PURPOSE: The goal of this study is to increase patient safety in parallel transmission (pTx) MRI systems. A major concern in these systems is radiofrequency-induced tissue heating, which can be avoided by specific absorption rate (SAR) prediction and SAR monitoring before and during the scan. METHODS: In this novel comprehensive safety concept, the SAR is predicted prior to the scan based on precalculated fields obtained from electromagnetic simulations on different body models. The radiofrequency fields and the global and local SAR are supervised in real time during the scan. This concept is integrated into a 3 T pTx MR scanner and validated experimentally. RESULTS: Phantom and in vivo experiments successfully validated the basic feasibility of the real-time SAR supervision concept. Supervising the SAR minimizes SAR overestimation. Monitoring the radiofrequency fields allows the detection of unsafe radiofrequency situations for the patient, which a SAR supervision system alone cannot detect. CONCLUSION: This study demonstrates safe scanning in a pTx system. This new safety concept is also applicable for field strengths above 3 T and represents an important step toward safe operation of pTx systems.
PURPOSE: The goal of this study is to increase patient safety in parallel transmission (pTx) MRI systems. A major concern in these systems is radiofrequency-induced tissue heating, which can be avoided by specific absorption rate (SAR) prediction and SAR monitoring before and during the scan. METHODS: In this novel comprehensive safety concept, the SAR is predicted prior to the scan based on precalculated fields obtained from electromagnetic simulations on different body models. The radiofrequency fields and the global and local SAR are supervised in real time during the scan. This concept is integrated into a 3 T pTx MR scanner and validated experimentally. RESULTS: Phantom and in vivo experiments successfully validated the basic feasibility of the real-time SAR supervision concept. Supervising the SAR minimizes SAR overestimation. Monitoring the radiofrequency fields allows the detection of unsafe radiofrequency situations for the patient, which a SAR supervision system alone cannot detect. CONCLUSION: This study demonstrates safe scanning in a pTx system. This new safety concept is also applicable for field strengths above 3 T and represents an important step toward safe operation of pTx systems.
Authors: Ettore Flavio Meliadò; Alessandro Sbrizzi; Cornelis A T van den Berg; Peter R Luijten; Alexander J E Raaijmakers Journal: Magn Reson Med Date: 2020-12-22 Impact factor: 4.668
Authors: Natalia Gudino; Jacco A de Zwart; Qi Duan; Stephen J Dodd; Joe Murphy-Boesch; Peter van Gelderen; Jeff H Duyn Journal: Magn Reson Med Date: 2017-09-14 Impact factor: 4.668
Authors: Vincent Gras; Markus Boland; Alexandre Vignaud; Guillaume Ferrand; Alexis Amadon; Franck Mauconduit; Denis Le Bihan; Tony Stöcker; Nicolas Boulant Journal: PLoS One Date: 2017-08-21 Impact factor: 3.240