Abstract
Brain signals can be measured using multiple imaging modalities, such as magnetic resonance imaging (MRI)-based techniques. Different modalities convey distinct yet complementary information; thus, their joint analyses can provide valuable insight into how the brain functions in both healthy and diseased conditions. Data-driven approaches have proven most useful for multimodal fusion as they minimize assumptions imposed on the data, and there are a number of methods that have been developed to uncover relationships across modalities. However, none of these methods, to the best of our knowledge, can discover “one-to-many associations”, meaning one component from one modality is linked with more than one component from another modality. However, such “one-to-many associations” are likely to exist, since the same brain region can be involved in multiple neurological processes. Additionally, most existing data fusion methods require the signal subspace order to be identical for all modalities—a severe restriction for real-world data of different modalities. Here, we propose a new fusion technique—the consecutive independence and correlation transform (C-ICT) model—which successively performs independent component analysis and independent vector analysis and is uniquely flexible in terms of the number of datasets, signal subspace order, and the opportunity to find “one-to-many associations”. We apply C-ICT to fuse diffusion MRI, structural MRI, and functional MRI datasets collected from healthy controls (HCs) and patients with schizophrenia (SZs). We identify six interpretable triplets of components, each of which consists of three associated components from the three modalities. Besides, components from these triplets that show significant group differences between the HCs and SZs are identified, which could be seen as putative biomarkers in schizophrenia.
Highlights
IntroductionFMRI detects neuronal activations by measuring the blood oxygenation level-dependent response in the brain
We found that the structure–structure associations were generally stronger than the structure–function associations
By using a two-sample t-test, we find that the ATR–ACR and corticospinal tract and superior longitudinal fasciculus (CST–SLF) from diffusion MRI (dMRI) have stronger activation in healthy controls (HCs) than in SZs, implying the white matter (WM) in these regions is less integrated in
Summary
FMRI detects neuronal activations by measuring the blood oxygenation level-dependent response in the brain Each of these three imaging techniques reveals different yet complementary information about brain structures or activities. ICA is a statistical method that seeks to recover latent sources from a set of observed data with the assumption that the latent sources are statistically independent of one another [50]. Since it places few assumptions on data, ICA has been widely used in brain imaging studies [51,52,53,54].
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