Advances in plastic optical fiber bio/chemical sensors to realize point-of-care-tests

IF 11.8 1区化学 Q1 CHEMISTRY, ANALYTICAL Trends in Analytical Chemistry Pub Date : 2024-06-01 DOI:10.1016/j.trac.2024.117797

Nunzio Cennamo , Maria Pesavento , Francesco Arcadio , Chiara Marzano , Luigi Zeni

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Abstract

The characteristics of Plastic Optical Fibers (POFs) are exploited to realize simple, highly sensitive, and low-cost bio/chemical sensors via innovative schemes. The POF's multimode characteristic and the simple modification processes are used to obtain novel ultra-sensitive platforms that can be combined with different kinds of receptors (bio-mimetic or biological receptors) to detect specific substances in different ranges for several application fields. This review reports several POF platforms based on different optical transduction principles obtained via low-cost setups, such as surface plasmon resonance (SPR), localized SPR, lossy mode resonance, evanescent wave, and others. The reported sensor configurations are useful to understand how the balance of the combination of these two components (POF platforms and receptors) can produce the desired optimal performance of the POF-based bio/chemical sensor in terms of substance and detection range.

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分析化学发展趋势》评论手稿塑料光纤生物/化学传感器在实现护理点测试方面的进展

利用塑料光纤（POF）的特性，通过创新方案实现简单、高灵敏度和低成本的生物/化学传感器。利用 POF 的多模特性和简单的改性工艺，可获得新型超灵敏平台，该平台可与不同类型的受体（生物模拟受体或生物受体）相结合，在不同范围内检测特定物质，适用于多个应用领域。本综述报告了几种基于不同光学传导原理的 POF 平台，这些原理是通过低成本设置获得的，如表面等离子体共振 (SPR)、局部 SPR、有损模式共振、蒸发波等。所报告的传感器配置有助于了解如何平衡这两种成分（POF 平台和受体）的组合，使基于 POF 的生物/化学传感器在物质和检测范围方面达到所需的最佳性能。

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来源期刊

Trends in Analytical Chemistry 化学-分析化学

CiteScore

20.00

自引率

4.60%

发文量

257

审稿时长

3.4 months

期刊介绍： TrAC publishes succinct and critical overviews of recent advancements in analytical chemistry, designed to assist analytical chemists and other users of analytical techniques. These reviews offer excellent, up-to-date, and timely coverage of various topics within analytical chemistry. Encompassing areas such as analytical instrumentation, biomedical analysis, biomolecular analysis, biosensors, chemical analysis, chemometrics, clinical chemistry, drug discovery, environmental analysis and monitoring, food analysis, forensic science, laboratory automation, materials science, metabolomics, pesticide-residue analysis, pharmaceutical analysis, proteomics, surface science, and water analysis and monitoring, these critical reviews provide comprehensive insights for practitioners in the field.