3D quantitative myocardial perfusion imaging with hyperpolarized HP001(bis-1,1-(hydroxymethyl)-[1-13C]cyclopropane-d8): Application of gradient echo and balanced SSFP sequences

Purpose: This study aims to show the viability of conducting three-dimensional (3D) myocardial perfusion quantification covering the entire heart using both GRE and bSSFP sequences with hyperpolarized HP001. Methods: A GRE sequence and a bSSFP sequence, both with a stack-of-spirals readout, were designed and applied to three pigs. The images were reconstructed using C-13 coil sensitivity maps measured in a phantom experiment. Perfusion was quantified using a constrained decomposition method, and the estimated rest/stress perfusion values from C-13 GRE/bSSFP and Dynamic contrast-enhanced MRI (DCE-MRI) were individually analyzed through histograms and the mean perfusion values were compared with reference values obtained from PET(O-15-water). The Myocardial Perfusion Reserve Index (MPRI) was estimated for C-13 GRE/bSSFP and DCE-MRI and compared with the reference values. Results: Perfusion values, estimated by both DCE and C-13 MRI, were found to be lower than reference values. However, DCE-MRI's estimated perfusion values were closer to the reference values than those obtained from C-13 MRI. In the case of MPRI estimation, the C-13 estimated MPRI values (GRE/bSSFP: 2.3/2.0) more closely align with the literature value (around 3) than the DCE estimated MPRI value (1.6). Conclusion: This study demonstrated the feasibility of 3D whole-heart myocardial perfusion quantification using hyperpolarized HP001 with both GRE and bSSFP sequences. The C-13 perfusion measurements underestimated perfusion values compared to the O-15 PET literature value, while the C-13 estimated MPRI value aligned better with the literature. This preliminary result indicates C-13 imaging may more accurately estimate MPRI values compared to DCE-MRI.