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Resolving bundle-specific intra-axonal T2 values within a voxel using diffusion-relaxation tract-based estimation

Barakovic, Muhamed, Tax, Chantal M.W., Rudrapatna, Umesh, Chamberland, Maxime, Rafael-Patino, Jonathan, Granziera, Cristina, Thiran, Jean-Philippe, Daducci, Alessandro, Canales-Rodríguez, Erick J. and Jones, Derek K. 2021. Resolving bundle-specific intra-axonal T2 values within a voxel using diffusion-relaxation tract-based estimation. NeuroImage 227 , 117617. 10.1016/j.neuroimage.2020.117617

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Abstract

At the typical spatial resolution of MRI in the human brain, approximately 60–90% of voxels contain multiple fiber populations. Quantifying microstructural properties of distinct fiber populations within a voxel is therefore challenging but necessary. While progress has been made for diffusion and T1-relaxation properties, how to resolve intra-voxel T2 heterogeneity remains an open question. Here a novel framework, named COMMIT-T2, is proposed that uses tractography-based spatial regularization with diffusion-relaxometry data to estimate multiple intra-axonal T2 values within a voxel. Unlike previously-proposed voxel-based T2 estimation methods, which (when applied in white matter) implicitly assume just one fiber bundle in the voxel or the same T2 for all bundles in the voxel, COMMIT-T2 can recover specific T2 values for each unique fiber population passing through the voxel. In this approach, the number of recovered unique T2 values is not determined by a number of model parameters set a priori, but rather by the number of tractography-reconstructed streamlines passing through the voxel. Proof-of-concept is provided in silico and in vivo, including a demonstration that distinct tract-specific T2 profiles can be recovered even in the three-way crossing of the corpus callosum, arcuate fasciculus, and corticospinal tract. We demonstrate the favourable performance of COMMIT-T2 compared to that of voxelwise approaches for mapping intra-axonal T2 exploiting diffusion, including a direction-averaged method and AMICO-T2, a new extension to the previously-proposed Accelerated Microstructure Imaging via Convex Optimization (AMICO) framework.

Item Type: Article
Date Type: Publication
Status: Published
Schools: Physics and Astronomy
Psychology
Cardiff University Brain Research Imaging Centre (CUBRIC)
Publisher: Elsevier
ISSN: 1053-8119
Date of First Compliant Deposit: 7 January 2021
Date of Acceptance: 29 November 2020
Last Modified: 11 Jan 2021 10:15
URI: http://orca.cardiff.ac.uk/id/eprint/137443

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