Abstract
Acceleration methods in fMRI aim to reconstruct high fidelity images from under-sampled k-space, allowing fMRI datasets to achieve higher temporal resolution, reduced physiological noise aliasing, and increased statistical degrees of freedom. While low levels of acceleration are typically part of standard fMRI protocols through parallel imaging, there exists the potential for approaches that allow much greater acceleration. One such existing approach is k-t FASTER, which exploits the inherent low-rank nature of fMRI. In this paper, we present a reformulated version of k-t FASTER which includes additional L2 constraints within a low-rank framework.We evaluated the effect of three different constraints against existing low-rank approaches to fMRI reconstruction: Tikhonov constraints, low-resolution priors, and temporal subspace smoothness. The different approaches are separately tested for robustness to under-sampling and thermal noise levels, in both retrospectively and prospectively-undersampled finger-tapping task fMRI data. Reconstruction quality is evaluated by accurate reconstruction of low-rank subspaces and activation maps.The use of L2 constraints was found to achieve consistently improved results, producing high fidelity reconstructions of statistical parameter maps at higher acceleration factors and lower SNR values than existing methods, but at a cost of longer computation time. In particular, the Tikhonov constraint proved very robust across all tested datasets, and the temporal subspace smoothness constraint provided the best reconstruction scores in the prospectively-undersampled dataset. These results demonstrate that regularized low-rank reconstruction of fMRI data can recover functional information at high acceleration factors without the use of any model-based spatial constraints.
Highlights
FMRI is a non-invasive, whole-brain functional imaging technique that suffers from a trade-off between temporal and spatial resolution
Optimal values of λX, λT, and λ∇ are evaluated for each dataset, method, and acceleration factor, and the optimized reconstructions are evaluated against the reconstructions using the k-t FASTER and kt PSF methods
The Low-Resolution Priors (LRP) constraints are defined by a peak in spatial Canonical Correlation Score (CCS) and a broad plateau in temporal CCS
Summary
FMRI is a non-invasive, whole-brain functional imaging technique that suffers from a trade-off between temporal and spatial resolution. Acceleration aims to increase the temporal resolution without loss of spatial resolution through higher sampling efficiency in conjunction with advanced image reconstruction that leverages additional information and/or constraints. Parallel imaging methods rely on the spatial variation of sensitivity profiles of multi-channel receiver coils, which provide additional spatial information in image reconstruction. This can occur in the image domain (e.g. SENSE Pruessmann et al, 1999) or in the sampling domain (e.g. GRAPPA Griswold et al, 2002). Simultaneous multi-slice imaging (Setsompop et al, 2012; Barth et al, 2016) extends these in-plane techniques to accelerate across slices without significant reduction factor SNR penalties when compared to 2D methods, since the under-sampling can be offset by acquiring more slices (even accounting for the loss in SNR due to Ernst angle and shorter TR), increasing the achievable temporal resolution. Parallel imaging is conventionally a timepoint-bytimepoint approach that does not leverage any temporal information during reconstruction
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