Cross-subject classification of depression by using multiparadigm EEG feature fusion

•A multiparadigm feature fusion method was proposed to distinguish depression.•The significance of EEG feature from eyes open and closed in the resting state for depression classification were discussed and compared in detail.•It proved that fusion of eyes open and closed EEG can efficiently promote...

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Published inComputer methods and programs in biomedicine Vol. 233; p. 107360
Main Authors Yang, Jianli, Zhang, Zhen, Fu, Zhiyu, Li, Bing, Xiong, Peng, Liu, Xiuling
Format Journal Article
LanguageEnglish
Published Ireland Elsevier B.V 01.05.2023
Subjects
Brain
Cross-subject
Depression
Depression - diagnosis
EEG
Electroencephalography - methods
Eye
Feature fusion
Multiparadigm
Support Vector Machine
Multiparadigm
Depression
Feature fusion
Cross-subject
EEG
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Abstract •A multiparadigm feature fusion method was proposed to distinguish depression.•The significance of EEG feature from eyes open and closed in the resting state for depression classification were discussed and compared in detail.•It proved that fusion of eyes open and closed EEG can efficiently promote the classification accuracy of depression, and it was closely related to the fusion methods.•Cross-subject validation was performed, and yield a classification accuracy of 94.03%. The aim of this study is to solve the non-stationarity and complexity characteristics and huge individual differences in the electroencephalogram (EEG) signals for depression classification. To address those problems, the Lempel–Ziv complexity feature matrices were extracted from the EEG signals under the two paradigms of eyes open and eyes closed in the resting state. Topographical map of brain and statistical analysis were introduced to investigate the significance of eyes open and eyes closed EEG for depression classification. To promote the classification accuracy, feature matrices from the two paradigms were fused. And linear combination and concatenation fusion methods were proposed to further reveal the underlying mechanism of improving classification accuracy. Support vector machine (SVM), K-nearest neighbor, and decision tree classifiers were employed and compared to classify depression under the eyes open, eyes closed and fused paradigm. The classification results of 10-fold cross-validation showed that the highest average accuracy (86.58%) under a single paradigm was achieved in the eyes-open state. The multiparadigm fusion method of concatenation was better than the linear combination. The best classification result was obtained using multiparadigm feature concatenation under the SVM classifier, yielding an accuracy of 94.03%. The multiparadigm feature fusion method proposed in this paper can effectively improve the accuracy of depression classification. It was proved that eyes open and eyes closed EEG have complementary information, which was benefit for the cross-subject classification of depression. It provides new ideas for depression classification in clinics.
AbstractList •A multiparadigm feature fusion method was proposed to distinguish depression.•The significance of EEG feature from eyes open and closed in the resting state for depression classification were discussed and compared in detail.•It proved that fusion of eyes open and closed EEG can efficiently promote the classification accuracy of depression, and it was closely related to the fusion methods.•Cross-subject validation was performed, and yield a classification accuracy of 94.03%. The aim of this study is to solve the non-stationarity and complexity characteristics and huge individual differences in the electroencephalogram (EEG) signals for depression classification. To address those problems, the Lempel–Ziv complexity feature matrices were extracted from the EEG signals under the two paradigms of eyes open and eyes closed in the resting state. Topographical map of brain and statistical analysis were introduced to investigate the significance of eyes open and eyes closed EEG for depression classification. To promote the classification accuracy, feature matrices from the two paradigms were fused. And linear combination and concatenation fusion methods were proposed to further reveal the underlying mechanism of improving classification accuracy. Support vector machine (SVM), K-nearest neighbor, and decision tree classifiers were employed and compared to classify depression under the eyes open, eyes closed and fused paradigm. The classification results of 10-fold cross-validation showed that the highest average accuracy (86.58%) under a single paradigm was achieved in the eyes-open state. The multiparadigm fusion method of concatenation was better than the linear combination. The best classification result was obtained using multiparadigm feature concatenation under the SVM classifier, yielding an accuracy of 94.03%. The multiparadigm feature fusion method proposed in this paper can effectively improve the accuracy of depression classification. It was proved that eyes open and eyes closed EEG have complementary information, which was benefit for the cross-subject classification of depression. It provides new ideas for depression classification in clinics.
