萃取-表面增强拉曼光谱联用技术及其在有害物质检测领域的应用

表面增强拉曼光谱(SERS)技术以其高灵敏度和分子特征指纹光谱在众多领域获得广泛应用,然而对于实际复杂样品中的目标分析物,样品基质会极大地干扰目标分析物SERS信号的准确获取,从而限制SERS在实际样品分析中的应用.萃取-表面增强拉曼光谱(Ex-SERS)联用技术为解决这一现实难题提供了可能性,国内外课题组结合萃取和SERS的各自优势,构建了基于固相萃取、固相微萃取、磁分散固相微萃取、薄层微萃取、液液分散微萃取、擦拭萃取等多种Ex-SERS联用技术,并以此发展了面向多种有害物质的Ex-SERS联用方法,可实现复杂基质中目标分析物的快速原位分离和SERS检测,进一步拓展SERS在实际样品分析中的应用.     

常压电离质谱在公共安全化学毒物检测的应用

常压电离质谱技术(Ambient ionization mass spectrometry,AIMS)以其敞开式环境、简便操作、原位、实时、高通量等优势,成为公共安全化学毒物检测领域的研究热点.该文基于文献计量分析,简要概述了AIMS的分类、发展趋势及其在公共安全化学毒物检测领域的发展现状,重点从检测灵敏度、样品前处理...     

应用于基因分析的最新SERS技术*

表面增强拉曼散射（SERS）是一种基于拉曼散射原理识别生物及化学分子的分析方法。SERS具有灵敏度高、水干扰小、分辨率高、稳定性好等优点,广泛应用于生物分析和生物医学研究领域。近年来,SERS技术在基因分析领域得到迅速的发展,成为国内外研究的热点。本文对应用于基因分析的一些最新SERS技术（包括基因的免标记检测和标记检测）进行较为全面的综述,着重介绍了免标记检测中基于金属纳米粒子和针尖增强拉曼散射的SERS技术,标记检测中基于拉曼活性物、PCR技术、分子信标、基底和标记物的SERS信号放大技术,并概括了基因多组分检测技术及SERS技术的应用前景。     

SERS技术在疾病诊断和生物分析中的应用

表面增强拉曼散射(surface-enhanced Raman scattering, SERS)技术以其独特的谱带窄、灵敏度高、抗光漂白、原位和无损等优势,在疾病诊断和生物分析领域得到了越来越广泛的应用。本文介绍了近几年来应用于生物大分子、病原微生物、细胞和活体检测分析中的最新SERS技术,并分别从标记与非标记的角度对其进行了阐述,总结了SERS标记检测生物大分子的基本识别模式,简述了检测低浓度病原微生物的SERS技术,着重评述了SERS检测技术在细胞和活体研究中的应用,并对基于SERS的疾病诊断和生物分析技术的发展趋势进行了初步展望。     

有序表面增强拉曼散射基底制备的研究发展北大核心CSCD

表面增强拉曼散射(Surface Enhanced Raman Scattering,SERS)是一种振动光谱技术,可直接识别目标分析物。在分析应用中,SERS信号的重现性极其重要,而这在很大程度上取决于SERS基底结构的均匀性。目前,SERS基底的重现性一直是制约该技术在分析测试中广泛应用的瓶颈,规则排列的纳米结构构成的有序化SERS基底的可控制备是该领域发展的前沿和趋势。本文就SERS基底的有序化制备方法及其应用进行了总结,分析了自组装法、光刻技术和模板辅助法所制备的有序SERS基底的特征、有序性形成原理和在分析测试中应用的可行性,为拓展SERS的实际应用提供一定的参考。     

基于SERS探针技术的细胞识别、成像与诊疗

表面增强拉曼散射(surface-enhanced Raman scattering, SERS),是指吸附在粗糙的金属纳米结构表面的被分析物,在光照射下其拉曼光谱获得显著增强的异常表面光学现象。近年来,SERS技术已广泛地用于物质检测和生物传感等研究,在生物医学领域表现出巨大的应用潜力并取得了令人瞩目的研究成果。本文回顾了SERS探针技术在细胞识别、成像与诊疗等方面的应用及最新研究进展,重点介绍了SERS细胞探针的构建方法与原理,以及基于SERS探针的细胞检测应用策略,并讨论了SERS探针技术在细胞检测中仍有待解决的关键问题。     

