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Design of universal parallel‐transmit refocusing k T ‐point pulses and application to 3D T 2 ‐weighted imaging at 7T
Author(s) -
Gras Vincent,
Mauconduit Franck,
Vignaud Alexandre,
Amadon Alexis,
Bihan Denis,
Stöcker Tony,
Boulant Nicolas
Publication year - 2018
Publication title -
magnetic resonance in medicine
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.696
H-Index - 225
eISSN - 1522-2594
pISSN - 0740-3194
DOI - 10.1002/mrm.27001
Subject(s) - specific absorption rate , flip angle , parallel communication , computer science , imaging phantom , excitation , physics , radio frequency , pulse (music) , transmission (telecommunications) , nuclear magnetic resonance , optics , magnetic resonance imaging , telecommunications , quantum mechanics , medicine , detector , antenna (radio) , radiology
Purpose T 2 ‐weighted sequences are particularly sensitive to the radiofrequency (RF) field inhomogeneity problem at ultra‐high‐field because of the errors accumulated by the imperfections of the train of refocusing pulses. As parallel transmission (pTx) has proved particularly useful to counteract RF heterogeneities, universal pulses were recently demonstrated to save precious time and computational efforts by skipping B 1 calibration and online RF pulse tailoring. Here, we report a universal RF pulse design for non‐selective refocusing pulses to mitigate the RF inhomogeneity problem at 7T in turbo spin‐echo sequences with variable flip angles. Method Average Hamiltonian theory was used to synthetize a single non‐selective refocusing pulse with pTx while optimizing its scaling properties in the presence of static field offsets. The design was performed under explicit power and specific absorption rate constraints on a database of 10 subjects using a 8Tx‐32Rx commercial coil at 7T. To validate the proposed design, the RF pulses were tested in simulation and applied in vivo on 5 additional test subjects. Results The root‐mean‐square rotation angle error (RA‐NRMSE) evaluation and experimental data demonstrated great improvement with the proposed universal pulses (RA‐NRMSE ∼8%) compared to the standard circularly polarized mode of excitation (RA‐NRMSE ∼26%). Conclusion This work further completes the spectrum of 3D universal pulses to mitigate RF field inhomogeneity throughout all 3D MRI sequences without any pTx calibration. The approach returns a single pulse that can be scaled to match the desired flip angle train, thereby increasing the modularity of the proposed plug and play approach. Magn Reson Med 80:53–65, 2018. © 2017 International Society for Magnetic Resonance in Medicine.