Automated Depression Detection Using Deep Representation and Sequence Learning with EEG Signals

Overview

Journal J Med Syst

Specialty Medical Informatics

Date 2019 May 30

PMID 31139932

Citations 44

Authors

Betul Ay

Ozal Yildirim

Muhammed Talo

Ulas Baran Baloglu

Galip Aydin

Subha D Puthankattil

U Rajendra Acharya

Affiliations

Soon will be listed here.

Abstract

Depression affects large number of people across the world today and it is considered as the global problem. It is a mood disorder which can be detected using electroencephalogram (EEG) signals. The manual detection of depression by analyzing the EEG signals requires lot of experience, tedious and time consuming. Hence, a fully automated depression diagnosis system developed using EEG signals will help the clinicians. Therefore, we propose a deep hybrid model developed using convolutional neural network (CNN) and long-short term memory (LSTM) architectures to detect depression using EEG signals. In the deep model, temporal properties of the signals are learned with CNN layers and the sequence learning process is provided through the LSTM layers. In this work, we have used EEG signals obtained from left and right hemispheres of the brain. Our work has provided 99.12% and 97.66% classification accuracies for the right and left hemisphere EEG signals respectively. Hence, we can conclude that the developed CNN-LSTM model is accurate and fast in detecting the depression using EEG signals. It can be employed in psychiatry wards of the hospitals to detect the depression using EEG signals accurately and thus aid the psychiatrists.

Citing Articles

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