. Baseline EEG microstates were used to build a machine-learning predictive model for the effects of rTMS treatment.
The class D microstate was less frequent and contribute in patients with ID, and these abnormalities were associated with sleep onset latency as measured by PSG. Additionally, the abnormalities were partially reversed to the levels observed in the GSC group following rTMS treatment. The baseline microstate characteristics could predict the therapeutic effect of ID after 20 days of rTMS, with an accuracy of 80.13%.
Our study highlights the value of EEG microstates as functional biomarkers of ID and provides a new perspective for studying the neurophysiological mechanisms of ID. In addition, we predicted the therapeutic effect of rTMS on ID based on the baseline microstates of patients with ID. This finding carries great practical significance for the selection of therapeutic options for patients with ID.
失眠症(ID)是最常见的精神障碍之一。对失眠症的研究主要集中在探索其发病机制、新的治疗方法以及治疗效果预测。该领域一种新兴技术是使用脑电图(EEG)微状态,它提供了一种新的脑电图特征提取方法,融合了时间和空间维度的信息。
探讨重复经颅磁刺激(rTMS)治疗失眠症的电生理机制,并使用基线微状态指标预测其疗效。
本研究纳入60例失眠症患者和40例年龄及性别匹配的良好睡眠对照者(GSC)。分析他们静息状态下的脑电图微状态,收集匹兹堡睡眠质量指数(PSQI)和多导睡眠图(PSG)以评估睡眠质量。60例失眠症患者平均分为治疗组和假刺激组,接受rTMS治疗20天,以测试rTMS对失眠症患者异常微状态是否有调节作用。此外,在另一组接受rTMS治疗的90例失眠症患者中,根据PSQI降低率的中位数将患者分为最佳反应组和次佳反应组。利用基线脑电图微状态建立机器学习预测模型,以预测rTMS治疗效果。
D类微状态在失眠症患者中出现频率较低且贡献较小,这些异常与PSG测量的入睡潜伏期相关。此外,rTMS治疗后,这些异常部分恢复到GSC组观察到的水平。基线微状态特征可预测rTMS治疗20天后失眠症的治疗效果,准确率为80.13%。
我们的研究突出了脑电图微状态作为失眠症功能生物标志物的价值,并为研究失眠症的神经生理机制提供了新的视角。此外,我们基于失眠症患者的基线微状态预测了rTMS对失眠症的治疗效果。这一发现对失眠症患者治疗方案的选择具有重要的实际意义。
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