Fast Nonconvex $T_2^*$ Mapping Using ADMM

TL;DR

This paper introduces a fast, nonconvex $T_2^*$ mapping method using ADMM that effectively reconstructs images from undersampled data, significantly reducing acquisition time and improving image quality in MRI.

Contribution

It proposes a novel joint-recovery framework with sparse priors on multiple echoes, outperforming previous methods especially at low sampling rates.

Findings

Outperforms state-of-the-art methods in low-sampling regimes

Enforces additional sparse priors on $T_2^*$-weighted images

Demonstrates effective convergence and robustness on in vivo data

Abstract

Magnetic resonance (MR)-$T_2^*$ mapping is widely used to study hemorrhage, calcification and iron deposition in various clinical applications, it provides a direct and precise mapping of desired contrast in the tissue. However, the long acquisition time required by conventional 3D high-resolution $T_2^*$ mapping method causes discomfort to patients and introduces motion artifacts to reconstructed images, which limits its wider applicability. In this paper we address this issue by performing $T_2^*$ mapping from undersampled data using compressive sensing (CS). We formulate the reconstruction as a nonconvex problem that can be decomposed into two subproblems. They can be solved either separately via the standard approach or jointly via the alternating direction method of multipliers (ADMM). Compared to previous CS-based approaches that only apply sparse regularization on the spin density $\boldsymbol X_0$ and the relaxation rate $\boldsymbol R_2^*$, our formulation enforces additional sparse priors on the $T_2^*$-weighted images at multiple echoes to improve the reconstruction performance. We performed convergence analysis of the proposed algorithm, evaluated its performance on in vivo data, and studied the effects of different sampling schemes. Experimental results showed that the proposed joint-recovery approach generally outperforms the state-of-the-art method, especially in the low-sampling rate regime, making it a preferred choice to perform fast 3D $T_2^*$ mapping in practice. The framework adopted in this work can be easily extended to other problems arising from MR or other imaging modalities with non-linearly coupled variables.