English

Learning compact q-space representations for multi-shell diffusion-weighted MRI

Medical Physics 2019-05-09 v2

Abstract

Diffusion-weighted MRI measures the direction and scale of the local diffusion process in every voxel through its spectrum in q-space, typically acquired in one or more shells. Recent developments in microstructure imaging and multi-tissue decomposition have sparked renewed attention in the radial b-value dependence of the signal. Applications in motion correction and outlier rejection therefore require a compact linear signal representation that extends over the radial as well as angular domain. Here, we introduce SHARD, a data-driven representation of the q-space signal based on spherical harmonics and a radial decomposition into orthonormal components. This representation provides a complete, orthogonal signal basis, tailored to the spherical geometry of q-space and calibrated to the data at hand. We demonstrate that the rank-reduced decomposition outperforms model-based alternatives in human brain data, whilst faithfully capturing the micro- and meso-structural information in the signal. Furthermore, we validate the potential of joint radial-spherical as compared to single-shell representations. As such, SHARD is optimally suited for applications that require low-rank signal predictions, such as motion correction and outlier rejection. Finally, we illustrate its application for the latter using outlier robust regression.

Keywords

Cite

@article{arxiv.1806.06456,
  title  = {Learning compact q-space representations for multi-shell diffusion-weighted MRI},
  author = {Daan Christiaens and Lucilio Cordero-Grande and Jana Hutter and Anthony N. Price and Maria Deprez and Joseph V. Hajnal and J-Donald Tournier},
  journal= {arXiv preprint arXiv:1806.06456},
  year   = {2019}
}

Comments

Accepted author manuscript, including supplementary materials

R2 v1 2026-06-23T02:32:34.757Z