Datensatz

Zusammenfassung

Purpose: To optimize transmit k-space trajectories for a wide range of excitation targets and to design 'Universal pTx RF pulses' based on these trajectories.

Methods: Transmit k-space trajectories (stack-of-spirals and SPINS) were optimized to best match different excitation targets using the parameters of the analytical equations of spirals and SPINS. The performances of RF pulses designed based on optimized and non-optimized trajectories were compared. The optimized trajectories were utilized for universal pulse design. The universal pulse performances were compared with subject specific tailored pulse performances. The OTUP-workflow (Optimization of transmit k-space Trajectories and Universal Pulse calculation) was tested on three test target excitation patterns. For one target (local excitation of a central area in the human brain) the pulses were tested in vivo at 9.4T.

Results: The workflow produced appropriate transmit k-space trajectories for each test target. Utilization of an optimized trajectory was crucial for the pulse performance. Using unsuited trajectories diminished the performance. It was possible to create target specific universal pulses. However, not every test target is equally well suited for universal pulse design. There was no significant difference in the in vivo performance between subject specific tailored pulses and universal pulse at 9.4T.

Conclusions: The proposed workflow further exploited and improved the universal pulse concept by combining it with gradient trajectory optimization for stack-of-spirals and SPINS. It emphasized the importance of a well-suited trajectory for pTx RF pulse design. Universal and tailored pulses performed with a sufficient degree of similarity in simulations and a high degree of similarity in vivo. The implemented OTUP-workflow and the B0 /B1 + map data from 18 subjects measured at 9.4T are available as open source (https://github.com/ole1965/workflow_OTUP.git).