Towards non-parametric fiber-specific T1 relaxometry in the human brain

Abstract

Purpose: To estimate fiber-specific T1 values, i.e. proxies for myelin content, in heterogeneous brain tissue. Methods: A diffusion-T1 correlation experiment was carried out on an in vivo human brain using tensor-valued diffusion encoding and multiple repetition times. The acquired data was inverted using a Monte-Carlo inversion algorithm that retrieves non-parametric distributions P(D,R1) of diffusion tensors and longitudinal relaxation rates R1 = 1/T1. Orientation distribution functions (ODFs) of the highly anisotropic components of P(D,R1) were defined to visualize orientation-specific diffusion-relaxation properties. Finally, Monte-Carlo density-peak clustering (MC-DPC) was performed to quantify fiber-specific features and investigate microstructural differences between white-matter fiber bundles. Results: Parameter maps corresponding to P(D,R1)'s statistical descriptors were obtained, exhibiting the expected R1 contrast between brain-tissue types. Our ODFs recovered local orientations consistent with the known anatomy and indicated possible differences in T1 relaxation between major fiber bundles. These differences, confirmed by MC-DPC, were in qualitative agreement with previous model-based works but seem biased by the limitations of our current experimental setup. Conclusions: Our Monte-Carlo framework enables the non-parametric estimation of fiber-specific diffusion-T1 features, thereby showing potential for characterizing developmental or pathological changes in T1 within a given fiber bundle, and for investigating inter-bundle T1 differences.