食源性致病菌的表面增强拉曼光谱检测技术研究进展

食源性致病菌引起的疾病的快速管控与预防是当前各国面临的食品安全监管难题之一,受到社会各界的广泛关注。目前常用的食源性致病菌检测方法存在步骤复杂、耗时、灵敏度低或选择性差等局限,发展快速、可靠的食源性致病菌检测方法仍是食品安全和公众健康的热点研究领域。表面增强拉曼光谱(SERS)作为一种新型的光谱快检技术,具有灵敏度高、选择性好、快速、无损检测等优点,在食源性致病菌检测方面表现出广阔的应用前景。该文简要介绍了SERS技术的背景、增强机制并总结了用于致病菌检测的活性纳米结构,全面综述了近5年来利用直接或间接SERS法以及SERS与其他技术结合检测食源性致病菌的研究进展,同时讨论了这些方法的优缺点。最后,提出当前SERS技术在实际应用中面临的挑战,并展望了SERS在食源性致病菌检测领域未来可能的发展趋势。     

表面增强拉曼光谱在细菌耐药性评价方面的研究进展

细菌耐药性问题引发全球关注。表面增强拉曼光谱技术(SERS)凭借灵敏度高、检测速度快等优势在评价细菌耐药性应用方面备受关注。本文首先总结了与细菌耐药性评价相关的SERS基底及检测方法,然后对SERS光谱技术在耐药菌和敏感菌鉴定、细菌生物膜成膜性分析与评价及抗菌药物敏感性筛查方面的应用进行总结,最后对SERS技术在细菌检测方面的一些瓶颈问题展开了讨论。希望本文能为SERS技术在细菌耐药性评价方面的应用提供方法指导和思路借鉴。     

表面增强拉曼光谱在动物源性食品兽药残留检测的研究进展

动物性食品安全问题日益突出,愈演愈烈,有关问题食品的报道也受到了公众的广泛关注。一旦兽药在畜牧养殖过程中被过度使用或滥用,药物残留将给人类健康带来严重危害。常见的残留检测方法存在成本高、速度慢和效率低等缺点,通常需要专业人员操作,传统的理化方法已不能满足食品质量检测的需要,因此研发快速高效的兽药残留检测方法起着关键作用。近年来,表面增强拉曼光谱（SERS）技术在真伪鉴别、非法添加物检测和农兽药残留等诸多领域得到了广泛应用,并以其快速检测、无损等优势在食品检测领域有着更为广阔的发展前景。与其他检测方法不同的是,SERS通过信号放大和高灵敏度的指纹光谱,可以快速识别目标分析物,进行定性或半定量分析。本文主要介绍了拉曼光谱和SERS在动物源性食品中兽药残留检测中的研究和应用,重点介绍了SERS的优势、食品样品的前处理以及SERS结合其他技术检测多种兽药的相关研究,并提出了SERS在实际监测中面临的挑战。     

基于贵金属纳米粒子的SERS活性基底研究进展

表面增强拉曼光谱(SERS)是一种新兴的分析技术,具有很高的检测灵敏度,可以实现单分子量级的检测,并且能够提供丰富的分子结构信息。将SERS发展成为一种具有实际应用意义的分析技术,其关键是制备灵敏度高、稳定性高、重现性好、选择性高的SERS活性基底。对贵金属纳米粒子表面进行分子修饰,或者将贵金属纳米粒子与基质材料进行复合,可以组成融合贵金属纳米粒子的SERS活性并弥补其缺陷的新型SERS基底材料。本文综述了近年来基于贵金属纳米粒子常见的分子修饰和基质复合型SERS活性基底的研究进展。     

A review of developments and applications of thin‐film microextraction coupled to surface‐enhanced Raman scattering

