Generalisation of continuous time random walk to anomalous diffusion MRI models with an age-related evaluation of human corpus callosum

TL;DR

This study unifies various anomalous diffusion MRI models under a continuous time random walk framework, linking them to diffusional kurtosis imaging, and demonstrates age-related microstructural changes in the human corpus callosum.

Contribution

It introduces a unified anomalous diffusion modeling approach and a novel link to diffusional kurtosis imaging, enabling better microstructural analysis in aging human brain tissue.

Findings

Anomalous diffusion parameters {} and ta} positively correlate with age.

Unified modeling framework allows consistent parameter comparison.

Enhanced tissue contrast in kurtosis maps based on sub-diffusion model.

Abstract

Diffusion MRI measures of the human brain provide key insight into microstructural variations across individuals and into the impact of central nervous system diseases and disorders. One approach to extract information from diffusion signals has been to use biologically relevant analytical models to link millimetre scale diffusion MRI measures with microscale influences. The other approach has been to represent diffusion as an anomalous transport process and infer microstructural information from the different anomalous diffusion equation parameters. In this study, we investigated how parameters of various anomalous diffusion models vary with age in the human brain white matter, particularly focusing on the corpus callosum. We first unified several established anomalous diffusion models (the super-diffusion, sub-diffusion, quasi-diffusion and fractional Bloch-Torrey models) under the continuous time random walk modelling framework. This unification allows a consistent parameter fitting strategy to be applied from which meaningful model parameter comparisons can be made. We then provided a novel way to derive the diffusional kurtosis imaging (DKI) model, which is shown to be a degree two approximation of the sub-diffusion model. This link between the DKI and sub-diffusion models led to a new robust technique for generating maps of kurtosis and diffusivity using the sub-diffusion parameters \b{eta}_SUB and D_SUB. Superior tissue contrast is achieved in kurtosis maps based on the sub-diffusion model. 7T diffusion weighted MRI data for 65 healthy participants in the age range 19-78 years was used in this study. Results revealed that anomalous diffusion model parameters {\alpha} and \b{eta} have shown consistent positive correlation with age in the corpus callosum, indicating {\alpha} and \b{eta} are sensitive to tissue microstructural changes in aging.