单线态氧
灵敏度(控制系统)
二氧乙烷
化学发光
化学
光化学
氧气
组合化学
有机化学
工程类
电子工程
作者
Rozan Tannous,Tal Kopp,Doron Shabat
出处
期刊:JACS Au
[American Chemical Society]
日期:2025-05-23
卷期号:5 (6): 2871-2883
被引量:3
标识
DOI:10.1021/jacsau.5c00465
摘要
Chemiluminescence imaging has emerged as a powerful alternative to fluorescence-based methods, offering significant advantages such as reduced background noise, elimination of autofluorescence, and prevention of photobleaching. These benefits are particularly critical for singlet oxygen detection, where the excitation light in fluorescence techniques can inadvertently generate singlet oxygen, compromising measurement accuracy. Despite this potential, the development of highly sensitive chemiluminescent probes for singlet oxygen detection under physiological conditions remains an urgent challenge. Here, we present a comprehensive structure-activity optimization of phenoxy-1,2-dioxetane precursors as probes for singlet oxygen detection in physiological environments. By systematically evaluating key parameterssteric hindrance at the oxidation site, the chemiexcitation rate of the luminophore, and total light emissionwe significantly increased the detection sensitivity of the singlet oxygen probe. Notably, a cyclobutyl-enolether probe (SOCL-CB) and a dimethyl-enolether probe (SOCL-DM) demonstrated 57-fold and 118-fold higher signal-to-noise (S/N) ratios, respectively, compared to the previously reported chemiluminescent adamantyl-enolether probe (SOCL-AD). The superior detection sensitivity of probe SOCL-DM was validated in an enzymatic model where singlet oxygen production was mediated by horseradish peroxidase. Remarkably, probe SOCL-DM detected singlet oxygen concentrations as low as 127 nM in this system, outperforming the previously reported probe SOCL-AD. These results establish probe SOCL-DM as the most sensitive chemiluminescent probe for singlet oxygen detection under physiological conditions reported to date. This study underscores the potential of chemiluminescent probes like SOCL-DM to facilitate real-time monitoring of singlet oxygen, providing invaluable tools for studying oxidative stress, elucidating cellular processes, and advancing diagnostic applications.
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