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Comparison of 16-Channel Asymmetric Sleeve Antenna and Dipole Antenna Transceiver Arrays at 10.5 Tesla MRI

Myung Kyun Woo, Lance DelaBarre, Matt Waks, Jingu Lee, Russell Lagore, Steve Jungst, Andrea Grant, Yiğitcan Eryaman, Kǎmil Uǧurbil, Gregor Adriany

2020IEEE Transactions on Medical Imaging29 citationsDOIOpen Access PDF

Abstract

Multi-element transmit arrays with low peak 10 g specific absorption rate (SAR) and high SAR efficiency (defined as ( [Formula: see text]SAR [Formula: see text] are essential for ultra-high field (UHF) magnetic resonance imaging (MRI) applications. Recently, the adaptation of dipole antennas used as MRI coil elements in multi-channel arrays has provided the community with a technological solution capable of producing uniform images and low SAR efficiency at these high field strengths. However, human head-sized arrays consisting of dipole elements have a practical limitation to the number of channels that can be used due to radiofrequency (RF) coupling between the antenna elements, as well as, the coaxial cables necessary to connect them. Here we suggest an asymmetric sleeve antenna as an alternative to the dipole antenna. When used in an array as MRI coil elements, the asymmetric sleeve antenna can generate reduced peak 10 g SAR and improved SAR efficiency. To demonstrate the advantages of an array consisting of our suggested design, we compared various performance metrics produced by 16-channel arrays of asymmetric sleeve antennas and dipole antennas with the same dimensions. Comparison data were produced on a phantom in electromagnetic (EM) simulations and verified with experiments at 10.5 Tesla (T). The results produced by the 16-channel asymmetric sleeve antenna array demonstrated 28 % lower peak 10 g SAR and 18.6 % higher SAR efficiency when compared to the 16-channel dipole antenna array.

Topics & Concepts

Dipole antennaTransceiverAntenna (radio)PhysicsAntenna measurementMonopole antennaDipoleNuclear magnetic resonanceOpticsTelecommunicationsComputer scienceWirelessQuantum mechanicsAdvanced MRI Techniques and ApplicationsMicrowave Imaging and Scattering AnalysisAdvanced NMR Techniques and Applications