Abstract
Support vector machine (SVM)‐based multivariate pattern analysis (MVPA) has delivered promising performance in decoding specific task states based on functional magnetic resonance imaging (fMRI) of the human brain. Conventionally, the SVM‐MVPA requires careful feature selection/extraction according to expert knowledge. In this study, we propose a deep neural network (DNN) for directly decoding multiple brain task states from fMRI signals of the brain without any burden for feature handcrafts. We trained and tested the DNN classifier using task fMRI data from the Human Connectome Project's S1200 dataset (N = 1,034). In tests to verify its performance, the proposed classification method identified seven tasks with an average accuracy of 93.7%. We also showed the general applicability of the DNN for transfer learning to small datasets (N = 43), a situation encountered in typical neuroscience research. The proposed method achieved an average accuracy of 89.0 and 94.7% on a working memory task and a motor classification task, respectively, higher than the accuracy of 69.2 and 68.6% obtained by the SVM‐MVPA. A network visualization analysis showed that the DNN automatically detected features from areas of the brain related to each task. Without incurring the burden of handcrafting the features, the proposed deep decoding method can classify brain task states highly accurately, and is a powerful tool for fMRI researchers.
Highlights
Researchers have been attempting to decode and identify functions of the human brain based on functional brain imaging data (Dehaene et al, 1998; Haynes & Rees, 2006; Jang, Plis, Calhoun, & Lee, 2017; Poldrack, Halchenko, & Hanson, 2009; Rubin et al, 2017)
Support vector machine (SVM) based multivariate pattern analysis (MVPA) has delivered promising performance in decoding specific task states based on functional magnetic resonance imaging of the human brain
The proposed method achieved an average accuracy of 89.0% and 94.7% on a working memory task and a motor classification task, respectively, higher than the accuracy of 69.2% and 68.6% obtained by the SVMMVPA
Summary
Researchers have been attempting to decode and identify functions of the human brain based on functional brain imaging data (Dehaene et al, 1998; Haynes & Rees, 2006; Jang, Plis, Calhoun, & Lee, 2017; Poldrack, Halchenko, & Hanson, 2009; Rubin et al, 2017). The most popular among these braindecoding methods is the support vector machine (SVM) based multi-voxel pattern analysis (MVPA), a supervised technology that incorporates information from multiple variables at the same time Kim & Oertzen, 2018; Nikolaus Kriegeskorte & Bandettini, 2007; N. Kriegeskorte, Goebel, & Bandettini, 2006; Norman, Polyn, Detre, & Haxby, 2006). We explore in this study an open-ended brain decoder that uses whole-brain neuroimaging data on humans
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