确保食品安全:基于微流控技术的食品污染物检测方法

IF 3 Q2 CHEMISTRY, ANALYTICAL Analytical science advances Pub Date : 2024-04-14 DOI:10.1002/ansa.202400003
Tom Kasputis, Kait Elizabeth Hosmer, Yawen He, Juhong Chen
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引用次数: 0

摘要

检测食源性污染是确保食品安全、防止人类痛苦和经济损失的关键挑战。受污染的食品包括生物制剂(如细菌、病毒和真菌)和化学物质(如毒素、过敏原、抗生素和重金属),对公众健康构成重大风险。微流控技术是一种变革性的解决方案,它以精确、高效的方法彻底改变了污染物的检测。通过在微型系统上操作微小体积的流体,微流体技术能够制造出用于生物传感应用的便携式芯片。从早期的玻璃和硅装置到现代的聚合物和纤维素芯片,微流体技术的进步大大提高了微流体技术的适应性、灵活性、成本效益和生物兼容性。微流控系统可与各种生物传感反应无缝集成,促进核酸扩增、目标分析物识别和精确信号读取。随着研究的不断深入,微流控技术有望在应对食源性污染物检测领域不断变化的挑战方面发挥关键作用。在这篇简短的综述中,我们将深入探讨最先进微流体设备的各种制造材料,包括无机物、弹性体、热塑性塑料和纸张。此外,我们还研究了微流控技术在检测食品污染物(包括细菌、病毒、真菌、过敏原等)方面具有独特优势的几种应用。本综述强调了微流控技术的巨大进步及其在推动食源性污染物检测和缓解方面的关键作用。
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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Ensuring food safety: Microfluidic-based approaches for the detection of food contaminants

Detecting foodborne contamination is a critical challenge in ensuring food safety and preventing human suffering and economic losses. Contaminated food, comprising biological agents (e.g. bacteria, viruses and fungi) and chemicals (e.g. toxins, allergens, antibiotics and heavy metals), poses significant risks to public health. Microfluidic technology has emerged as a transformative solution, revolutionizing the detection of contaminants with precise and efficient methodologies. By manipulating minute volumes of fluid on miniaturized systems, microfluidics enables the creation of portable chips for biosensing applications. Advancements from early glass and silicon devices to modern polymers and cellulose-based chips have significantly enhanced microfluidic technology, offering adaptability, flexibility, cost-effectiveness and biocompatibility. Microfluidic systems integrate seamlessly with various biosensing reactions, facilitating nucleic acid amplification, target analyte recognition and accurate signal readouts. As research progresses, microfluidic technology is poised to play a pivotal role in addressing evolving challenges in the detection of foodborne contaminants. In this short review, we delve into various manufacturing materials for state-of-the-art microfluidic devices, including inorganics, elastomers, thermoplastics and paper. Additionally, we examine several applications where microfluidic technology offers unique advantages in the detection of food contaminants, including bacteria, viruses, fungi, allergens and more. This review underscores the significant advancement of microfluidic technology and its pivotal role in advancing the detection and mitigation of foodborne contaminants.

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