Parallel-transmit (pTx) RF excitation offers minor improvements compared to standard circularly polarized excitation if local SAR limits are always enforced.
Parallel-transmit body coils can be safely used at 0.5T, 1.5T, and 3T, but uncertainties in patient anatomy require simulating many models to establish appropriate safety factors.
Abstract Purpose To investigate safety and performance aspects of parallel‐transmit (pTx) RF control‐modes for a body coil at . Methods Electromagnetic simulations of 11 human voxel models in cardiac imaging position were conducted for , and and a body coil with a configurable number of transmit channels (1, 2, 4, 8, 16). Three safety modes were considered: the ‘SAR‐controlled mode’ (SCM), where specific absorption rate (SAR) is limited directly, a ‘phase agnostic SAR‐controlled mode’ (PASCM), where phase information is neglected, and a ‘power‐controlled mode’ (PCM), where the voltage amplitude for each channel is limited. For either mode, safety limits were established based on a set of ‘anchor’ simulations and then evaluated in ‘target’ simulations on previously unseen models. The comparison allowed to derive safety factors accounting for varying patient anatomies. All control modes were compared in terms of the amplitude and homogeneity they permit under their respective safety requirements. Results Large safety factors (approximately five) are needed if only one or two anchor models are investigated but they shrink with increasing number of anchors. The achievable is highest for SCM but this advantage is reduced when the safety factor is included. PCM appears to be more robust against variations of subjects. PASCM performance is mostly in between SCM and PCM. Compared to standard circularly polarized (CP) excitation, pTx offers minor improvements if local SAR limits are always enforced. Conclusion PTx body coils can safely be used at . Uncertainties in patient anatomy must be accounted for, however, by simulating many models.
Petzold et al. (Wed,) conducted a other in cardiac imaging (n=11). Parallel-transmit (pTx) RF control-modes vs. Standard circularly polarized (CP) excitation was evaluated on Amplitude and homogeneity permitted under safety requirements. Parallel-transmit (pTx) RF excitation offers minor improvements compared to standard circularly polarized excitation if local SAR limits are always enforced.