Title :
A tuned SQUID amplifier for MRI based on a DOIT flux locked loop
Author :
Seton, H.C. ; Hutchison, J.M.S. ; Bussell, D.M.
Author_Institution :
Dept. of Bio-Med. Phys. & Bio-Eng., Aberdeen Univ., UK
fDate :
6/1/1997 12:00:00 AM
Abstract :
We have developed a 4.2 K, flux locked, tuned d.c. SQUID amplifier to improve the SNR of a low field MRI system operating at 0.01 T (425 kHz). The flux locked loop, based on the Direct Offset Integration Technique, has a noise level of 2.6 /spl mu//spl Phi//sub 0/ Hz/sup -1/2/ and a slew rate of 1.6/spl times/10/sup 6/ /spl Phi//sub 0/ s/sup -1/ at 425 kHz when used with a commercially obtained SQUID. The high intrinsic Q-factor of the MRI pick-up coil is damped by the action of the loop and by an additional feedback circuit to provide imaging bandwidths of up to 10 kHz. We have developed a special low noise liquid helium cryostat so that the final system has a magnetic field resolution of 0.08 fT Hz/sup -1/. This receiver was used in a small scale MRI system to image non-conducting test objects and the human arm. The images show significant improvements in SNR over those obtained with an equivalent room temperature receiver.
Keywords :
SQUIDs; biomedical NMR; biomedical electronics; 0.01 T; 10 kHz; 4.2 K; 425 kHz; DOIT flux locked loop; Direct Offset Integration Technique; SNR; damped Q-factor; feedback circuit; human arm; imaging bandwidth; low field MRI system; low noise liquid helium cryostat; magnetic field resolution; noise level; nonconducting test object; pick-up coil; receiver; slew rate; tuned DC SQUID amplifier; Bandwidth; Circuit noise; Coils; Feedback circuits; High-resolution imaging; Magnetic resonance imaging; Noise level; Q factor; SQUIDs; Signal to noise ratio;
Journal_Title :
Applied Superconductivity, IEEE Transactions on