Surface‐enhanced Raman scattering (SERS) greatly expands the applications of Raman spectroscopy and is a promising technique for food safety, environmental analysis, and public safety. Thin‐film microextraction (TFME) provides an efficient sample preparation method for SERS to improve its selectivity and detection efficiency. This review comprehensively describes the development and applications of SERS and TFME, including the history, mechanisim, and active substrate of SERS and the theory, device, forms, and practical applications of TFME. The applications of TFME‐SERS in food safety and environment monitoring are discussed, which could improve their advantages. TFME extracts and enriches the target analytes to eliminate the interfering substance, providing a facial way for SERS to analyze the target analytes in complex matrices. The development of TFME‐SERS technology not only expands the application range of TFME, but greatly improves the anti‐interference ability and detection sensitivity of SERS. Thus, the established methods are fast, convenient, and highly sensitive. This technology is potential to be applied in the on‐site and real‐time detection.     

等离子体金属纳米结构在SERS传感及可穿戴应力传感中的应用

等离子体金属(金、银)纳米结构因其特有的理化性能,被广泛应用于表面增强拉曼散射(Surface-enhanced Raman scattering,SERS)传感及可穿戴应力传感领域。其中,SERS是一种应用贵金属纳米材料增强拉曼散射信号的检测技术,该技术灵敏度高、特异性强,已被广泛用于生物医学、环境监测、食品药品检测等领域。随着电子检测技术和柔性电子材料的快速发展,柔性可穿戴传感技术也得到了快速发展,且取得了大量的研究成果。SERS检测技术主要依赖于贵金属纳米增强基底材料,而基于贵金属纳米结构的可穿戴传感元件对人体微应力、微应变的传感具有极高的灵敏度。SERS增强基底材料与可穿戴应力传感元件材料具有互通互用性,将贵金属纳米SERS基底应用于柔性可穿戴式检测,这是SERS检测技术比较新颖的、尚未深入研究的应用领域之一。该文综述了贵金属溶胶纳米结构的材料组成分类以及该类材料在SERS和可穿戴应力传感中的应用,并分析了胶体贵金属纳米结构组成及成分对SERS传感、可穿戴应力传感灵敏度、可重复性及稳定性的影响,最后展望了贵金属胶体纳米结构在SERS传感和柔性可穿戴应用中的发展趋势。     

SERS-based mercury ion detections: principles,strategies and recent advances

Mercury ion (Hg²⁺), known as one of the highly toxic and soluble heavy metal ions, is causing serious environmental pollution and irreversible damage to the health. It is urgent to develop some rapid and ultrasensitive methods for detecting trace mercury ions in the environment especially drink water. Surface-enhanced Raman scattering (SERS) is considered as a novel and powerful optical analysis technique since it has the significant advantages of ultra-sensitivity and high specificity. In recent years, the SERS technique and its application in the detection of Hg²⁺ have become more prevalent and compelling. This review provides an overall survey of the development of SERS-based Hg²⁺ detections and presents a summary relating to the basic principles, detection strategies, recent advances and current challenges of SERS for Hg²⁺ detections.     

Explosive and chemical threat detection by surface-enhanced Raman scattering: A review

Acts of terror and warfare threats are challenging tasks for defense agencies around the world and of growing importance to security conscious policy makers and the general public. Explosives and chemical warfare agents are two of the major concerns in this context, as illustrated by the recent Boston Marathon bombing and nerve gas attacks on civilians in the Middle East. To prevent such tragic disasters, security personnel must be able to find, identify and deactivate the threats at multiple locations and levels. This involves major technical and practical challenges, such as detection of ultra-low quantities of hazardous compounds at remote locations for anti-terror purposes and monitoring of environmental sanitation of dumped or left behind toxic substances and explosives. Surface-enhanced Raman scattering (SERS) is one of todays most interesting and rapidly developing methods for label-free ultrasensitive vibrational “fingerprinting” of a variety of molecular compounds. Performance highlights include attomolar detection of TNT and DNT explosives, a sensitivity that few, if any, other technique can compete with. Moreover, instrumentation needed for SERS analysis are becoming progressively better, smaller and cheaper, and can today be acquired for a retail price close to 10,000 US$. This contribution aims to give a comprehensive overview of SERS as a technique for detection of explosives and chemical threats. We discuss the prospects of SERS becoming a major tool for convenient in-situ threat identification and we summarize existing SERS detection methods and substrates with particular focus on ultra-sensitive real-time detection. General concepts, detection capabilities and perspectives are discussed in order to guide potential users of the technique for homeland security and anti-warfare purposes.     

