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用于选择性醛检测的荧光化学传感器的最新进展。

Recent progress in fluorescent chemosensors for selective aldehyde detection.

作者信息

Semwal Keshav, Das Avijit Kumar

机构信息

Department of Chemistry, Christ University Hosur Road Bangalore 560029 Karnataka India

出版信息

RSC Adv. 2025 Apr 1;15(13):10005-10021. doi: 10.1039/d5ra01010a. eCollection 2025 Mar 28.

DOI:10.1039/d5ra01010a
PMID:40171288
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11959364/
Abstract

Aldehydes (R-CHO) are volatile and chemically active compounds prevalent in the environment, industrial chemicals, food fermentation, and human metabolism. Their release into the atmosphere can lead to pollution and adverse health effects, from mild irritation to severe respiratory and immune system damage. Among aldehydes, formaldehyde (FA) and acetaldehyde (AA) are notable indoor air pollutants with stringent safety limits set by organizations like WHO and OSHA. Current detection techniques, including gas and liquid chromatography, while highly accurate, are expensive and require trained personnel. Conventional sensors, such as semiconductor and chemiresistive types, offer portability and online detection but are hindered by poor selectivity and sensitivity. Optical chemosensors, which operate based on fluorescence or colorimetric changes induced by chemical interactions, have emerged as a promising alternative due to their high sensitivity, selectivity, cost-effectiveness, and portability. This review explores the advancements in optical chemosensors for aldehyde detection, emphasizing novel molecular designs utilizing mechanisms like imine bond formation, cyclization reactions, and aza-Cope rearrangements The applications of these sensors in environmental monitoring, biomedical analysis, and other industries are highlighted, showcasing their potential for real-time, low-concentration detection of aldehydes in diverse settings.

摘要

醛类(R-CHO)是挥发性且具有化学活性的化合物,广泛存在于环境、工业化学品、食品发酵和人体新陈代谢中。它们释放到大气中会导致污染并对健康产生不利影响,从轻度刺激到严重的呼吸系统和免疫系统损害。在醛类中,甲醛(FA)和乙醛(AA)是显著的室内空气污染物,世界卫生组织(WHO)和职业安全与健康管理局(OSHA)等组织对其设定了严格的安全限值。当前的检测技术,包括气相色谱法和液相色谱法,虽然准确性高,但成本高昂且需要专业人员操作。传统传感器,如半导体和化学电阻型传感器,具有便携性和可在线检测的特点,但选择性和灵敏度较差。基于化学相互作用引起的荧光或比色变化进行工作的光学化学传感器,因其高灵敏度、选择性、成本效益和便携性,已成为一种有前景的替代方案。本综述探讨了用于醛类检测的光学化学传感器的进展,重点介绍了利用亚胺键形成、环化反应和氮杂-Cope重排等机制的新型分子设计。还突出了这些传感器在环境监测、生物医学分析和其他行业中的应用,展示了它们在不同环境中对醛类进行实时、低浓度检测的潜力。

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