Your search keyword '"Uri Nevo"' showing total 2 results

1. Estimation of pore size distribution using concentric double pulsed-field gradient NMR

Author

Uri Nevo and Dan Benjamini

Subjects

Nuclear and High Energy Physics, Magnetic Resonance Spectroscopy, Manufactured Materials, Dispersity, Biophysics, Analytical chemistry, Condensed Matter Physics, Biochemistry, Characterization (materials science), Computational physics, Amplitude, Materials Testing, Range (statistics), Well-defined, Porous medium, Pulsed field gradient, Porosity, Algorithms

Abstract

Estimation of pore size distribution of well calibrated phantoms using NMR is demonstrated here for the first time. Porous materials are a central constituent in fields as diverse as biology, geology, and oil drilling. Noninvasive characterization of monodisperse porous samples using conventional pulsed-field gradient (PFG) NMR is a well-established method. However, estimation of pore size distribution of heterogeneous polydisperse systems, which comprise most of the materials found in nature, remains extremely challenging. Concentric double pulsed-field gradient (CDPFG) is a 2-D technique where both q (the amplitude of the diffusion gradient) and φ (the relative angle between the gradient pairs) are varied. A recent prediction indicates this method should produce a more accurate and robust estimation of pore size distribution than its conventional 1-D versions. Five well defined size distribution phantoms, consisting of 1–5 different pore sizes in the range of 5–25 μm were used. The estimated pore size distributions were all in good agreement with the known theoretical size distributions, and were obtained without any a priori assumption on the size distribution model. These findings support that in addition to its theoretical benefits, the CDPFG method is experimentally reliable. Furthermore, by adding the angle parameter, sensitivity to small compartment sizes is increased without the use of strong gradients, thus making CDPFG safe for biological applications.

Published

2013

2. Faster imaging with a portable unilateral NMR device

Author

Asaf Liberman, Elad Bergman, Yifat Sarda, and Uri Nevo

Subjects

Nuclear and High Energy Physics, Signal processing, Scanner, Magnetic Resonance Spectroscopy, Miniaturization, business.industry, Computer science, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, Biophysics, High resolution, Signal Processing, Computer-Assisted, Equipment Design, Fast spin echo, Condensed Matter Physics, Data Compression, Biochemistry, Signal, Magnetic Resonance Imaging, Equipment Failure Analysis, Compressed sensing, Nuclear magnetic resonance, Single point imaging, business, Computer hardware

Abstract

Unilateral NMR devices are important tools in various applications such as non-destructive testing and well logging, but are not applied routinely for imaging, primarily because B0 inhomogeneity in these scanners leads to a relatively low signal and requires use of the slow single point imaging scan scheme. Enabling high quality, fast imaging could make this affordable and portable technology practical for various imaging applications as well as for new applications that are not yet feasible with MRI technology. The goal of this work was to improve imaging times in a portable unilateral NMR scanner. Both Compressed Sensing and Fast Spin Echo were modified and applied to fit the unique characteristics of a unilateral device. Two printed phantoms, allowing high resolution images, were scanned with both methods and compared to a standard scan and to a low pass scan to evaluate performance. Both methods were found to be feasible with a unilateral device, proving ways to accelerate single point imaging in such scanners. This outcome encourages us to explore how to further accelerate imaging times in unilateral NMR devices so that this technology might become clinically applicable in the future.

Published

2012