Hierarchical Bayesian myocardial perfusion quantification
Cian M. Scannell, Amedeo Chiribiri, Adriana D.M. Villa, Marcel, Breeuwer, Jack Lee

TL;DR
This paper demonstrates that hierarchical Bayesian inference significantly improves the reliability of myocardial perfusion quantification from MRI data, enabling fully automated, voxel-wise assessment with better accuracy than traditional least-squares methods.
Contribution
It introduces a hierarchical Bayesian approach for fitting tracer-kinetic models to perfusion MRI data, enhancing robustness and reliability over conventional methods.
Findings
Bayesian inference reduces normalized mean square error from 0.32 to 0.13.
Quantitative MBF maps from Bayesian inference match visual assessment in all slices.
The method enables fully automated, voxel-wise myocardial perfusion assessment.
Abstract
Purpose: Tracer-kinetic models can be used for the quantitative assessment of contrast-enhanced MRI data. However, the model-fitting can produce unreliable results due to the limited data acquired and the high noise levels. Such problems are especially prevalent in myocardial perfusion MRI leading to the compromise of constrained numerical deconvolutions and segmental signal averaging being commonly used as alternatives to the more complex tracer-kinetic models. Methods: In this work, the use of hierarchical Bayesian inference for the parameter estimation is explored. It is shown that with Bayesian inference it is possible to reliably fit the two-compartment exchange model to perfusion data. The use of prior knowledge on the ranges of kinetic parameters and the fact that neighbouring voxels are likely to have similar kinetic properties combined with a Markov chain Monte Carlo based…
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