Abstract

Resting-state functional magnetic resonance imaging (rs-fMRI) data are 4-dimensional volumes (3-space + 1-time) that have been posited to reflect the underlying mechanisms of information exchange between brain regions, thus making it an attractive modality to develop diagnostic biomarkers of brain dysfunction. The enormous success of deep learning in computer vision has sparked recent interest in applying deep learning in neuroimaging. But the dimensionality of rs-fMRI data is too high (~20 M), making it difficult to meaningfully process the data in its raw form for deep learning experiments. It is currently not clear how the data should be engineered to optimally extract the time information, and whether combining different representations of time could provide better results. In this paper, we explored various transformations that retain the full spatial resolution by summarizing the temporal dimension of the rs-fMRI data, therefore making it possible to train a full three-dimensional convolutional neural network (3D-CNN) even on a moderately sized [~2,000 from Autism Brain Imaging Data Exchange (ABIDE)-I and II] data set. These transformations summarize the activity in each voxel of the rs-fMRI or that of the voxel and its neighbors to a single number. For each brain volume, we calculated regional homogeneity, the amplitude of low-frequency fluctuations, the fractional amplitude of low-frequency fluctuations, degree centrality, eigenvector centrality, local functional connectivity density, entropy, voxel-mirrored homotopic connectivity, and auto-correlation lag. We trained the 3D-CNN on a publically available autism dataset to classify the rs-fMRI images as being from individuals with autism spectrum disorder (ASD) or from healthy controls (CON) at an individual level. We attained results competitive on this task for a combined ABIDE-I and II datasets of ~66%. When all summary measures were combined the result was still only as good as that of the best single measure which was regional homogeneity (ReHo). In addition, we also applied the support vector machine (SVM) algorithm on the same dataset and achieved comparable results, suggesting that 3D-CNNs could not learn additional information from these temporal transformations that were more useful to differentiate ASD from CON.

Highlights

  • Neuroimaging holds the promise of objective diagnosis and prognosis in psychiatry

  • In our experiments we pursued the goal of classifying the rsfMRI brain images of autism spectrum disorder (ASD) subjects from healthy controls by means of their temporal summary measures

  • We have proposed a machine learning solution for using Resting-state functional magnetic resonance imaging (rs-fMRI) that does not compromise its spatial properties

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Summary

Introduction

Neuroimaging holds the promise of objective diagnosis and prognosis in psychiatry. But unlike neurological disorders, psychiatric disorders do not show obvious structural brain abnormalities. Researchers have long posited that brain abnormalities of psychiatric patients are reflected in functional scans such as resting-state functional magnetic resonance imaging (rs-fMRI) [1]. These scans involve mapping the blood oxygenation level (a proxy for brain activity) throughout the brain every 1 or 2 s—resulting in a 4-D data product, 3-D of the brain, and 1-D in time. At a scanning resolution of 4 mm and 300 temporal sampling points, this results in a 20 million dimensional feature vector Hidden somewhere in this high-dimensional spatio-temporal signal are the biomarkers that could distinguish between healthy and psychiatric subjects. Mining these rs-fMRI images for such patterns is the challenge we are facing

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