Fast multi-parametric imaging in abdomen by corrected dual-flip angle sequence with interleaved echo acquisition.

Purpose: To achieve simultaneous T /proton density fat fraction (PDFF)/ mapping in abdomen within a single breadth-hold, and validate the accuracy using state-of-art measurement.

Theory And Methods: An optimized multiple echo gradient echo (GRE) sequence with dual flip-angle acquisition was used to realize simultaneous water T (T )/PDFF/ quantification. A new method, referred to as "solving the fat-water ambiguity based on their T difference" (SORT), was proposed to address the fat-water separation problem. This method was based on the finding that compared to the true solution, the wrong (or aliased) solution to fat-water separation problem showed extra dependency on the applied flip angle due to the T difference between fat and water. The measurement sequence was applied to correct the inhomogeneity for T relaxometry. The 2D parallel imaging was incorporated to enable the acquisition within a single breath-hold in abdomen.

Results: The multi-parametric quantification results of the proposed method were consistent with the results of reference methods in phantom experiments (PDFF quantification: R  = 0.993, mean error 0.73%; T quantification: R  = 0.999, mean error 4.3%; quantification: R  = 0.949, mean error 4.07 s ). For volunteer studies, robust fat-water separation was achieved without evident fat-water swaps. Based on the accurate fat-water separation, simultaneous T /PDFF/ quantification was realized for whole liver within a single breath-hold.

Conclusion: The proposed method accurately quantified T /PDFF/ for the whole liver within a single breath-hold. This technique serves as a quantitative tool for disease management in patients with hepatic steatosis.