T1, T2, and fat fraction cardiac MR fingerprinting: preliminary clinical evaluation
Journal of Magnetic Resonance Imaging, 2021•Wiley Online Library
Background Dixon cardiac magnetic resonance fingerprinting (MRF) has been recently
introduced to simultaneously provide water T1, water T2, and fat fraction (FF) maps. Purpose
To assess Dixon cardiac MRF repeatability in healthy subjects and its clinical feasibility in a
cohort of patients with cardiovascular disease. Population T1MES phantom, water‐fat
phantom, 11 healthy subjects and 19 patients with suspected cardiovascular disease. Study
Type Prospective. Field Strength/Sequence 1.5 T, inversion recovery spin echo (IRSE) …
introduced to simultaneously provide water T1, water T2, and fat fraction (FF) maps. Purpose
To assess Dixon cardiac MRF repeatability in healthy subjects and its clinical feasibility in a
cohort of patients with cardiovascular disease. Population T1MES phantom, water‐fat
phantom, 11 healthy subjects and 19 patients with suspected cardiovascular disease. Study
Type Prospective. Field Strength/Sequence 1.5 T, inversion recovery spin echo (IRSE) …
Background
Dixon cardiac magnetic resonance fingerprinting (MRF) has been recently introduced to simultaneously provide water T1, water T2, and fat fraction (FF) maps.
Purpose
To assess Dixon cardiac MRF repeatability in healthy subjects and its clinical feasibility in a cohort of patients with cardiovascular disease.
Population
T1MES phantom, water‐fat phantom, 11 healthy subjects and 19 patients with suspected cardiovascular disease.
Study Type
Prospective.
Field Strength/Sequence
1.5T, inversion recovery spin echo (IRSE), multiecho spin echo (MESE), modified Look–Locker inversion recovery (MOLLI), T2 gradient spin echo (T2‐GRASE), 6‐echo gradient rewound echo (GRE), and Dixon cardiac MRF.
Assessment
Dixon cardiac MRF precision was assessed through repeated scans against conventional MOLLI, T2‐GRASE, and PDFF in phantom and 11 healthy subjects. Dixon cardiac MRF native T1, T2, FF, postcontrast T1 and synthetic extracellular volume (ECV) maps were assessed in 19 patients in comparison to conventional sequences. Measurements in patients were performed in the septum and in late gadolinium enhanced (LGE) areas and assessed using mean value distributions, correlation, and Bland–Altman plots. Image quality and diagnostic confidence were assessed by three experts using 5‐point scoring scales.
Statistical Tests
Paired Wilcoxon rank signed test and paired t‐tests were applied. Statistical significance was indicated by *(P < 0.05).
Results
Dixon cardiac MRF showed good overall precision in phantom and in vivo. Septal average repeatability was ~23 msec for T1, ~2.2 msec for T2, and ~1% for FF. Biases in healthy subjects/patients were measured at +37 msec*/+60 msec* and –8.8 msec*/–8 msec* when compared to MOLLI and T2‐GRASE, respectively. No statistically significant differences in postcontrast T1 (P = 0.17) and synthetic ECV (P = 0.19) measurements were observed in patients.
Data Conclusion
Dixon cardiac MRF attained good overall precision in phantom and healthy subjects, while providing coregistered T1, T2, and fat fraction maps in a single breath‐hold scan with similar or better image quality than conventional methods in patients.
Level of Evidence
2.
Technical Efficacy Stage
2.
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