Purpose A new framework for the design of parallel transmit (pTx) pulses is presented introducing constraints for local and global specific absorption rate (SAR) in the presence of errors in the radiofrequency (RF) transmit chain. Methods The first step is the design of a pTx RF pulse with explicit constraints for global and local SAR. Then, the worst possible SAR associated with that pulse due to RF transmission errors ("worst-case SAR") is calculated. Finally, this information is used to re-calculate the pulse with lower SAR constraints, iterating this procedure until its worst-case SAR is within safety limits. Results Analysis of an actual pTx RF transmit chain revealed amplitude errors as high as 8% (20%) and phase errors above 3° (15°) for spokes (spiral) pulses. Simulations show that using the proposed framework, pulses can be designed with controlled "worst-case SAR" in the presence of errors of this magnitude at minor cost of the excitation profile quality. Conclusion Our worst-case SAR-constrained pTx design strategy yields pulses with local and global SAR within the safety limits even in the presence of RF transmission errors. This strategy is a natural way to incorporate SAR safety factors in the design of pTx pulses.
Bibliographical noteFunding Information:
Grant sponsor: Consejer?a de Educaci?n, Juventud y Deporte de la Comunidad de Madrid (Spain) through the Madrid-MIT M1Visi?n Consortium project; Grant sponsor: Spanish Ministry of Economy and Competitiveness; Grant number: Project TEC2012-39095-C03-02; Grant sponsor: National Institutes of Health; Grant number: R01EB006847; Grant sponsor: Siemens-MIT CKI Alliance.
- RF errors
- SAR control
- high-field MRI
- pTx pulse design