A Novel Approach for Colorimetric Detection of Glyphosate in Food Based on a Split Aptamer Nanostructure and DNAzyme Activity.

IF 2.6 4区化学 Q2 BIOCHEMICAL RESEARCH METHODS

Journal of Fluorescence Pub Date : 2024-10-29 DOI:10.1007/s10895-024-03998-x

Zahra Mohammadi, Mahdi Rahaie, Fatemeh Moradifar

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引用次数: 0

Abstract

Glyphosate has become the most widely used herbicide worldwide in recent years. There are many concerns about toxicity and mutagenicity from long-term use of glyphosate in humans and animals. Therefore, the methods that can help in easy and quick detection of this chemical compound in food and water are critical. In this work, a biosensor was fabricated by combining the enzymatic properties of a specific DNA G-quadruplex and selectivity of a split aptamer to detect glyphosate in foods and water in a quick and simple colorimetric manner. The color change in this method is based on the oxidation of TMB by the G-quadruplex enzyme and the function of aptamer to trap glyphosate, which is visible to the naked eye in the presence and absence of the herbicide. The biosensor showed its high performance in various real samples of water and foods and provided a detection limit of 1.37 nM (R² = 0.9899) with a linear response range of 100 to 400 nM of glyphosate. This biosensor can provide an innovative, cheap and fast approach for the detection and monitoring of glyphosate in various foods and water.

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基于分离式色聚体纳米结构和 DNA 酶活性的食品中草甘膦比色检测新方法

近年来，草甘膦已成为全球使用最广泛的除草剂。人们对长期使用草甘膦对人类和动物的毒性和致突变性表示担忧。因此，能够帮助简便、快速地检测食物和水中这种化学物质的方法至关重要。在这项工作中，通过结合特异性 DNA G-四链节的酶学特性和分离式适配体的选择性，制作了一种生物传感器，以快速、简单的比色法检测食品和水中的草甘膦。该方法中的颜色变化是基于 G-四叠体酶对 TMB 的氧化作用和合体对草甘膦的捕获功能，在除草剂存在和不存在的情况下，肉眼都能看到草甘膦的颜色变化。该生物传感器在各种真实的水和食品样品中表现出了很高的性能，其检测限为 1.37 nM（R² = 0.9899），草甘膦的线性响应范围为 100 至 400 nM。该生物传感器为检测和监测各种食品和水中的草甘膦提供了一种创新、廉价和快速的方法。

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.