Spatial-Temporal EEG Fusion Based on Neural Network for Major Depressive Disorder Detection.

IF 3.9 2区 生物学 Q1 MATHEMATICAL & COMPUTATIONAL BIOLOGY
Bingtao Zhang, Dan Wei, Guanghui Yan, Xiulan Li, Yun Su, Hanshu Cai
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引用次数: 0

Abstract

In view of the major depressive disorder characteristics such as high mortality as well as high recurrence, it is important to explore an objective and effective detection method for major depressive disorder. Considering the advantages complementary of different machine learning algorithms in information mining process, as well as the fusion complementary of different information, in this study, the spatial-temporal electroencephalography fusion framework using neural network is proposed for major depressive disorder detection. Since electroencephalography is a typical time series signal, we introduce recurrent neural network embedded in long short-term memory unit for extract temporal domain features to solve the problem of long-distance information dependence. To reduce the volume conductor effect, the temporal electroencephalography data are mapping into a spatial brain functional network using phase lag index, then the spatial domain features were extracted from brain functional network using 2D convolutional neural networks. Considering the complementarity between different types of features, the spatial-temporal electroencephalography features are fused to achieve data diversity. The experimental results show that spatial-temporal features fusion can improve the detection accuracy of major depressive disorder with a highest of 96.33%. In addition, our research also found that theta, alpha, and full frequency band in brain regions of left frontal, left central, right temporal are closely related to MDD detection, especially theta frequency band in left frontal region. Only using single-dimension EEG data as decision basis, it is difficult to fully explore the valuable information hidden in the data, which affects the overall detection performance of MDD. Meanwhile, different algorithms have their own advantages for different application scenarios. Ideally, different algorithms should use their respective advantages to jointly address complex problems in engineering fields. To this end, we propose a computer-aided MDD detection framework based on spatial-temporal EEG fusion using neural network, as shown in Fig. 1. The simplified process is as follows: (1) Raw EEG data acquisition and preprocessing. (2) The time series EEG data of each channel are input as recurrent neural network (RNN), and RNN is used to process and extract temporal domain (TD) features. (3) The BFN among different EEG channels is constructed, and CNN is used to process and extract the spatial domain (SD) features of the BFN. (4) Based on the theory of information complementarity, the spatial-temporal information is fused to realize efficient MDD detection. Fig. 1 MDD detection framework based on spatial-temporal EEG fusion.

Abstract Image

Abstract Image

Abstract Image

基于神经网络的脑电时空融合在抑郁症检测中的应用。
鉴于重性抑郁症的高死亡率和高复发率等特点,探索一种客观有效的重性抑郁症检测方法具有重要意义。考虑到不同机器学习算法在信息挖掘过程中的优势互补,以及不同信息的融合互补,本研究提出了一种基于神经网络的时空脑电融合框架,用于抑郁症的检测。由于脑电图是一个典型的时间序列信号,我们引入了嵌入长短期记忆单元的递归神经网络来提取时域特征,以解决远距离信息依赖的问题。为了减少体积导体效应,使用相位滞后指数将时间脑电图数据映射到空间脑功能网络中,然后使用2D卷积神经网络从脑功能网络提取空间域特征。考虑到不同类型特征之间的互补性,将时空脑电图特征融合以实现数据多样性。实验结果表明,时空特征融合可以提高重性抑郁障碍的检测准确率,最高可达96.33%。此外,我们的研究还发现,左额、左中、右颞脑区的θ、α和全频带与MDD检测密切相关,尤其是左额区的θ频带。仅使用一维脑电数据作为决策基础,很难充分挖掘数据中隐藏的有价值信息,这影响了MDD的整体检测性能。同时,对于不同的应用场景,不同的算法也有各自的优势。理想情况下,不同的算法应该利用各自的优势来共同解决工程领域中的复杂问题。为此,我们提出了一种基于神经网络时空脑电融合的计算机辅助MDD检测框架,如图所示。1。简化过程如下:(1)原始脑电图数据的采集和预处理。(2) 每个通道的时间序列EEG数据作为递归神经网络(RNN)输入,并使用RNN处理和提取时域(TD)特征。(3) 构造了不同脑电通道之间的BFN,并使用CNN对BFN的空间域(SD)特征进行处理和提取。(4) 基于信息互补理论,对时空信息进行融合,实现高效的MDD检测。图1基于时空脑电融合的MDD检测框架。
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来源期刊
Interdisciplinary Sciences: Computational Life Sciences
Interdisciplinary Sciences: Computational Life Sciences MATHEMATICAL & COMPUTATIONAL BIOLOGY-
CiteScore
8.60
自引率
4.20%
发文量
55
期刊介绍: Interdisciplinary Sciences--Computational Life Sciences aims to cover the most recent and outstanding developments in interdisciplinary areas of sciences, especially focusing on computational life sciences, an area that is enjoying rapid development at the forefront of scientific research and technology. The journal publishes original papers of significant general interest covering recent research and developments. Articles will be published rapidly by taking full advantage of internet technology for online submission and peer-reviewing of manuscripts, and then by publishing OnlineFirstTM through SpringerLink even before the issue is built or sent to the printer. The editorial board consists of many leading scientists with international reputation, among others, Luc Montagnier (UNESCO, France), Dennis Salahub (University of Calgary, Canada), Weitao Yang (Duke University, USA). Prof. Dongqing Wei at the Shanghai Jiatong University is appointed as the editor-in-chief; he made important contributions in bioinformatics and computational physics and is best known for his ground-breaking works on the theory of ferroelectric liquids. With the help from a team of associate editors and the editorial board, an international journal with sound reputation shall be created.
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