Motivation: Unlocking SNR benefits of ultra-high field for high-resolution quantitative MRI is hindered by transmit-field (B1+) inhomogeneities because optimal flip-angles are not realised throughout the field-of-view. Goal(s): We investigate how flip-angle schedules for MR Fingerprinting can be adjusted to enhance robustness towards B1+ inhomogeneity. Approach: We incorporate B1+ into Cramer-Rao bound optimisation, demonstrate that predicted errors are reduced compared with a conventionally optimised flip-angle schedule, and show this in invivo experiments. Results: B1+ informed CRB optimisation reduces predicted peak T2-error by a factor of three, which removes artefacts in invivo experiments. B1+ corrections successfully removed shading in T1-maps. Impact: This work addresses one of the problems of quantitative imaging at ultra-high field to make its benefit more accessible. The larger aim is to achieve high resolution parameter maps which can be useful for diagnosis and research of neurodegenerative diseases.
Horger et al. (Tue,) studied this question.
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