High-resolution in vivo MR-STAT using a matrix-free and parallelized reconstruction algorithm
Files
Publication date
2020-04-01
Editors
Advisors
Supervisors
Document Type
Article
Metadata
Show full item recordCollections
License
Abstract
MR-STAT is a recently proposed framework that allows the reconstruction of multiple quantitative parameter maps from a single short scan by performing spatial localisation and parameter estimation on the time-domain data simultaneously, without relying on the fast Fourier transform (FFT). To do this at high resolution, specialized algorithms are required to solve the underlying large-scale nonlinear optimisation problem. We propose a matrix-free and parallelized inexact Gauss–Newton based reconstruction algorithm for this purpose. The proposed algorithm is implemented on a high-performance computing cluster and is demonstrated to be able to generate high-resolution (1 mm (Formula presented.) 1 mm in-plane resolution) quantitative parameter maps in simulation, phantom, and in vivo brain experiments. Reconstructed (Formula presented.) and (Formula presented.) values for the gel phantoms are in agreement with results from gold standard measurements and, for the in vivo experiments, the quantitative values show good agreement with literature values. In all experiments, short pulse sequences with robust Cartesian sampling are used, for which MR fingerprinting reconstructions are shown to fail.
Keywords
large-scale nonlinear optimization, MR fingerprinting, MR-STAT, parallel computing, quantitative MRI, Molecular Medicine, Radiology Nuclear Medicine and imaging, Spectroscopy, Research Support, Non-U.S. Gov't, Journal Article
Citation
van der Heide, O, Sbrizzi, A, Luijten, P R & van den Berg, C A T 2020, 'High-resolution in vivo MR-STAT using a matrix-free and parallelized reconstruction algorithm', NMR in Biomedicine, vol. 33, no. 4, e4251. https://doi.org/10.1002/nbm.4251