Robust frequency-dependent diffusion kurtosis computation using an   efficient direction scheme, axisymmetric modelling, and spatial   regularization

J. Hamilton (1; 2); K. Xu (3; 4); A. Brown (3; 4); C. A.; Baron (1; 2) ((1) Centre for Functional; Metabolic Mapping (CFMM),; Robarts Research Institute; University of Western Ontario; (2) Department of; Medical Biophysics; Schulich School of Medicine; Dentistry; University of; Western Ontario; (3) Translational Neuroscience Group; Robarts Research; Institute; Schulich School of Medicine; Dentistry; University of Western; Ontario; (4) Department of Anatomy; Cell Biology; University of Western; Ontario)

arXiv:2309.02319·physics.med-ph·January 9, 2024

Robust frequency-dependent diffusion kurtosis computation using an efficient direction scheme, axisymmetric modelling, and spatial regularization

J. Hamilton (1, 2), K. Xu (3, 4), A. Brown (3, 4), C. A., Baron (1, 2) ((1) Centre for Functional, Metabolic Mapping (CFMM),, Robarts Research Institute, University of Western Ontario, (2) Department of, Medical Biophysics, Schulich School of Medicine, Dentistry, University of

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TL;DR

This paper introduces a novel robust DKI fitting algorithm that combines axisymmetric modeling, spatial regularization, and an efficient 10-direction scheme to improve frequency-dependent diffusion kurtosis imaging, enabling better tissue microstructure insights.

Contribution

The paper proposes a new DKI fitting method that integrates axisymmetric modeling, spatial regularization, and an efficient encoding scheme for enhanced robustness and map quality.

Findings

01

Axisymmetric modeling preserves contrast and reduces noise in DKI maps.

02

Efficient 10-direction scheme with the proposed fitting yields superior map quality.

03

Spatial regularization outperforms Gaussian filtering in preserving spatial features.

Abstract

Frequency-dependent diffusion MRI (dMRI) using oscillating gradient encoding and diffusion kurtosis imaging (DKI) techniques have been shown to provide additional insight into tissue microstructure compared to conventional dMRI. However, a technical challenge when combining these techniques is that the generation of the large b-values required for DKI is difficult when using oscillating gradient diffusion encoding. While efficient encoding schemes can enable larger b-values by maximizing multiple gradient channels simultaneously, they do not have sufficient directions to enable fitting of the full kurtosis tensor. Accordingly, we investigate a DKI fitting algorithm that combines axisymmetric DKI fitting, a prior that enforces the same axis of symmetry for all oscillating gradient frequencies, and spatial regularization, which together enable robust DKI fitting for a 10-direction scheme…

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Taxonomy

TopicsAdvanced Neuroimaging Techniques and Applications · MRI in cancer diagnosis · Advanced MRI Techniques and Applications