Abstract
Magnetic resonance fingerprinting (MRF) is able to estimate multiple quantitative tissue parameters from a relatively short acquisition. The main characteristic of an MRF sequence is the simultaneous application of 1) transient states excitation and 2) highly undersampled ${k}$-space. Despite the promising empirical results obtained with MRF, no work has appeared that formally describes the combined impact of these two aspects on the reconstruction accuracy. In this paper, a mathematical model is derived that directly relates the time-varying RF excitation and the ${k}$-space sampling to the spatially dependent reconstruction errors. A subsequent in-depth analysis identifies the mechanisms by which MRF sequence properties affect accuracy, providing a formal explanation of several empirically observed or intuitively understood facts. The new insights are obtained which show how this analytical framework could be used to improve the MRF protocol.
Original language | English |
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Pages (from-to) | 2445-2455 |
Journal | IEEE Transactions on Medical Imaging |
Volume | 38 |
Issue number | 10 |
DOIs | |
Publication status | Published - Oct 2019 |
Keywords
- Error analysis
- MR fingerprinting
- experimental design
- magnetic resonance imaging
- quantitative MRI