arXiv:2508.19478v1 Announce Type: new
Abstract: Diffusion MRI (dMRI) biophysical models hold promise for characterizing gray matter tissue microstructure. Yet, the reliability of estimated parameters remains largely under-studied, especially in models that incorporate water exchange. In this study, we investigate the accuracy, precision, and presence of degeneracy of two recently proposed gray matter models, NEXI and SANDIX, using two acquisition protocols from the literature, on both simulated and in vivo data. We employ $mu$GUIDE, a Bayesian inference framework based on deep learning, to quantify model uncertainty and detect parameter degeneracies, enabling a more interpretable assessment of fitted parameters. Our results show that while some microstructural parameters, such as extra-cellular diffusivity and neurite signal fraction, are robustly estimated, others, such as exchange time and soma radius, are often associated with high uncertainty and estimation bias, especially under realistic noise conditions and reduced acquisition protocols. Comparisons with non-linear least squares fitting underscore the added value of uncertainty-aware methods, which allow for the identification and filtering of unreliable estimates. These findings emphasize the need to report uncertainty and consider model degeneracies when interpreting model-based estimates. Our study advocates for the integration of probabilistic fitting approaches in neuroscience imaging pipelines to improve reproducibility and biological interpretability.