Theoretical study on oxidation mechanism of fluorescent probe, coumarin-7-pinacolboronate by various reactive oxygen species

IF 1.9 4区 化学 Q2 CHEMISTRY, ORGANIC Journal of Physical Organic Chemistry Pub Date : 2023-11-20 DOI:10.1002/poc.4585
Yujie Guo, Yan Leng, Hongbo Liu, Chun-Gang Min, Ai-Min Ren, Qinhong Yin
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Abstract

Hydrogen peroxide (H2O2) as relatively stable reactive oxygen species gains considerable attention because it can regulate physiological and pathological processes. In order to better detect H2O2, fluorescent probes were widely applied. Over the past 20 years, a great deal of boronate-based fluorescent molecular probes appeared due to relatively simple oxidation reaction. However, the reaction mechanisms that boronate derivatives were converted into fluorescent product by H2O2 are poorly studied. In this paper, taking coumarin-7-pinacolboronate (CBU) as an example, the oxidation mechanism of boronate-based probes by various reactive oxygen species was studied by theoretical calculations. The results found that (1) the chemical reaction mechanisms are nearly identical for the reactions of CBU with hydrogen peroxide, hypochlorous acid, peroxynitrite, and tyrosine hydroperoxide, respectively. (2) There is not radical intermediate during the reaction. (3) The different reactive oxygen species has a strong influence on rate limiting step and reaction rate.

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各种活性氧氧化荧光探针香豆素-7-蒎酸硼酸酯机理的理论研究
过氧化氢(H2O2)作为一种相对稳定的活性氧,因其能够调节人体的生理和病理过程而备受关注。为了更好地检测H2O2,荧光探针被广泛应用。近20年来,由于氧化反应相对简单,出现了大量基于硼酸盐的荧光分子探针。然而,硼酸盐衍生物在H2O2作用下转化为荧光产物的反应机理研究较少。本文以香豆素-7-蒎酸硼酸酯(CBU)为例,通过理论计算研究了不同活性氧对硼酸酯基探针的氧化机理。结果发现:(1)CBU分别与过氧化氢、次氯酸、过氧亚硝酸盐和过氧化酪氨酸的化学反应机理几乎相同。(2)反应过程中无自由基中间体。(3)不同的活性氧种类对限速步长和反应速率有较大的影响。
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来源期刊
CiteScore
3.60
自引率
11.10%
发文量
161
审稿时长
2.3 months
期刊介绍: The Journal of Physical Organic Chemistry is the foremost international journal devoted to the relationship between molecular structure and chemical reactivity in organic systems. It publishes Research Articles, Reviews and Mini Reviews based on research striving to understand the principles governing chemical structures in relation to activity and transformation with physical and mathematical rigor, using results derived from experimental and computational methods. Physical Organic Chemistry is a central and fundamental field with multiple applications in fields such as molecular recognition, supramolecular chemistry, catalysis, photochemistry, biological and material sciences, nanotechnology and surface science.
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