A Quick, Highly Selective and Sensitive Colorimetric and Fluorimetric Sensor for Cyanide Ion.

IF 2.6 4区化学 Q2 BIOCHEMICAL RESEARCH METHODS

Journal of Fluorescence Pub Date : 2025-03-01 Epub Date: 2024-03-05 DOI:10.1007/s10895-024-03638-4

Jayasudha Palanisamy, Amal M Al-Mohaimeed, Wedad A Al-Onazi

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引用次数: 0

Abstract

A newly developed diindolium moiety has been synthesized and structurally investigated by employing a number of spectroscopic methods like NMR and HRMS in order to serve as a cyanide sensor DI. The interaction between DI and the CN^- ion causes a noticeable color shift from pink to colorless, making it easy to detect CN^- ions with the naked eye. Besides, the sensor exhibited fluorescence color change from orange to light blue under UV lamp. Sensor DI has remarkable selectivity and sensitivity in distinguishing between CN^- and a wide range of interfering anions. The sensing mechanism of sensor DI towards CN^- ion involves the nucleophilic addition process of CN^- to the electron deficient indolium moiety. The detection limit of cyanide ion by sensor DI is calculated to be 1.4 × 10^- 7 M by UV-visible and 8.2 × 10^- 8 M by fluorescence technique which are lower than the limit set by WHO. The application of sensor DI for cyanide ion is utilized by making test kit and by taking different sources of water to test the presence of cyanide ion.

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一种快速、高选择性、高灵敏度的氰离子比色和荧光传感器。

我们合成了一种新开发的二吲哚鎓分子，并采用核磁共振和 HRMS 等多种光谱方法对其结构进行了研究，以便将其用作氰化物传感器 DI。DI 与 CN- 离子的相互作用会引起明显的颜色变化，从粉红色变为无色，因此很容易用肉眼检测到 CN- 离子。此外，在紫外灯下，传感器的荧光颜色也会从橙色变为淡蓝色。传感器 DI 在区分 CN- 和多种干扰阴离子方面具有显著的选择性和灵敏度。传感器 DI 对 CN- 离子的感应机制是 CN- 与缺电子的吲哚鎓分子发生亲核加成反应。根据计算，传感器 DI 对氰离子的紫外-可见光检测限为 1.4 × 10- 7 M，荧光检测限为 8.2 × 10- 8 M，均低于世界卫生组织规定的检测限。应用传感器 DI 检测氰离子的方法包括制作检测试剂盒和取不同水源检测氰离子的存在。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Fluorescence 化学-分析化学

CiteScore

4.60

自引率

7.40%

发文量

203

审稿时长

5.4 months

期刊介绍： Journal of Fluorescence is an international forum for the publication of peer-reviewed original articles that advance the practice of this established spectroscopic technique. Topics covered include advances in theory/and or data analysis, studies of the photophysics of aromatic molecules, solvent, and environmental effects, development of stationary or time-resolved measurements, advances in fluorescence microscopy, imaging, photobleaching/recovery measurements, and/or phosphorescence for studies of cell biology, chemical biology and the advanced uses of fluorescence in flow cytometry/analysis, immunology, high throughput screening/drug discovery, DNA sequencing/arrays, genomics and proteomics. Typical applications might include studies of macromolecular dynamics and conformation, intracellular chemistry, and gene expression. The journal also publishes papers that describe the synthesis and characterization of new fluorophores, particularly those displaying unique sensitivities and/or optical properties. In addition to original articles, the Journal also publishes reviews, rapid communications, short communications, letters to the editor, topical news articles, and technical and design notes.