EEG microstate biomarkers for schizophrenia: a novel approach using deep neural networks.

IF 3.1 3区工程技术 Q2 NEUROSCIENCES

Cognitive Neurodynamics Pub Date : 2025-12-01 Epub Date: 2025-05-03 DOI:10.1007/s11571-025-10251-z

Zahra Raeisi, Omid Bashiri, MohammadReza EskandariNasab, Mahdi Arshadi, Alireza Golkarieh, Hossein Najafzadeh

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Abstract

Schizophrenia remains a challenging neuropsychiatric disorder with complex diagnostic processes. Current clinical approaches often rely on subjective assessments, highlighting the critical need for objective, quantitative diagnostic methods. This study aimed to develop a robust classification approach for schizophrenia using EEG microstate analysis and advanced machine learning techniques. We analyzed EEG signals from 14 healthy individuals and 14 patients with schizophrenia during a 15-min resting-state session across 19 EEG channels. A data augmentation strategy expanded the dataset to 56 subjects in each group. The signals were preprocessed and segmented into five frequency bands (delta, theta, alpha, beta, gamma) and five microstates (A, B, C, D, E) using k-means clustering. Five key features were extracted from each microstate: duration, occurrence, standard deviation, coverage, and frequency. A Deep Neural Network (DNN) model, along with other machine learning classifiers, was developed to classify the data. A comprehensive fivefold cross-validation approach evaluated model performance across various EEG channels, frequency bands, and feature combinations. Significant alterations in microstate transition probabilities were observed, particularly in higher frequency bands. The gamma band showed the most pronounced differences, with a notable disruption in D → A transitions (absolute difference = 0.100). The Random Forest classifier achieved the highest accuracy of 99.94% ± 0.12%, utilizing theta band features from the F8 frontal channel. The deep neural network model demonstrated robust performance with 98.31% ± 0.68% accuracy, primarily in the occipital region. Feature size 2 consistently provided optimal classification across most models. Our study introduces a novel, high-precision EEG microstate analysis approach for schizophrenia diagnosis, offering an objective diagnostic tool with potential applications in neuropsychiatric disorders. The findings reveal critical insights into neural dynamics associated with schizophrenia, demonstrating the potential for transforming clinical diagnostic practices through advanced machine learning and neurophysiological feature extraction.

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精神分裂症的EEG微状态生物标志物：一种使用深度神经网络的新方法。

精神分裂症仍然是一种具有复杂诊断过程的具有挑战性的神经精神疾病。目前的临床方法往往依赖于主观评估，强调了对客观、定量诊断方法的迫切需要。本研究旨在利用EEG微状态分析和先进的机器学习技术开发一种强大的精神分裂症分类方法。我们分析了14名健康个体和14名精神分裂症患者在15分钟静息状态下的19个脑电图通道的脑电图信号。数据增强策略将数据集扩展到每组56个受试者。对信号进行预处理，并使用k-means聚类将其分割为5个频段（delta、theta、alpha、beta、gamma）和5个微观状态（A、B、C、D、E）。从每个微状态中提取五个关键特征：持续时间、发生次数、标准偏差、覆盖范围和频率。开发了深度神经网络（DNN）模型以及其他机器学习分类器来对数据进行分类。综合的五重交叉验证方法评估了模型在不同EEG通道、频带和特征组合中的性能。观察到微态转变概率的显著变化，特别是在较高的频段。伽玛波段差异最明显，D→a跃迁明显中断（绝对差= 0.100）。随机森林分类器利用F8正面通道的θ波段特征，达到了99.94%±0.12%的最高准确率。该深度神经网络模型的准确率为98.31%±0.68%，主要集中在枕区。特征大小2始终在大多数模型中提供最佳分类。本研究为精神分裂症的诊断提供了一种新的、高精度的脑电图微状态分析方法，为神经精神疾病的诊断提供了一种具有潜在应用价值的客观诊断工具。这些发现揭示了与精神分裂症相关的神经动力学的重要见解，展示了通过先进的机器学习和神经生理特征提取改变临床诊断实践的潜力。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Cognitive Neurodynamics 医学-神经科学

CiteScore

6.90

自引率

18.90%

发文量

140

审稿时长

12 months

期刊介绍： Cognitive Neurodynamics provides a unique forum of communication and cooperation for scientists and engineers working in the field of cognitive neurodynamics, intelligent science and applications, bridging the gap between theory and application, without any preference for pure theoretical, experimental or computational models. The emphasis is to publish original models of cognitive neurodynamics, novel computational theories and experimental results. In particular, intelligent science inspired by cognitive neuroscience and neurodynamics is also very welcome. The scope of Cognitive Neurodynamics covers cognitive neuroscience, neural computation based on dynamics, computer science, intelligent science as well as their interdisciplinary applications in the natural and engineering sciences. Papers that are appropriate for non-specialist readers are encouraged. 1. There is no page limit for manuscripts submitted to Cognitive Neurodynamics. Research papers should clearly represent an important advance of especially broad interest to researchers and technologists in neuroscience, biophysics, BCI, neural computer and intelligent robotics. 2. Cognitive Neurodynamics also welcomes brief communications: short papers reporting results that are of genuinely broad interest but that for one reason and another do not make a sufficiently complete story to justify a full article publication. Brief Communications should consist of approximately four manuscript pages. 3. Cognitive Neurodynamics publishes review articles in which a specific field is reviewed through an exhaustive literature survey. There are no restrictions on the number of pages. Review articles are usually invited, but submitted reviews will also be considered.