Schizophrenia diagnosis using the GRU-layer's alpha-EEG rhythm's dependability

IF 2.1 4区医学 Q3 CLINICAL NEUROLOGY Psychiatry Research: Neuroimaging Pub Date : 2024-08-28 DOI:10.1016/j.pscychresns.2024.111886

Pankaj Kumar Sahu, Karan Jain

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Abstract

Verifying schizophrenia (SZ) can be assisted by deep learning techniques and patterns in brain activity observed in alpha-EEG recordings. The suggested research provides evidence of the reliability of alpha-EEG rhythm in a Gated-Recurrent-Unit-based deep-learning model for investigating SZ. This study suggests Rudiment Densely-Coupled Convolutional Gated Recurrent Unit (RDCGRU) for the various EEG-rhythm-based (gamma, beta, alpha, theta, and delta) diagnoses of SZ. The model includes multiple 1-D-Convolution (Con-1-D) folds with steps greater than 1, which enables the model to programmatically and effectively learn how to reduce the incoming signal. The Con-1-D layers and numerous Gated Recurrent Unit (GRU) layers comprise the Exponential-Linear-Unit activation function. This powerful activation function facilitates in-deep-network training and improves classification performance. The Densely-Coupled Convolutional Gated Recurrent Unit (DCGRU) layers enable RDCGRU to address the training accuracy loss brought on by vanishing or exploding gradients, and this might make it possible to develop intense, deep versions of RDCGRU for more complex problems. The sigmoid activation function is implemented in the digital (binary) classifier's output nodes. The RDCGRU deep learning model attained the most excellent accuracy, 88.88 %, with alpha-EEG rhythm. The research achievements: The RDCGRU deep learning model's GRU cells responded superiorly to the alpha-EEG rhythm in EEG-based verification of SZ.

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利用 GRU 层的α-EEG 节奏可靠性诊断精神分裂症

通过深度学习技术和α-EEG记录中观察到的大脑活动模式，可以帮助验证精神分裂症（SZ）。建议的研究为基于门控-递归单元的深度学习模型调查 SZ 提供了阿尔法-脑电图节律可靠性的证据。这项研究提出了基于 Rudiment Densely-Coupled Convolutional Gated Recurrent Unit (RDCGRU) 的 SZ 诊断方法，适用于各种基于脑电图节奏（γ、β、α、θ 和 δ）的 SZ 诊断。该模型包括多个步长大于 1 的一维卷积（Con-1-D）褶皱，这使得该模型能够通过编程有效地学习如何减少输入信号。Con-1-D 层和多个门控递归单元 (GRU) 层构成了指数线性单元激活函数。这一功能强大的激活函数有助于深度网络训练并提高分类性能。密集耦合卷积门控递归单元（DCGRU）层使 RDCGRU 能够解决梯度消失或爆炸带来的训练精度损失问题，这可能会使 RDCGRU 开发出针对更复杂问题的高强度深度版本成为可能。在数字（二进制）分类器的输出节点中实现了 sigmoid 激活函数。RDCGRU 深度学习模型在α-EEG 韵律方面取得了最出色的准确率（88.88%）。研究成果：RDCGRU深度学习模型的GRU单元对基于脑电图的SZ验证中α-EEG节律的响应更优。

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来源期刊

Psychiatry Research: Neuroimaging 医学-精神病学

CiteScore

3.80

自引率

0.00%

发文量

审稿时长

22.5 weeks

期刊介绍： The Neuroimaging section of Psychiatry Research publishes manuscripts on positron emission tomography, magnetic resonance imaging, computerized electroencephalographic topography, regional cerebral blood flow, computed tomography, magnetoencephalography, autoradiography, post-mortem regional analyses, and other imaging techniques. Reports concerning results in psychiatric disorders, dementias, and the effects of behaviorial tasks and pharmacological treatments are featured. We also invite manuscripts on the methods of obtaining images and computer processing of the images themselves. Selected case reports are also published.