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小鼠体内氮氧化物的脉冲电子顺磁共振成像

Pulsed EPR imaging of nitroxides in mice.

作者信息

Hyodo Fuminori, Matsumoto Shingo, Devasahayam Nallathamby, Dharmaraj Christopher, Subramanian Sankaran, Mitchell James B, Krishna Murali C

机构信息

Radiation Biology Branch, Center for Cancer Research, National Cancer Institute, National Institutes of Health, Bethesda, MD 20892-1002, USA.

出版信息

J Magn Reson. 2009 Apr;197(2):181-5. doi: 10.1016/j.jmr.2008.12.018. Epub 2008 Dec 24.

DOI:10.1016/j.jmr.2008.12.018
PMID:19157932
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3496157/
Abstract

Nitroxides, unlike trityl radicals, have shorter T(2)s which until now were not detectable in vivo by a time-domain pulsed Electron Paramagnetic Resonance (EPR) spectrometer at 300 MHz since their phase memory times were shorter than the spectrometer recovery times. In the current version of the time-domain EPR spectrometer with improved spectrometer recovery times, the feasibility of detecting signals from nitroxide radicals was tested. Among the nitroxides evaluated, deuterated (15)N-Tempone ((15)N-PDT) was found to have the longest T(2). The signal intensity profile as a function of concentration of these agents was evaluated and a biphasic behavior was observed; beyond a nitroxide concentration of 1.5mM, signal intensity was found to decrease as a result of self-broadening. Imaging experiments were carried out with (15)N-PDT in solutions equilibrated with 0%, 5%, 10%, and 21% oxygen using the single point imaging (SPI) modality in EPR. The image intensity in these tubes was found to depend on the oxygen concentration which in turn influences the T(2) of (15)N-PDT. In vivo experiments were demonstrated with (15)N-PDT in anesthetized mice where the distribution and metabolism of (15)N-PDT could be monitored. This study, for the first time shows the capability to image a cell-permeable nitroxide in mice using pulsed EPR in the SPI modality.

摘要

与三苯甲基自由基不同,氮氧化物的T(2)较短,由于其相位记忆时间短于光谱仪恢复时间,到目前为止,在300 MHz的时域脉冲电子顺磁共振(EPR)光谱仪上无法在体内检测到它们。在具有改进的光谱仪恢复时间的当前版本的时域EPR光谱仪中,测试了检测来自氮氧化物自由基信号的可行性。在所评估的氮氧化物中,发现氘代(15)N-Tempone((15)N-PDT)具有最长的T(2)。评估了这些试剂的信号强度随浓度的变化情况,观察到一种双相行为;当氮氧化物浓度超过1.5 mM时,由于自展宽,信号强度会降低。使用EPR中的单点成像(SPI)模式,用(15)N-PDT在与0%、5%、10%和21%氧气平衡的溶液中进行成像实验。发现这些试管中的图像强度取决于氧气浓度,而氧气浓度又会影响(15)N-PDT的T(2)。在麻醉小鼠中用(15)N-PDT进行了体内实验,在该实验中可以监测(15)N-PDT的分布和代谢。这项研究首次展示了使用SPI模式的脉冲EPR在小鼠体内对细胞可渗透的氮氧化物进行成像的能力。

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