Construction and calibration of a 50 T/m z-gradient coil for quantitative diffusion microimaging

q-Space imaging is capable of providing quantitative geometrical information of structures at cellular resolution. However, the size of restrictions that can be probed hinges on available gradient amplitude and places very high demands on gradient performance. In this work we describe the design and...

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Bibliographic Details
Published in:Journal of magnetic resonance (1997) 2007-05, Vol.186 (1), p.17-25
Main Authors: Wright, A.C., Bataille, H., Ong, H.H., Wehrli, S.L., Song, H.K., Wehrli, F.W.
Format: Article
Language:English
Subjects:
Animals
Calibration
Computer-Aided Design
Diffusion
Diffusion Magnetic Resonance Imaging - instrumentation
Diffusion Magnetic Resonance Imaging - standards
Equipment Design
Equipment Failure Analysis
Gradient coil
Image Enhancement - instrumentation
Image Enhancement - standards
Magnetics
Mice
NMR microimaging
q-space
Reproducibility of Results
Sensitivity and Specificity
Spinal cord
Spinal Cord - anatomy & histology
Spinal Cord - physiology
Transducers
United States
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Summary:q-Space imaging is capable of providing quantitative geometrical information of structures at cellular resolution. However, the size of restrictions that can be probed hinges on available gradient amplitude and places very high demands on gradient performance. In this work we describe the design and construction of a small, high-amplitude (50 T/m) z-gradient coil, interfaced with a commercial 9.4 T microimaging system. We also describe a method to calibrate the coil for quantitative measurements of molecular diffusion at very high-gradient amplitudes. Calibration showed linear current response up to 50 T/m, with a gain = 1.255 T/m/A. The z-gradient coil was combined with the commercial x- and y-gradients for tri-axial imaging, and its performance was demonstrated by ADC maps of free water and by q-space experiments on water sequestered around polystyrene microspheres (4.5 μm diameter), which showed the expected diffraction peak. In addition, diffusion-weighted images of a fixed mouse spinal cord illustrated the capability of this coil for quantitative imaging of tissue microstructure.
ISSN:1090-7807
1096-0856
DOI:10.1016/j.jmr.2007.01.011