Preparative isotachophoresis with surface enhanced Raman scattering as a promising tool for clinical samples analysis

A surface enhanced Raman scattering (SERS) spectrometry is an interesting alternative for a rapid molecular recognition of analytes at very low concentration levels. The hyphenation of this technique with advanced separation methods enhances its potential as a detection technique. Until now, it has been hyphenated mainly with common chromatographic and electrophoretic techniques. This work demonstrates for a first time a power of preparative isotachophoresis-surface enhanced Raman scattering spectrometry (pITP-SERS) combination on the analysis of model analyte (buserelin) in a complex biological sample (urine). An off-line identification of target analyte was performed using a comparison of Raman spectra of buserelin standard with spectra obtained by the analyses of the fractions from preparative isotachophoretic runs. SERS determination of buserelin was based on the method of standard addition to minimize the matrix effects. The linearity of developed method was obtained in the concentration range from 0.2 to 1.5 nmol L(-1) with coefficient of determination 0.991. The calculated limit of detection is in tens of pico mols per liter.     

表面增强拉曼光谱技术在食品检测中的应用研究进展

食品污染是危害公众健康和安全的重要问题,探究灵敏、快速、简单的技术,以便在痕量水平上检测污染物,对保障食品质量安全和风险评价具有十分重要的意义.表面增强拉曼光谱(SERS)是利用光与金、银等纳米结构材料相互作用产生很强的表面等离子激元共振效应,可显著增强吸附在纳米结构表面上分子的拉曼信号,以超灵敏获取样品自身或拉曼探针...     

Single-step multiplex detection of toxic metal ions by Au nanowires-on-chip sensor using reporter elimination

We have developed a Au nanowires (NWs)-on-chip surface-enhanced Raman scattering (SERS) multiplex sensor that can sensitively detect multiple toxic metal ions. Most importantly, the reporter elimination method simplified the detection procedure to a single step, which has been much desired for remote environmental monitoring. This sensor has several notable features. First, it shows high reproducibility based on well-defined single-crystalline Au NWs. Second, single-NW-sensors that can detect a specific metal ion are combined for multiplex sensing of metal ions. Third, when a sample solution is put onto the NWs-on-chip sensor, a decrease in the SERS signal of a specific NW-sensor identifies the target metal ion. Simple, rapid, sensitive and quantitative detection of metal ions becomes possible through the measurement of the SERS signals. We successfully detected ions of mercury (Hg(2+)), silver (Ag(+)), and lead (Pb(2+)) coexisting in the same solution by using this sensor.     

Minireview: Recent Advances in Surface-Enhanced Raman Scattering-Based Nucleic Acid Detection with Application to Pathogen Diagnosis

Surface-enhanced Raman scattering (SERS) is a promising analytical tool in nanoscale detection because of its high sensitivity and selectivity. This review focuses on recent advances in SERS-based detection of DNA and RNA. First, nanostructure-based SERS-active substrates are introduced. Using label-free and labeled SERS, target biomolecules such DNA, RNA and microRNA have been successfully detected. Finally, applications in pathogen diagnosis are discussed. The prospects and challenges of SERS-based bioanalysis are highlighted.     

Plasmonics nanoprobes: detection of single-nucleotide polymorphisms in the breast cancer BRCA1 gene

This paper describes the application of plasmonics-based nanoprobes that combine the modulation of the plasmonics effect to change the surface-enhanced Raman scattering (SERS) of a Raman label and the specificity of a DNA hairpin loop sequence to recognize and discriminate a variety of molecular target sequences. Hybridization with target DNA opens the hairpin and physically separates the Raman label from the metal nanoparticle thus reducing the plasmonics effect and quenching the SERS signal of the label. We have successfully demonstrated the specificity and selectivity of the nanoprobes in the detection of a single-nucleotide polymorphism (SNP) in the breast cancer BRCA1 gene in a homogenous solution at room temperature. In addition, the potential application of plasmonics nanoprobes for quantitative DNA diagnostic testing is discussed.