利用新型纳米复合比色传感器高效检测小麦霉变程度

IF 4 2区 农林科学 Q2 CHEMISTRY, APPLIED
Hui Jiang , Menghan Ge , Jihong Deng , Quansheng Chen
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引用次数: 0

摘要

小麦是全球最重要的粮食作物之一,由小麦霉菌产生的黄曲霉毒素 B1 (AFB1) 有可能对人类和牲畜造成严重危害。本研究利用介孔二氧化硅纳米颗粒(MSNs)修饰比色传感阵列(CSA),制备了纳米复合比色传感器(Nano-CSA),用于鉴定小麦霉菌的程度。选择了 12 种金属卟啉试剂作为构建 CSA 的化学反应染料。为了提高传感器的灵敏度,将 MSNs 与 12 种化学反应染料单独结合,并通过超声波振荡和磁力搅拌等技术促进 MSNs 与染料的均匀结合。传感器的设计目的是在封闭的反应室中与真菌产生的挥发性气体发生反应。MSNs 能有效捕捉气体分子,使化学染料的颜色发生显著变化,从而通过比色传感系统对不同霉变程度小麦的气体指纹进行表征。对数据进行了表征技术和数据分析,以证明纳米修饰传感器阵列的有效性。在识别不同霉变程度的小麦样本时,CSA 的准确率为 87.50%,而 Nano-CSA 分类模型的准确率为 97.50%。这些研究结果表明,纳米修饰可以提高化学反应染料对气体分子的反应能力。纳米-CSA 可以有效、灵敏地分辨小麦的霉变程度,在预测小麦霉变程度方面具有潜在的应用价值。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Efficient detection of wheat mold degree using novel nano-composite colorimetric sensor
Wheat is one of the most significant food crops globally, and the aflatoxin B1 (AFB1) produced by wheat mold has the potential to cause substantial harm to humans and livestock. This study employed mesoporous silica nanoparticles (MSNs) to modify colorimetric sensing arrays (CSA) for the preparation of nano-composite colorimetric sensors (Nano-CSA) for the identification of the degree of wheat mold. Twelve metal porphyrin reagents were selected as chemical response dyes for the construction of the CSA. To enhance the sensor's sensitivity, the MSNs were individually combined with the 12 chemical response dyes, and the homogeneous integration of the MSNs and dyes was facilitated through techniques such as ultrasonic oscillation and magnetic stirring. The sensor is designed to react with the volatile gas the fungus produces in a closed reaction chamber. The MSNs effectively capture gas molecules, causing significant color changes in the chemical dyes, thereby enabling the characterization of the gas fingerprints of wheat with different degrees of mold through a colorimetric sensing system. The data were subjected to characterization techniques and data analysis to demonstrate the effectiveness of the nano-modified sensor array. The CSA demonstrated an accuracy of 87.50 % in identifying wheat samples with varying degrees of mildew, while the Nano-CSA classification model exhibited an accuracy of 97.50 %. These findings indicate that nano-modification can enhance the responsiveness of chemical response dyes to gas molecules. Nano-CSA can effectively and sensitively distinguish the degree of wheat mildew, suggesting potential applications in predicting the degree of wheat mildew.
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来源期刊
Journal of Food Composition and Analysis
Journal of Food Composition and Analysis 工程技术-食品科技
CiteScore
6.20
自引率
11.60%
发文量
601
审稿时长
53 days
期刊介绍: The Journal of Food Composition and Analysis publishes manuscripts on scientific aspects of data on the chemical composition of human foods, with particular emphasis on actual data on composition of foods; analytical methods; studies on the manipulation, storage, distribution and use of food composition data; and studies on the statistics, use and distribution of such data and data systems. The Journal''s basis is nutrient composition, with increasing emphasis on bioactive non-nutrient and anti-nutrient components. Papers must provide sufficient description of the food samples, analytical methods, quality control procedures and statistical treatments of the data to permit the end users of the food composition data to evaluate the appropriateness of such data in their projects. The Journal does not publish papers on: microbiological compounds; sensory quality; aromatics/volatiles in food and wine; essential oils; organoleptic characteristics of food; physical properties; or clinical papers and pharmacology-related papers.
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