In this work a generic model-based reconstruction for the quantification of relaxation parameters is developed. In contrast to previous approaches that rely on simplified models derived from the Bloch equations, this work includes the Bloch equations directly into the reconstruction. Therefore, non-linear calibrationless parallel imaging is combined with a generic Runge-Kutta 5(4) based forward operator to simulate spin dynamics described by arbitrary sequences. Gradients are determined by using a sensitivity analysis and solving the resulting ordinary differential equations parallel to the signal simulation. Based on this formulation an IRGNM-FISTA algorithm is used to estimate quantitative maps for T1, T2, M0, and the coil profiles cN from fully-sampled multi-inversion and golden-angle single-shot inversion-recovery radial bSSFP measurement with a custom-built T1-T2 phantom.
@article{arxiv.1905.03188,
title = {Model-Based Reconstruction for Quantitative MRI using the Bloch Equations},
author = {Nick Scholand},
journal= {arXiv preprint arXiv:1905.03188},
year = {2019}
}