2018
DOI: 10.1002/mrm.27628
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Magnetic resonance fingerprinting with dictionary‐based fat and water separation (DBFW MRF): A multi‐component approach

Abstract: Purpose To obtain a fast and robust fat‐water separation with simultaneous estimation of water T 1 , fat T 1 , and fat fraction maps. Methods We modified an MR fingerprinting (MRF) framework to use a single dictionary combination of a water and fat dictionary. A variable TE acquisition pattern with maximum TE = 4.8 ms was used to increase the fat–water separability. Radiofrequency (RF) spoiling was used to reduce the… Show more

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Cited by 43 publications
(59 citation statements)
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“…Assländer et al analytically calculated the CRLB and its gradient for the pSSFP sequence, but this is valid only for balanced sequences with constraints on the dephasing between TRs, TR ≪ T1, T2, and restrictions on the sign of the magnetization. Overall, these approaches may face difficulty when applied to MRF sequences with gradient spoiling, RF‐spoiling, additional parameter estimates such as fat fraction or T2*, or long repetition times …”
Section: Theorymentioning
confidence: 99%
See 1 more Smart Citation
“…Assländer et al analytically calculated the CRLB and its gradient for the pSSFP sequence, but this is valid only for balanced sequences with constraints on the dephasing between TRs, TR ≪ T1, T2, and restrictions on the sign of the magnetization. Overall, these approaches may face difficulty when applied to MRF sequences with gradient spoiling, RF‐spoiling, additional parameter estimates such as fat fraction or T2*, or long repetition times …”
Section: Theorymentioning
confidence: 99%
“…Assländer et al analytically calculated the CRLB and its gradient for the pSSFP sequence, but this is valid only for balanced sequences with constraints on the dephasing between TRs, TR ≪ T 1 , T 2 , and restrictions on the sign of the magnetization. Overall, these approaches may face difficulty when applied to MRF sequences with gradient spoiling, 12 RF-spoiling, 28,29 additional parameter estimates such as fat fraction 30 or T * 2 , 28,31 or long repetition times. 32 Automatic differentiation allows us to jointly optimize over flip angles and TRs with high-computational efficiency in MRF, where finite differences would be infeasible due to the number of control variables.…”
Section: Motivation For Automatic Differentiation In Optimal Contromentioning
confidence: 99%
“…In previous approaches to enable water–fat MRF, additional parameters such as B 0 and/or B 1 needed to be included in the dictionary for correction. The correction was achieved in earlier water–fat MRF works using separate acquisitions to obtain the field maps or adding the additional parameters as part of the dictionary matching step . Both techniques significantly increase the dictionary size (and corresponding computation time) without providing additional diagnostic information.…”
Section: Introductionmentioning
confidence: 99%
“…The correction was achieved in earlier water-fat MRF works using separate acquisitions to obtain the field maps 25,26 or adding the additional parameters as part of the dictionary matching step. [22][23][24] Both techniques significantly increase the dictionary size (and corresponding computation time) without providing additional diagnostic information. Since cardiac MRF requires subject-specific dictionaries, shortening dictionary computation times is essential to maintain feasible reconstruction times.…”
Section: Introductionmentioning
confidence: 99%
“…Some examples include sequences that are sensitive to T 2 *, 61-64 perfusion, 65,66 and water-fat quantification. 43,67 A more complicated model is needed in the case of MRF for chemical exchange, or MRF-X, 68 in which six properties are quantified, including two relaxation properties to characterize two exchanging components within a voxel, volume fraction, and exchange rate.…”
Section: Direct Sequence Optimization and Metricsmentioning
confidence: 99%