The aim of this study is to solve the non-stationarity and complexity characteristics and huge individual differences in the electroencephalogram (EEG) signals for depression classification. To address those problems, the Lempel-Ziv complexity feature matrices were extracted from the EEG signals under the two paradigms of eyes open and eyes closed in the resting state. Topographical map of brain and statistical analysis were introduced to investigate the significance of eyes open and eyes closed EEG for depression classification. To promote the classification accuracy, feature matrices from the two paradigms were fused. And linear combination and concatenation fusion methods were proposed to further reveal the underlying mechanism of improving classification accuracy. Support vector machine (SVM), K-nearest neighbor, and decision tree classifiers were employed and compared to classify depression under the eyes open, eyes closed and fused paradigm. The classification results of 10-fold cross-validation showed that the highest average accuracy (86.58%) under a single paradigm was achieved in the eyes-open state. The multiparadigm fusion method of concatenation was better than the linear combination. The best classification result was obtained using multiparadigm feature concatenation under the SVM classifier, yielding an accuracy of 94.03%. The multiparadigm feature fusion method proposed in this paper can effectively improve the accuracy of depression classification. It was proved that eyes open and eyes closed EEG have complementary information, which was benefit for the cross-subject classification of depression. It provides new ideas for depression classification in clinics.
The aim of this study is to solve the non-stationarity and complexity characteristics and huge individual differences in the electroencephalogram (EEG) signals for depression classification.BACKGROUND AND OBJECTIVEThe aim of this study is to solve the non-stationarity and complexity characteristics and huge individual differences in the electroencephalogram (EEG) signals for depression classification.To address those problems, the Lempel-Ziv complexity feature matrices were extracted from the EEG signals under the two paradigms of eyes open and eyes closed in the resting state. Topographical map of brain and statistical analysis were introduced to investigate the significance of eyes open and eyes closed EEG for depression classification. To promote the classification accuracy, feature matrices from the two paradigms were fused. And linear combination and concatenation fusion methods were proposed to further reveal the underlying mechanism of improving classification accuracy. Support vector machine (SVM), K-nearest neighbor, and decision tree classifiers were employed and compared to classify depression under the eyes open, eyes closed and fused paradigm.METHODSTo address those problems, the Lempel-Ziv complexity feature matrices were extracted from the EEG signals under the two paradigms of eyes open and eyes closed in the resting state. Topographical map of brain and statistical analysis were introduced to investigate the significance of eyes open and eyes closed EEG for depression classification. To promote the classification accuracy, feature matrices from the two paradigms were fused. And linear combination and concatenation fusion methods were proposed to further reveal the underlying mechanism of improving classification accuracy. Support vector machine (SVM), K-nearest neighbor, and decision tree classifiers were employed and compared to classify depression under the eyes open, eyes closed and fused paradigm.The classification results of 10-fold cross-validation showed that the highest average accuracy (86.58%) under a single paradigm was achieved in the eyes-open state. The multiparadigm fusion method of concatenation was better than the linear combination. The best classification result was obtained using multiparadigm feature concatenation under the SVM classifier, yielding an accuracy of 94.03%.RESULTSThe classification results of 10-fold cross-validation showed that the highest average accuracy (86.58%) under a single paradigm was achieved in the eyes-open state. The multiparadigm fusion method of concatenation was better than the linear combination. The best classification result was obtained using multiparadigm feature concatenation under the SVM classifier, yielding an accuracy of 94.03%.The multiparadigm feature fusion method proposed in this paper can effectively improve the accuracy of depression classification. It was proved that eyes open and eyes closed EEG have complementary information, which was benefit for the cross-subject classification of depression. It provides new ideas for depression classification in clinics.CONCLUSIONThe multiparadigm feature fusion method proposed in this paper can effectively improve the accuracy of depression classification. It was proved that eyes open and eyes closed EEG have complementary information, which was benefit for the cross-subject classification of depression. It provides new ideas for depression classification in clinics.
ArticleNumber 107360
Author Xiong, Peng
Yang, Jianli
Fu, Zhiyu
Liu, Xiuling
Li, Bing
Zhang, Zhen
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Keywords Multiparadigm
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Feature fusion
Cross-subject
EEG
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Snippet •A multiparadigm feature fusion method was proposed to distinguish depression.•The significance of EEG feature from eyes open and closed in the resting state...
The aim of this study is to solve the non-stationarity and complexity characteristics and huge individual differences in the electroencephalogram (EEG) signals...
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SubjectTerms Brain
Cross-subject
Depression
Depression - diagnosis
EEG
Electroencephalography - methods
Eye
Feature fusion
Multiparadigm
Support Vector Machine
Title Cross-subject classification of depression by using multiparadigm EEG feature fusion
URI https://www.clinicalkey.com/#!/content/1-s2.0-S0169260723000275
https://dx.doi.org/10.1016/j.cmpb.2023.107360
https://www.ncbi.nlm.nih.gov/pubmed/36944276
https://www.proquest.com/docview/2789711808
Volume 233
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