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Displacement current distribution on a high dielectric constant helmet and its effect on RF field at 10.5 T (447 MHz)
Author(s) -
Gandji Navid P.,
Sica Christopher T.,
Lanagan Michael T.,
Woo MyungKyun,
DelaBarre Lance,
Radder Jerahmie,
Zhang Bei,
Lattanzi Riccardo,
Adriany Gregor,
Ugurbil Kamil,
Yang Qing X.
Publication year - 2021
Publication title -
magnetic resonance in medicine
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.696
H-Index - 225
eISSN - 1522-2594
pISSN - 0740-3194
DOI - 10.1002/mrm.28923
Subject(s) - specific absorption rate , human head , imaging phantom , head (geology) , electromagnetic coil , displacement (psychology) , dipole , materials science , dielectric , absorption (acoustics) , electric field , optics , electromagnetic field , acoustics , physics , computational physics , nuclear magnetic resonance , computer science , optoelectronics , telecommunications , geology , psychology , quantum mechanics , geomorphology , antenna (radio) , psychotherapist
Purpose Investigating the designs and effects of high dielectric constant (HDC) materials in the shape of a conformal helmet on the enhancement of RF field and reduction of specific absorption rate at 10.5 T for human brain studies. Methods A continuous and a segmented four‐piece HDC helmet fit to a human head inside an eight‐channel fractionated‐dipole array were constructed and studied with a phantom and a human head model using computer electromagnetic simulations. The simulated transmit efficiency and receive sensitivity were experimentally validated using a phantom with identical electric properties and helmet‐coil configurations of the computer model. The temporal and spatial distributions of displacement currents on the HDC helmets were analyzed. Results Using the continuous HDC helmet, simulation results in the human head model demonstrated an average transmit efficiency enhancement of 66%. A propagating displacement current was induced on the continuous helmet, leading to an inhomogeneous RF field enhancement in the brain. Using the segmented four‐piece helmet design to reduce this effect, an average 55% and 57% enhancement in the transmit efficiency and SNR was achieved in human head, respectively, along with 8% and 28% reductions in average and maximum local specific absorption rate. Conclusion The HDC helmets enhanced the transmit efficiency and SNR of the dipole array coil in the human head at 10.5 T. The segmentation of the helmet to disrupt the continuity of circumscribing displacement currents in the helmet produced a more uniform distribution of the transmit field and lower specific absorption rate in the human head compared with the continuous helmet design.

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