利用纳米结构作为SERS基底的生物成像、检测和分析。

Wei Xie, Penghe Qiu, Chuanbin Mao
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引用次数: 112

摘要

表面增强拉曼散射(SERS)是发生在纳米级粗糙金属表面的一种现象。当散射体放置在非常接近表面的位置时,拉曼散射信号的幅度可以大大增强,这使得这种现象成为一种高灵敏度的分析技术。SERS继承了传统拉曼光谱的一般优点,克服了拉曼散射固有的小截面问题。这是一种灵敏且无损的生物样品光谱方法,既可用于传递分子结构信息,也可用于检测痕量分析物。因此,SERS一直被认为是生物医学研究的有力工具。金属纳米结构在SERS的所有生物医学应用中起着关键作用,因为增强的拉曼信号只能在精细划分的衬底表面获得。本文综述了SERS作为一种分析技术在生物成像、分析和检测中的应用进展。本文还重点介绍了SERS活性纳米结构制备的最新进展。
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Bio-imaging, detection and analysis by using nanostructures as SERS substrates.

Surface-enhanced Raman scattering (SERS) is a phenomenon that occurs on nanoscale-roughed metallic surface. The magnitude of the Raman scattering signal can be greatly enhanced when the scatterer is placed in the very close vicinity of the surface, which enables this phenomenon to be a highly sensitive analytical technique. SERS inherits the general strongpoint of conventional Raman spectroscopy and overcomes the inherently small cross section problem of a Raman scattering. It is a sensitive and nondestructive spectroscopic method for biological samples, and can be exploited either for the delivery of molecular structural information or for the detection of trace levels of analytes. Therefore, SERS has long been regarded as a powerful tool in biomedical research. Metallic nanostructure plays a key role in all the biomedical applications of SERS because the enhanced Raman signal can only be obtained on the surface of a finely divided substrate. This review focuses on progress made in the use of SERS as an analytical technique in bio-imaging, analysis and detection. Recent progress in the fabrication of SERS active nanostructures is also highlighted.

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来源期刊
Journal of Materials Chemistry
Journal of Materials Chemistry 工程技术-材料科学:综合
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1.5 months
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