Improving Radiofrequency Power and Specific Absorption Rate Management with Bumped Transmit Elements in Ultra-high Field MRI

Overview

Journal Magn Reson Med

Publisher Wiley

Specialty Radiology

Date 2020 Aug 9

PMID 32767392

Citations 8

Authors

Alireza Sadeghi-Tarakameh

Gregor Adriany

Gregory J Metzger

Russell L Lagore

Steve Jungst

Lance DelaBarre

Pierre-Francois Van de Moortele

Kamil Ugurbil

Ergin Atalar

Yigitcan Eryaman

Affiliations

Soon will be listed here.

Abstract

Purpose: In this study, we investigate a strategy to reduce the local specific absorption rate (SAR) while keeping constant inside the region of interest (ROI) at the ultra-high field (B ≥ 7T) MRI.

Methods: Locally raising the resonance structure under the discontinuity (i.e., creating a bump) increases the distance between the accumulated charges and the tissue. As a result, it reduces the electric field and local SAR generated by these charges inside the tissue. The at a point that is sufficiently far from the coil, however, is not affected by this modification. In this study, three different resonant elements (i.e., loop coil, snake antenna, and fractionated dipole [FD]) are investigated. For experimental validation, a bumped FD is further investigated at 10.5T. After the validation, the transmit performances of eight-channel arrays of each element are compared through electromagnetic (EM) simulations.

Results: Introducing a bump reduced the peak 10g-averaged SAR by 21, 26, 23% for the loop and snake antenna at 7T, and FD at 10.5T, respectively. In addition, eight-channel bumped FD array at 10.5T had a 27% lower peak 10g-averaged SAR in a realistic human body simulation (i.e., prostate imaging) compared to an eight-channel FD array.

Conclusion: In this study, we investigated a simple design strategy based on adding bumps to a resonant element to reduce the local SAR while maintaining inside an ROI. As an example, we modified an FD and performed EM simulations and phantom experiments with a 10.5T scanner. Results show that the peak 10g-averaged SAR can be reduced more than 25%.

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A nine-channel transmit/receive array for spine imaging at 10.5 T: Introduction to a nonuniform dielectric substrate antenna.

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