Radio frequency coil technology for small-animal MRI

A review of the theory, technology, and use of radio frequency (RF) coils for small‐animal MRI is presented. It includes a brief overview of MR signal‐to‐noise (S/N) analysis and discussions of the various coils commonly used in small‐animal MR: surface coils, linear volume coils, birdcages, and the...

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Bibliographic Details
Published in:NMR in biomedicine 2007-05, Vol.20 (3), p.304-325
Main Authors: Doty, F. David, Entzminger, George, Kulkarni, Jatin, Pamarthy, Kranti, Staab, John P.
Format: Article
Language:English
Subjects:
Animals
Brain - diagnostic imaging
circular polarization volume coils
decoupling
Electric Capacitance
Electric Conductivity
Embryo, Mammalian - diagnostic imaging
low-noise preamplifiers
Magnetic Resonance Imaging - instrumentation
Magnetic Resonance Imaging - methods
Mice
Models, Theoretical
phased arrays
Radio Waves
Radiography
Rats
small-animal MRI
surface coils
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Summary:A review of the theory, technology, and use of radio frequency (RF) coils for small‐animal MRI is presented. It includes a brief overview of MR signal‐to‐noise (S/N) analysis and discussions of the various coils commonly used in small‐animal MR: surface coils, linear volume coils, birdcages, and their derivatives. The scope is limited to mid‐range coils, i.e. coils where the product (fd) of the frequency f and the coil diameter d is in the range 2–30 MHz‐m. Common applications include mouse brain and body coils from 125 to 750 MHz, rat body coils up to 500 MHz, and small surface coils at all fields. In this regime, all the sources of loss (coil, capacitor, sample, shield, and transmission lines) are important. All such losses may be accurately captured in some modern full‐wave 3D electromagnetics software, and new simulation results are presented for a selection of surface coils using Microwave Studio 2006 by Computer Simulation Technology, showing the dramatic importance of the ‘lift‐off effect’. Standard linear circuit simulators have been shown to be useful in optimization of complex coil tuning and matching circuits. There appears to be considerable potential for trading S/N for speed using phased arrays, especially for a larger field of view. Circuit simulators are shown to be useful for optimal mismatching of ultra‐low‐noise preamps based on the enhancement‐mode pseudomorphic high‐electron‐mobility transistor for optimal coil decoupling in phased arrays. Cryogenically cooled RF coils are shown to offer considerable opportunity for future gains in S/N in smaller samples. Copyright © 2007 John Wiley & Sons, Ltd.
ISSN:0952-3480
1099-1492
DOI:10.1002/nbm.1149