T 1e and T 2e maps derived in vivo from the rat using longitudinally detected electron spin resonance phase imaging: Application to abdominal oxygen mapping

A novel imaging modality is introduced which uses radiofrequency longitudinally detected electron spin resonance (RF‐LODESR). It is capable of providing qualitative and semiquantitative information on a variety of parameters reflecting physiological function, the most significant being tissue oxygen...

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Bibliographic Details
Published in:Magnetic resonance in medicine 2001-12, Vol.46 (6), p.1223-1232
Main Authors: Panagiotelis, Ioannis, Nicholson, Ian, Foster, Margaret A., Hutchison, James M.S.
Format: Article
Language:English
Subjects:
electron relaxation times
ESR
in vivo EPR
LODESR
oxygen imaging
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Summary:A novel imaging modality is introduced which uses radiofrequency longitudinally detected electron spin resonance (RF‐LODESR). It is capable of providing qualitative and semiquantitative information on a variety of parameters reflecting physiological function, the most significant being tissue oxygenation. Effective spin‐lattice (T *1e) and spin‐spin (T *2e) electronic relaxation time maps of the abdomen of living 200‐g rats were generated after intravenous administration of a triarylmethyl free radical (TAM). These maps were used to evaluate oxygen distribution. Differences between the liver, kidneys, and bladder were noted. Conclusions were made regarding the distribution, perfusion, and excretion rate of the contrast medium. Ligature‐induced anoxia in the kidney was also visualized. LODESR involves transverse ESR irradiation with a modulated excitation, and observing oscillations in the spin magnetization parallel to the main magnetic field. The T *1e and T *2e maps were calculated from a set of LODESR signal phase images collected at different detection frequencies. Each phase image also provides qualitative information on tissue oxygen levels without any further processing. This method presents an alternative to the conventional transverse ESR linewidth‐based oximetry methods, particularly for animal whole‐body imaging applications. Magn Reson Med 46:1223–1232, 2001. © 2001 Wiley‐Liss, Inc.
ISSN:0740-3194
1522-2594
DOI:10.1002/mrm.1320