Design and first implementation of wireless square-shaped transmission line resonators in 1H MRI for small animal studies

[Display omitted] •Novel square-shaped design for transmission line resonators.•Calculation of the resonant frequency matches the measured value with a small error.•Cheap cost and absence of high-voltage non-magnetic capacitors.•Easy fabrication with the help of any printed circuit boards company.•U...

Full description

Saved in:
Bibliographic Details
Published in:Journal of magnetic resonance (1997) 2022-06, Vol.339, p.107216-107216, Article 107216
Main Authors: Gulyaev, Mikhail V., Protopopov, Alex, Pavlova, Olga S., Anisimov, Nikolay V., Pirogov, Yury A.
Format: Article
Language:English
Subjects:
B1+ mapping
Mathematical calculations
RF coil design
Transmission line resonator
Wireless coil
Citations: Items that this one cites
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:[Display omitted] •Novel square-shaped design for transmission line resonators.•Calculation of the resonant frequency matches the measured value with a small error.•Cheap cost and absence of high-voltage non-magnetic capacitors.•Easy fabrication with the help of any printed circuit boards company.•Use in routine MRI studies as inductively coupled coil. This work is dedicated to the development of a novel design for wireless transmission line resonators (TLRs). The TLRs are often considered as circular-shaped coils made up of two conductive circuits separated by a dielectric layer. We propose a square-shaped TLR design, wherein the coil has two square turns with two symmetrical gaps on each of the conductive layers, and the latter are rotated relative to each other by 90°. The calculation error of the resonant frequency of the square-shaped TLRs is no more than ∼3% of the measured value. The effectiveness of the square-shaped TLR design was evaluated in comparative 1H MRI studies to conventional wireless square loop of the same resonant frequency and with the same-sized inner square of the TLR. The Bruker birdcage was used as a transceiver and as inductively coupled with the wireless coils. We found that the performance of the square-shaped TLR and the square loop is comparable, but the B1+-field generated by the TLR has a wider distribution profile. It was reflected in rat brain studies, when some structures of rat head were not captured by the square loop. Comparative experiments with a standard circular-shaped TLR showed that a signal is predominantly concentrated inside the inner turn of the TLRs. The proposed TLR design can be a promising path to be explored, especially for scanning small objects of study, when the scan area is comparable to the size of the rigid lumped capacitors.
ISSN:1090-7807
1096-0856
DOI:10.1016/j.jmr.2022.107216