Study on the Effect of Non-Symmetrical Current Distribution Controlled by Capacitor Placement in Radio-Frequency Coils for 7T MRI

Hernández, Daniel; Nam, Taewoo; Jeong, Yonghwa; Kim, Donghyuk; Kim, Kyoung-Nam

doi:10.3390/bios12100867

Cited by 3 publications

(1 citation statement)

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“…Several studies have focused on the advancement of radiofrequency coils, including loop coils and microstrips [16][17][18][19], for their application in MRI. When it comes to transmission, coils capable of generating a uniform field and maintaining a low specific absorption rate (SAR) are preferred.…”

Section: Introductionmentioning

confidence: 99%

Current Recycled and Self-Phase Shift to Expand the Length of Radio-Frequency Coils, With Application to Brain and Spine Coil Array at 7T MRI

Hernandez,

Kim,

Nam

et al. 2023

IEEE Access

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The use of the 7-Tesla (T) magnetic resonance imaging (MRI) promises improved imaging quality and higher resolution compared with lower-field MRI systems. The design of the loop coil considers the tradeoff between coil size and performance. A larger coil enables deeper field penetration, but it may result in poorer field uniformity and localization. On the other hand, a smaller coil offers improved localization capabilities, however, field penetration reduces, and multiple coil elements are required to cover the same space as large coils. Additionally, safety concerns regarding the high-energy absorption of electromagnetic waves in healthy tissues principally limit the use of the 7T MRI, which is measured with the specific absorption rate (SAR). A coil that can generate a uniform magnetic field while maintaining a low SAR is necessary to comply with the SAR limits. We propose a coil design that recirculates the current and provides a phase shift in the same structure to provide a magnetic field over a broad area, thus reducing the number of channels required to cover the same area. We present electromagnetic (EM) simulations of the proposed coil with a magnetic field and SAR computed for the brain and human spine model. We build the coil and acquire images with a phantom using a 7T MRI system. The proposed coil improves the SAR by 43% compared with the reference coil in the spinal area in the case of EM simulations, indicating the imaging quality improvement potential of our proposed coil.INDEX TERMS MRI, Antennas, Spine imaging, EM simulations.

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Section: Introductionmentioning

confidence: 99%