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A 32-Channel Sleeve Antenna Receiver Array for Human Head MRI Applications at 10.5 T

Myung Kyun Woo, Lance DelaBarre, Matt Waks, Russell Lagore, Jeehoon Kim, Steve Jungst, Yiğitcan Eryaman, Kǎmil Uǧurbil, Gregor Adriany

2023IEEE Transactions on Medical Imaging11 citationsDOIOpen Access PDF

Abstract

For human brain magnetic resonance imaging (MRI), high channel count ( ≥ 32 ) radiofrequency receiver coil arrays are utilized to achieve maximum signal-to-noise ratio (SNR) and to accelerate parallel imaging techniques. With ultra-high field (UHF) MRI at 7 tesla (T) and higher, dipole antenna arrays have been shown to generate high SNR in the deep regions of the brain, however the array elements exhibit increased electromagnetic coupling with one another, making array construction more difficult with the increasing number of elements. Compared to a classical dipole antenna array, a sleeve antenna array incorporates the coaxial ground into the feed-point, resulting in a modified asymmetric antenna structure with improved intra-element decoupling. Here, we extended our previous 16-channel sleeve transceiver work and developed a 32-channel azimuthally arranged sleeve antenna receive-only array for 10.5 T human brain imaging. We experimentally compared the achievable SNR of the sleeve antenna array at 10.5 T to a more traditional 32-channel loop array bult onto a human head-shaped former. The results obtained with a head shaped phantom clearly demonstrated that peripheral intrinsic SNR can be significantly improved compared to a loop array with the same number of elements- except for the superior part of the phantom where sleeve antenna elements are not located.

Topics & Concepts

Head (geology)Human headAntenna (radio)Channel (broadcasting)Computer scienceOpticsTelecommunicationsPhysicsGeologyGeomorphologyAbsorption (acoustics)Advanced MRI Techniques and ApplicationsAdvanced NMR Techniques and ApplicationsElectron Spin Resonance Studies