In vivo EPR spectroscopy of free radicals in the heart.
Author(s) -
Jay L. Zweíer,
Periannan Kuppusamy
Publication year - 1994
Publication title -
environmental health perspectives
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 2.257
H-Index - 282
eISSN - 1552-9924
pISSN - 0091-6765
DOI - 10.1289/ehp.94102s1045
Subject(s) - electron paramagnetic resonance , radical , spectrometer , in vivo , chemistry , spectroscopy , nuclear magnetic resonance , analytical chemistry (journal) , aqueous solution , materials science , biochemistry , organic chemistry , optics , physics , quantum mechanics , biology , microbiology and biotechnology
Electron paramagnetic resonance (EPR) spectroscopy can be applied to directly measure free radicals; however, it has not been possible to measure important biologic radicals in situ because conventional spectrometer designs are not suitable for the performance of measurements on large aqueous structures such as whole organs or tissues. We describe the design, construction, and application of instrumentation developed in an effort to obtain optimum performance in measuring free radicals in intact biologic organs or tissues. This spectrometer consists of a 1- to 2-GHz microwave bridge with the source locked to the resonant frequency of a specially designed recessed gap, loop-gap resonator. The principles of resonator design and construction are analyzed and described. Using this spectrometer radical concentrations as low as 0.4 microM in aqueous solutions could be measured. Studies of isolated beating hearts involving simultaneous real time measurements of free radicals and cardiac contractile function are performed. This in vivo EPR technique is applied to study the kinetics of free radical uptake and metabolism in normally perfused and globally ischemic hearts. In addition, it is demonstrated that this technique can be used to noninvasively measure tissue oxygen consumption. Thus, low frequency EPR spectroscopy offers great promise in the study of in vivo free radical generation and the effects of this radical generation on whole biologic tissues.
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