1999
DOI: 10.1073/pnas.96.8.4586
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Noninvasive measurement of anatomic structure and intraluminal oxygenation in the gastrointestinal tract of living mice with spatial and spectral EPR imaging

Abstract: EPR imaging has emerged as an important tool for noninvasive three-dimensional (3D) spatial mapping of free radicals in biological tissues. Spectral-spatial EPR imaging enables mapping of the spectral information at each spatial position, and, from the observed line width, the localized tissue oxygenation can be mapped. We report the development of EPR imaging instrumentation enabling 3D spatial and spectral-spatial EPR imaging of small animals. This instrumentation, along with the use of a biocompatible charc… Show more

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Cited by 354 publications
(303 citation statements)
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“…The EPR spectroscopy and imaging experiments were performed on a custom-built 750 MHz spectrometer with spectroscopy and imaging capability (18). The system has powerful 3D gradients capable of achieving gradient magnitudes of up to 1000 mT/m with a linearity of better than 1% over a 6-cm sphere.…”
Section: Epr Spectroscopy and Imaging Instrumentationmentioning
confidence: 99%
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“…The EPR spectroscopy and imaging experiments were performed on a custom-built 750 MHz spectrometer with spectroscopy and imaging capability (18). The system has powerful 3D gradients capable of achieving gradient magnitudes of up to 1000 mT/m with a linearity of better than 1% over a 6-cm sphere.…”
Section: Epr Spectroscopy and Imaging Instrumentationmentioning
confidence: 99%
“…The system has powerful 3D gradients capable of achieving gradient magnitudes of up to 1000 mT/m with a linearity of better than 1% over a 6-cm sphere. The microwave bridge, the transversely-oriented electric field reentrant resonator (TERR) with ATC and ACC provisions, the three sets of watercooled gradient coils, and the imaging acquisition/reconstruction software were as reported previously (16,18). The parameters for EPRI were as follows: frequency ϭ 750 MHz; microwave power ϭ 50 mW; modulation amplitude ϭ 0.1 mT; scan width ϭ 3.2 mT; scan time ϭ 15 s; time constant ϭ 80 ms; field gradient ϭ 80 mT/m along the y and z directions and 40 mT/m along the x direction; and spatial window size ϭ 40 ϫ 80 ϫ 40 mm.…”
Section: Epr Spectroscopy and Imaging Instrumentationmentioning
confidence: 99%
“…Hence low-frequency spectrometers operating in the range 200 MHz to 3 GHz were developed to enable EPR measurements on large aqueous samples. 7,14,15,[27][28][29][30][31] The main feature of these low-frequency spectrometers is the resonators capable of accommodating large aqueous samples with minimal dielectric dissipation. However, there is a disadvantage in the use of lower frequencies as the sensitivity of the measurement is directly related to the square of the operating frequency.…”
Section: Cw Epr Imaging For Biological Applications Choice Of Frequencymentioning
confidence: 99%
“…Over the last decade a variety of low-frequency instrumentation suitable for lossy biological samples have been developed, which enabled spectroscopic measurements on biological samples of sizes up to a whole rat. 7,14,15,[27][28][29][30][31] …”
Section: Cw Epr Imaging For Biological Applications Choice Of Frequencymentioning
confidence: 99%
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