论文信息 - SQUID-detected in vivo MRI at microtesla magnetic fields

SQUID-detected in vivo MRI at microtesla magnetic fields

We use a low transition temperature (T/sub c/) Super-conducting Quantum Interference Device (SQUID) to perform in vivo magnetic resonance imaging (MRI) at magnetic fields around 100 microtesla, corresponding to proton Larmor frequencies of about 5 kHz. In such low fields, broadening of the nuclear magnetic resonance lines due to inhomogeneous magnetic fields and susceptibility variations of the sample are minimized, enabling us to obtain high quality images. To reduce environmental noise the signal is detected by a second-order gradiometer, coupled to the SQUID, and the experiment is surrounded by a 3-mm thick Al shield. To increase the signal-to-noise ratio (SNR), we prepolarize the samples in a field up to 100 mT. Three-dimensional images are acquired in less than 6 minutes with a standard spin-echo phase-encoding sequence. Using encoding gradients of /spl sim/100 /spl mu/T/m we obtain three-dimensional images of bell peppers with a resolution of 2/spl times/2/spl times/8 mm/sup 3/. Our system is ideally suited to acquiring images of small, peripheral parts of the human body such as hands and arms. In vivo images of an arm, acquired at 132 /spl mu/T, show 24-mm sections of the forearm with a resolution of 3/spl times/3 mm/sup 2/ and a SNR of 10. We discuss possible applications of MRI at these low magnetic fields.

[1] P. Lauterbur,et al. Image Formation by Induced Local Interactions: Examples Employing Nuclear Magnetic Resonance , 1973, Nature.

[2] Yu-Chung N. Cheng,et al. Magnetic Resonance Imaging: Physical Principles and Sequence Design , 1999 .

[3] Miss A.O. Penney. (b) , 1974, The New Yale Book of Quotations.

[4] Gorazd Planinsic,et al. Relaxation-time measurement and imaging in the earth's magnetic field , 1994 .

[5] Robert McDermott,et al. Microtesla MRI with a superconducting quantum interference device. , 2004, Proceedings of the National Academy of Sciences of the United States of America.

[6] S. H. Koenig,et al. Relaxometry of Tissue , 2007 .

[7] John Clarke,et al. Superconducting quantum interference devices: State of the art and applications , 2003, Proceedings of the IEEE.

[8] A Macovski,et al. Novel approaches to low‐cost MRI , 1993, Magnetic resonance in medicine.

[9] J. Hutchison,et al. A 4.2 K receiver coil and SQUID amplifier used to improve the SNR of low-field magnetic resonance images of the human arm , 1997 .

[10] John S George,et al. SQUID detected NMR in microtesla magnetic fields. , 2004, Journal of magnetic resonance (San Diego, Calif. 1997 : Print).

[11] P. Mansfield,et al. NMR 'diffraction' in solids? , 1973 .

[12] John Clarke,et al. Low field magnetic resonance images of polarized noble gases obtained with a dc superconducting quantum interference device , 1998 .