Purpose: To develop and evaluate an imaging sequence to simultaneously quantify the epicardial fat volume and myocardial T 1 relaxation time.
Methods: We introduced a novel simultaneous myocardial T 1 mapping and fat/water separation sequence (joint T 1 -fat/water separation). Dixon reconstruction is performed on a dual-echo data set to generate water/fat images. T 1 maps are computed using the water images, whereas the epicardial fat volume is calculated from the fat images. A phantom experiment using vials with different T 1 /T 2 values and a bottle of oil was performed. Additional phantom experiment using vials of mixed fat/water was performed to show the potential of this sequence to mitigate the effect of intravoxel fat on estimated T 1 maps. In vivo evaluation was performed in 17 subjects. Epicardial fat volume, native myocardial T 1 measurements and precision were compared among slice-interleaved T 1 mapping, Dixon, and the proposed sequence.
Results: In the first phantom, the proposed sequence separated oil from water vials and there were no differences in T 1 of the fat-free vials (P = .1). In the second phantom, the T 1 error decreased from 22%, 36%, 57%, and 73% to 8%, 9%, 16%, and 26%, respectively. In vivo there was no difference between myocardial T 1 values (1067 ± 17 ms versus 1077 ± 24 ms, P = .6). The epicardial fat volume was similar for both sequences (54.3 ± 33 cm 3 versus 52.4 ± 32 cm 3 , P = .8).
Conclusion: The proposed sequence provides simultaneous quantification of native myocardial T 1 and epicardial fat volume. This will eliminate the need for an additional sequence in the cardiac imaging protocol if both measurements are clinically indicated.
(© 2018 The Authors Magnetic Resonance in Medicine published by Wiley Periodicals, Inc. on behalf of International Society for Magnetic Resonance in Medicine.)