生理水平的氧对电子顺磁共振检测自由基中间体的影响。

M C Krishna, A Samuni
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引用次数: 8

摘要

众所周知,氧通过自旋晶格和海森堡自旋-自旋相互作用增强了自由基EPR探针的弛豫,从而影响了线的高度和宽度。这两种弛豫过程对信号高度有相反的影响,并取决于氧的浓度、入射微波功率和其他顺磁物质的存在。在涉及自由基的化学、生化和细胞过程的EPR研究中,分子氧除了影响主要自由基的产生速度和自旋加合物氮氧化物的稳定性外,还对所研究的自由基物种的EPR信号强度具有显著的磁性影响。这些影响经常被忽视,并可能导致伪影并导致错误的解释。在常用的微波功率下,研究了氧和铁氰化物对稳定和持久自旋加合氮氧化物EPR信号高度的影响。结果表明,在常用的EPR光谱仪仪器条件下,自旋加合物的EPR信号会发生人为变化,避免这种变化的最佳方法是使用透气池保持氧水平恒定。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
The effect of oxygen at physiological levels on the detection of free radical intermediates by electron paramagnetic resonance.

It is well known that oxygen enhances the relaxation of free radical EPR probes through spin lattice and Heisenberg spin-spin interactions with consequent effect on the line height and width. The two relaxation processes have opposing effects on the signal heights and depend on the concentration of oxygen, the incident microwave power, and the presence of other paramagnetic species. During EPR studies of chemical, biochemical, and cellular processes involving free radicals, molecular oxygen has significant magnetic influence on the EPR signal intensity of the free radical species under investigation in addition to affecting the rates of production of the primary species and the stability of the spin adduct nitroxides. These effects are often overlooked and can cause artifacts and lead to erroneous interpretation. In the present study, the effects of oxygen and ferricyanide on the EPR signal height of stable and persistent spin adduct nitroxides at commonly employed microwave powers were examined. The results show that under commonly adopted EPR spectrometer instrumental conditions, artifactual changes in the EPR signal of spin adducts occur and the best way to avoid them is by keeping the oxygen level constant using a gas-permeable cell.

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