期刊
NMR IN BIOMEDICINE
卷 34, 期 7, 页码 -出版社
WILEY
DOI: 10.1002/nbm.4515
关键词
body imaging at UHF MRI; integrated transmit coil arrays; VOP compression
资金
- EuropeanResearch Council [291903]
- European Research Council (ERC) [291903] Funding Source: European Research Council (ERC)
This study investigates the performance of integrated RF transmit arrays with high channel counts for body imaging at 7 T, optimizing the position and number of transmit elements. Results show that integrated multiring arrays can generate homogeneous B-1(+) field distributions for large FOVs, especially for coronal/sagittal slices, enabling body imaging at 7 T with a clinical workflow.
The aim of the current study was to investigate the performance of integrated RF transmit arrays with high channel count consisting of meander microstrip antennas for body imaging at 7 T and to optimize the position and number of transmit elements. RF simulations using multiring antenna arrays placed behind the bore liner were performed for realistic exposure conditions for body imaging. Simulations were performed for arrays with as few as eight elements and for arrays with high channel counts of up to 48 elements. The B-1(+) field was evaluated regarding the degrees of freedom for RF shimming in the abdomen. Worst-case specific absorption rate (SAR(wc)), SAR overestimation in the matrix compression, the number of virtual observation points (VOPs) and SAR efficiency were evaluated. Constrained RF shimming was performed in differently oriented regions of interest in the body, and the deviation from a target B-1(+) field was evaluated. Results show that integrated multiring arrays are able to generate homogeneous B-1(+) field distributions for large FOVs, especially for coronal/sagittal slices, and thus enable body imaging at 7 T with a clinical workflow; however, a low duty cycle or a high SAR is required to achieve homogeneous B-1(+) distributions and to exploit the full potential. In conclusion, integrated arrays allow for high element counts that have high degrees of freedom for the pulse optimization but also produce high SAR(wc), which reduces the SAR accuracy in the VOP compression for low-SAR protocols, leading to a potential reduction in array performance. Smaller SAR overestimations can increase SAR accuracy, but lead to a high number of VOPs, which increases the computational cost for VOP evaluation and makes online SAR monitoring or pulse optimization challenging. Arrays with interleaved rings showed the best results in the study.
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