{"title":"利用有效连接网络研究自闭症患者大脑中的电信号","authors":"Farzaneh Bahrami, Maryam Taghizadeh, Farzaneh Shayegh","doi":"10.4103/jmss.jmss_15_24","DOIUrl":null,"url":null,"abstract":"<p><p>Unlike other functional integration methods that examine the relationship and correlation between two channels, effective connection reports the direct effect of one channel on another and expresses their causal relationship. In this article, we investigate and classify electroencephalographic (EEG) signals based on effective connectivity. In this study, we leverage the Granger causality (GC) relationship, a method for measuring effective connectivity, to analyze EEG signals from both healthy individuals and those with autism. The EEG signals examined in this article were recorded during the presentation of abstract images. Given the nonstationary nature of EEG signals, a vector autoregression model has been employed to model the relationships between signals across different channels. GC is then used to quantify the influence of these channels on one another. Selecting regions of interest (ROI) is a critical step, as the quality of the time periods under consideration significantly impacts the outcomes of the connectivity analysis among the electrodes. By comparing these effects in the ROI and various areas, we have distinguished healthy subjects from those suffering from autism. Furthermore, through statistical analysis, we have compared the results between healthy individuals and those with autism. 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引用次数: 0
摘要
与其他研究两个通道之间关系和相关性的功能整合方法不同,有效连接报告了一个通道对另一个通道的直接影响,并表达了它们之间的因果关系。在本文中,我们根据有效连接对脑电图(EEG)信号进行研究和分类。在这项研究中,我们利用格兰杰因果关系(GC)这一测量有效连通性的方法来分析健康人和自闭症患者的脑电信号。本文研究的脑电信号是在呈现抽象图像时记录的。鉴于脑电信号的非平稳性,我们采用了向量自回归模型来模拟不同通道信号之间的关系。然后利用 GC 量化这些通道之间的相互影响。选择感兴趣区(ROI)是一个关键步骤,因为所考虑的时间段的质量会对电极之间的连接性分析结果产生重大影响。通过比较 ROI 和不同区域的这些影响,我们将健康受试者与自闭症患者区分开来。此外,通过统计分析,我们还比较了健康人和自闭症患者之间的结果。我们发现,与自闭症患者相比,健康人这两个半球之间的因果关系明显较弱。
Investigation of Electrical Signals in the Brain of People with Autism Using Effective Connectivity Network.
Unlike other functional integration methods that examine the relationship and correlation between two channels, effective connection reports the direct effect of one channel on another and expresses their causal relationship. In this article, we investigate and classify electroencephalographic (EEG) signals based on effective connectivity. In this study, we leverage the Granger causality (GC) relationship, a method for measuring effective connectivity, to analyze EEG signals from both healthy individuals and those with autism. The EEG signals examined in this article were recorded during the presentation of abstract images. Given the nonstationary nature of EEG signals, a vector autoregression model has been employed to model the relationships between signals across different channels. GC is then used to quantify the influence of these channels on one another. Selecting regions of interest (ROI) is a critical step, as the quality of the time periods under consideration significantly impacts the outcomes of the connectivity analysis among the electrodes. By comparing these effects in the ROI and various areas, we have distinguished healthy subjects from those suffering from autism. Furthermore, through statistical analysis, we have compared the results between healthy individuals and those with autism. It has been observed that the causal relationship between these two hemispheres is significantly weaker in healthy individuals compared to those with autism.
期刊介绍:
JMSS is an interdisciplinary journal that incorporates all aspects of the biomedical engineering including bioelectrics, bioinformatics, medical physics, health technology assessment, etc. Subject areas covered by the journal include: - Bioelectric: Bioinstruments Biosensors Modeling Biomedical signal processing Medical image analysis and processing Medical imaging devices Control of biological systems Neuromuscular systems Cognitive sciences Telemedicine Robotic Medical ultrasonography Bioelectromagnetics Electrophysiology Cell tracking - Bioinformatics and medical informatics: Analysis of biological data Data mining Stochastic modeling Computational genomics Artificial intelligence & fuzzy Applications Medical softwares Bioalgorithms Electronic health - Biophysics and medical physics: Computed tomography Radiation therapy Laser therapy - Education in biomedical engineering - Health technology assessment - Standard in biomedical engineering.
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