Journal
BRAIN CONNECTIVITY
Volume 13, Issue 2, Pages 80-88Publisher
MARY ANN LIEBERT, INC
DOI: 10.1089/brain.2021.0186
Keywords
data augmentation; deep learning; fMRI; machine learning; simulation
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This study proposes a new data augmentation method called BLENDS, which generates new nonlinear warp fields for synthesizing augmented images from existing 4D fMRI data. The results show that using BLENDS significantly improves the predictive performance of deep learning models in neuroimaging.
Introduction: Data augmentation improves the accuracy of deep learning models when training data are scarce by synthesizing additional samples. This work addresses the lack of validated augmentation methods specific for synthesizing anatomically realistic four-dimensional (4D) (three-dimensional [3D] + time) images for neuroimaging, such as functional magnetic resonance imaging (fMRI), by proposing a new augmentation method.Methods: The proposed method, Brain Library Enrichment through Nonlinear Deformation Synthesis (BLENDS), generates new nonlinear warp fields by combining intersubject coregistration maps, computed using symmetric normalization, through spatial blending. These new warp fields can be applied to existing 4D fMRI to create new augmented images. BLENDS was tested on two neuroimaging problems using de-identified data sets: (1) the prediction of antidepressant response from task-based fMRI (original data set n = 163), and (2) the prediction of Parkinson's disease (PD) symptom trajectory from baseline resting-state fMRI regional homogeneity (original data set n = 43).Results: BLENDS readily generates hundreds of new fMRI from existing images, with unique anatomical variations from the source images, that significantly improve prediction performance. For antidepressant response prediction, augmenting each original image once (2 x the original training data) significantly increased prediction R-2 from 0.055 to 0.098 (p < 1e-6), whereas at 10 x augmentation R-2 increased to 0.103. For the prediction of PD trajectory, 10 x augmentation R-2 increased from -0.044 to 0.472 (p < 1e-6).Conclusions: Augmentation of fMRI through nonlinear transformations with BLENDS significantly improved the performance of deep learning models on clinically relevant predictive tasks. This method will help neuroimaging researchers overcome data set size limitations and achieve more accurate predictive models.
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