Department of Psychiatry and Behavioural Neurosciences, McMaster University, Hamilton, Canada; Homewood Research Institute, Guelph, Canada.
Department of Psychiatry, Western University, London, Canada; Homewood Research Institute, Guelph, Canada; Vector Institute, Toronto, Canada.
Neuroimage Clin. 2022;35:103135. doi: 10.1016/j.nicl.2022.103135. Epub 2022 Jul 29.
Microstates offer a promising framework to study fast-scale brain dynamics in the resting-state electroencephalogram (EEG). However, microstate dynamics have yet to be investigated in post-traumatic stress disorder (PTSD), despite research demonstrating resting-state alterations in PTSD. We performed microstate-based segmentation of resting-state EEG in a clinical population of participants with PTSD (N = 61) and a non-traumatized, healthy control group (N = 61). Microstate-based measures (i.e., occurrence, mean duration, time coverage) were compared group-wise using broadband (1-30 Hz) and frequency-specific (i.e., delta, theta, alpha, beta bands) decompositions. In the broadband comparisons, the centro-posterior maximum microstate (map E) occurred significantly less frequently (d = -0.64, pFWE = 0.03) and had a significantly shorter mean duration in participants with PTSD as compared to controls (d = -0.71, pFWE < 0.01). These differences were reflected in the narrow frequency bands as well, with lower frequency bands like delta (d = -0.78, pFWE < 0.01), theta (d = -0.74, pFWE = 0.01), and alpha (d = -0.65, pFWE = 0.02) repeating these group-level trends, only with larger effect sizes. Interestingly, a support vector machine classification analysis comparing broadband and frequency-specific measures revealed that models containing only alpha band features significantly out-perform broadband models. When classifying PTSD, the classification accuracy was 76 % and 65 % for the alpha band and the broadband model, respectively (p = 0.03). Taken together, we provide original evidence supporting the clinical utility of microstates as diagnostic markers of PTSD and demonstrate that filtering EEG into distinct frequency bands significantly improves microstate-based classification of a psychiatric disorder.
微状态为研究静息态脑电图(EEG)中的快速尺度脑动力学提供了一个很有前景的框架。然而,尽管有研究表明 PTSD 存在静息态改变,但微状态动力学尚未在创伤后应激障碍(PTSD)中得到研究。我们对 PTSD 患者(N=61)和非创伤、健康对照组(N=61)的静息态 EEG 进行了基于微状态的分割。使用宽带(1-30 Hz)和频带特异性(即 delta、theta、alpha、beta 频带)分解,在组间比较基于微状态的测量(即发生、平均持续时间、时间覆盖率)。在宽带比较中,与对照组相比,PTSD 患者的中央-后最大微状态(map E)发生的频率显著降低(d=-0.64,pFWE=0.03),平均持续时间也显著缩短(d=-0.71,pFWE<0.01)。这些差异在窄频带中也得到了反映,低频带如 delta(d=-0.78,pFWE<0.01)、theta(d=-0.74,pFWE=0.01)和 alpha(d=-0.65,pFWE=0.02)也出现了类似的组间趋势,只是效应量更大。有趣的是,比较宽带和频带特异性测量的支持向量机分类分析表明,仅包含 alpha 频带特征的模型明显优于宽带模型。在对 PTSD 进行分类时,alpha 频带和宽带模型的分类准确率分别为 76%和 65%(p=0.03)。总之,我们提供了支持微状态作为 PTSD 诊断标志物的临床效用的原始证据,并证明将 EEG 过滤到不同频带中可以显著提高基于微状态的精神障碍分类。
