Abstract
Compressed Sensing (CS) and parallel imaging are two promising techniques that accelerate the MRI acquisition process. Combining these two techniques is of great interest due to the complementary information used in each. In this study, we proposed a novel reconstruction framework that effectively combined compressed sensing and nonlinear parallel imaging technique for dynamic cardiac imaging. Specifically, the proposed method decouples the reconstruction process into two sequential steps: In the first step, a series of aliased dynamic images were reconstructed from the highly undersampled k-space data using compressed sensing; In the second step, nonlinear parallel imaging technique, i.e. nonlinear GRAPPA, was utilized to reconstruct the original dynamic images from the reconstructed k-space data obtained from the first step. In addition, we also proposed a tailored k-space down-sampling scheme that satisfies both the incoherent undersampling requirement for CS and the structured undersampling requirement for nonlinear parallel imaging. The proposed method was validated using four in vivo experiments of dynamic cardiac cine MRI with retrospective undersampling. Experimental results showed that the proposed method is superior at reducing aliasing artifacts and preserving the spatial details and temporal variations, compared with the competing k-t FOCUSS and k-t FOCUSS with sensitivity encoding methods, with the same numbers of measurements.
Highlights
Dynamic Magnetic resonance imaging is an important medical imaging modality for the diagnosis of cardiovascular diseases
We proposed a novel reconstruction framework that efficiently combines compressed sensing and non-linear parallel imaging technique to accelerate dynamic cardiac imaging, extending results in our conference papers [40, 41]
The center 32 phase encoding lines were fully sampled as the auto calibration signals (ACS) data and estimating the coil sensitivity, which makes the net reduction factor R = 2.89 for all methods
Summary
Dynamic Magnetic resonance imaging (dMRI) is an important medical imaging modality for the diagnosis of cardiovascular diseases. Hu et al BMC Medical Imaging (2021) 21:182 from the undersampled MRI data by exploiting spatial and/or temporal correlations in the dynamic image series. The success of applying CS to dynamic cardiac MRI greatly accelerates the acquisition process [18,19,20,21,22,23,24,25,26] Such success is based on two important properties of the dynamic cardiac images: firstly, the dynamic cardiac images exhibit strong correlations between frames which guarantee the sparse representation of the sequence in a specific transform domain; secondly, the sampling pattern can be designed to satisfy the incoherence requirement of CS theory
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