A minimum-phase Shinnar-Le Roux spectral-spatial excitation RF pulse for simultaneous water and lipid suppression in 1H-MRSI of body extremities

Abstract Purpose To develop a spectral-spatial (SPSP) excitation RF pulse for simultaneous water and lipid suppression in proton ( 1 H) magnetic resonance spectroscopic imaging (MRSI) of body extremities. Methods An SPSP excitation pulse is designed to excite Creatine (Cr) and Choline (Cho) metabolite signals while suppressing the overwhelming water and lipid signals. The SPSP pulse is designed using a recently proposed multidimensional Shinnar-Le Roux (SLR) RF pulse design method. A minimum-phase spectral selectivity profile is used to minimize signal loss from T 2 ⁎ decay. Results The performance of the SPSP pulse is evaluated via Bloch equation simulations and phantom experiments. The feasibility of the proposed method is demonstrated using three-dimensional, short repetition-time, free induction decay-based 1 H-MRSI in the thigh muscle at 3 T. Conclusion The proposed SPSP excitation pulse is useful for simultaneous water and lipid suppression. The proposed method enables new applications of high-resolution 1 H-MRSI in body extremities.