非等离子体表面增强拉曼光谱纳米结构在生物医学应用中的最新进展。

IF 6.9 2区 医学 Q1 MEDICINE, RESEARCH & EXPERIMENTAL Wiley interdisciplinary reviews. Nanomedicine and nanobiotechnology Pub Date : 2022-07-01 DOI:10.1002/wnan.1795
Da Li, Kelly Aubertin, Delphine Onidas, Philippe Nizard, Nordin Félidj, Florence Gazeau, Claire Mangeney, Yun Luo
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引用次数: 3

摘要

表面增强拉曼光谱(SERS)是一种新兴的强大的振动技术,为生物医学科学提供了前所未有的机会,用于生物标志物的敏感检测以及生物样品的成像和跟踪。传统的SERS检测基于等离子体衬底(例如,Au和Ag纳米结构)的使用,这些衬底具有非常高的增强因子(EF = 1010 -1011),但存在严重的局限性,包括由于欧姆损耗引起的光致局部热效应和昂贵的价格。这些缺点可能会限制检测的准确性和大规模的实际应用。在这篇综述中,我们重点介绍了基于无等离子体SERS检测的低成本纳米结构的替代方法,如碳、氧化物、硫族化合物、聚合物、硅等。非等离子体SERS检测的机制归因于衬底和被吸附分子之间的界面电荷转移,没有光热副作用,但与等离子体纳米结构相比,通常较少的EF。回顾和讨论了通过调整衬底组成、结构和表面化学来提高拉曼信号检测的策略。生物医学应用,例如,SERS细胞表征,生物传感和生物成像也被介绍,强调了底物表面功能化的重要性,以实现敏感,准确的分析,以及良好的生物相容性。本文分类如下:诊断工具>诊断纳米设备诊断工具>生物传感诊断工具>体内纳米诊断和成像。
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Recent advances in non-plasmonic surface-enhanced Raman spectroscopy nanostructures for biomedical applications.

Surface-enhanced Raman spectroscopy (SERS) is an emerging powerful vibrational technique offering unprecedented opportunities in biomedical science for the sensitive detection of biomarkers and the imaging and tracking of biological samples. Conventional SERS detection is based on the use of plasmonic substrates (e.g., Au and Ag nanostructures), which exhibit very high enhancement factors (EF = 1010 -1011 ) but suffers from serious limitations, including light-induced local heating effect due to ohmic loss and expensive price. These drawbacks may limit detection accuracy and large-scaled practical applications. In this review, we focus on alternative approaches based on plasmon-free SERS detection on low-cost nanostructures, such as carbons, oxides, chalcogenides, polymers, silicons, and so forth. The mechanism of non-plasmonic SERS detection has been attributed to interfacial charge transfer between the substrate and the adsorbed molecules, with no photothermal side-effects but usually less EF compared with plasmonic nanostructures. The strategies to improve Raman signal detection, through the tailoring of substrate composition, structure, and surface chemistry, is reviewed and discussed. The biomedical applications, for example, SERS cell characterization, biosensing, and bioimaging are also presented, highlighting the importance of substrate surface functionalization to achieve sensitive, accurate analysis, and excellent biocompatibility. This article is categorized under: Diagnostic Tools > Diagnostic Nanodevices Diagnostic Tools > Biosensing Diagnostic Tools > In Vivo Nanodiagnostics and Imaging.

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来源期刊
Wiley interdisciplinary reviews. Nanomedicine and nanobiotechnology
Wiley interdisciplinary reviews. Nanomedicine and nanobiotechnology NANOSCIENCE & NANOTECHNOLOGY-MEDICINE, RESEARCH & EXPERIMENTAL
CiteScore
16.60
自引率
2.30%
发文量
93
期刊介绍: Nanotechnology stands as one of the pivotal scientific domains of the twenty-first century, recognized universally for its transformative potential. Within the biomedical realm, nanotechnology finds crucial applications in nanobiotechnology and nanomedicine, highlighted as one of seven emerging research areas under the NIH Roadmap for Medical Research. The advancement of this field hinges upon collaborative efforts across diverse disciplines, including clinicians, biomedical engineers, materials scientists, applied physicists, and toxicologists. Recognizing the imperative for a high-caliber interdisciplinary review platform, WIREs Nanomedicine and Nanobiotechnology emerges to fulfill this critical need. Our topical coverage spans a wide spectrum, encompassing areas such as toxicology and regulatory issues, implantable materials and surgical technologies, diagnostic tools, nanotechnology approaches to biology, therapeutic approaches and drug discovery, and biology-inspired nanomaterials. Join us in exploring the frontiers of nanotechnology and its profound impact on biomedical research and healthcare.
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