Classification of schizophrenia and normal controls using 3D convolutional neural network and outcome visualization

• Published in: Schizophrenia research Vol. 212; pp. 186 - 195
• Main Authors: Oh, Kanghan, Kim, Woosung, Shen, Guangfan, Piao, Yanhong, Kang, Nam-In, Oh, Il-Seok, Chung, Young Chul
• Format: Journal Article
• Language: English
• Published: Netherlands Elsevier B.V 01.10.2019
• Subjects: Classification accuracy; Convolutional neural network; Saliency map; Schizophrenia; Support vector machine; Schizophrenia; Support vector machine; Saliency map; Classification accuracy; Convolutional neural network
• ISSN: 0920-9964; 1573-2509
• DOI: 10.1016/j.schres.2019.07.034

The recent deep learning-based studies on the classification of schizophrenia (SCZ) using MRI data rely on manual extraction of feature vector, which destroys the 3D structure of MRI data. In order to both identify SCZ and find relevant biomarkers, preserving the 3D structure in classification pipeline is critical. The present study investigated whether the proposed 3D convolutional neural network (CNN) model produces higher accuracy compared to the support vector machine (SVM) and other 3D-CNN models in distinguishing individuals with SCZ spectrum disorders (SSDs) from healthy controls. We sought to construct saliency map using class saliency visualization (CSV) method. Task-based fMRI data were obtained from 103 patients with SSDs and 41 normal controls. To preserve spatial locality, we used 3D activation map as input for the 3D convolutional autoencoder (3D-CAE)-based CNN model. Data on 62 patients with SSDs were used for unsupervised pretraining with 3D-CAE. Data on the remaining 41 patients and 41 normal controls were processed for training and testing with CNN. The performance of our model was analyzed and compared with SVM and other 3D-CNN models. The learned CNN model was visualized using CSV method. Using task-based fMRI data, our model achieved 84.15%∼84.43% classification accuracies, outperforming SVM and other 3D-CNN models. The inferior and middle temporal lobes were identified as key regions for classification. Our findings suggest that the proposed 3D-CAE-based CNN can classify patients with SSDs and controls with higher accuracy compared to other models. Visualization of salient regions provides important clinical information.