Discovery and visualization of structural biomarkers from MRI using transport-based morphometry
This addresses the challenge of identifying complex, diffuse brain biomarkers for diseases like aging-related conditions, though it appears incremental as a novel image transformation method building on existing morphometry approaches.
The researchers tackled the problem of detecting subtle brain tissue changes in MRI that conventional feature-based methods miss, developing transport-based morphometry (TBM) which losslessly transforms images to a more separable domain and successfully discovered characteristic aging changes and potential fitness-mediated brain health mechanisms in older adults.
Disease in the brain is often associated with subtle, spatially diffuse, or complex tissue changes that may lie beneath the level of gross visual inspection, even on magnetic resonance imaging (MRI). Unfortunately, current computer-assisted approaches that examine pre-specified features, whether anatomically-defined (i.e. thalamic volume, cortical thickness) or based on pixelwise comparison (i.e. deformation-based methods), are prone to missing a vast array of physical changes that are not well-encapsulated by these metrics. In this paper, we have developed a technique for automated pattern analysis that can fully determine the relationship between brain structure and observable phenotype without requiring any a priori features. Our technique, called transport-based morphometry (TBM), is an image transformation that maps brain images losslessly to a domain where they become much more separable. The new approach is validated on structural brain images of healthy older adult subjects where even linear models for discrimination, regression, and blind source separation enable TBM to independently discover the characteristic changes of aging and highlight potential mechanisms by which aerobic fitness may mediate brain health later in life. TBM is a generative approach that can provide visualization of physically meaningful shifts in tissue distribution through inverse transformation. The proposed framework is a powerful technique that can potentially elucidate genotype-structural-behavioral associations in myriad diseases.