Rigid Motion Estimation using Accelerated Iterative Coordinate Descent (REACT) for MR Imaging

TL;DR

This paper introduces REACT, an efficient iterative method for estimating 3D rigid motion in MRI, improving image quality by optimizing motion parameters through coordinate descent and local convexity assumptions.

Contribution

The paper presents REACT, a novel accelerated coordinate descent approach for 3D rigid motion estimation in MRI, avoiding exhaustive searches and demonstrating improved correction over existing methods.

Findings

REACT outperformed traditional translational methods in coronary artery sharpness.

Numerical simulations confirmed local convexity of subproblems near solutions.

REACT achieved higher u-IEPA than nonrigid correction in vivo.

Abstract

Purpose: To develop a computationally viable autofocus method for estimating 3D rigid motion in MR imaging. Theory and Methods: The proposed method, REACT, assumes a piecewise-constant motion trajectory and estimates the rigid motion parameters of individual temporal segments by optimizing an image-quality metric. Coordinate descent is adopted to decompose the high-dimensional optimization problem into a series of subproblems, each updating the motion parameters of a single temporal segment. The cost function of each subproblem is assumed to be approximately locally convex under suitable acquisition conditions. Each subproblem is then solved using a derivative-free solver, thereby avoiding an exhaustive grid search. Numerical simulations were conducted to investigate the local convexity assumption. REACT was evaluated for respiratory motion correction on in vivo free-breathing coronary MR angiography datasets acquired using a 3D cones trajectory with image-based navigators (iNAVs). An autofocus nonrigid motion correction method was also evaluated for comparison. Coronary artery sharpness was quantified using unbounded image edge profile acutance (u-IEPA). Results: In numerical simulations, the objective surfaces of the subproblems were approximately locally convex when the current motion estimate was close to the desired solution. In the in vivo study, REACT yielded higher u-IEPA than the conventional iNAV-based translational motion-estimation method for both the left anterior descending artery (LAD) and right coronary artery. REACT also yielded higher u-IEPA for the LAD than the autofocus nonrigid motion correction method. Conclusion: This study demonstrates the feasibility of coordinate descent for autofocus motion correction in MR imaging.