基于纳米信号标签的表面增强拉曼散射在病原菌检测中的应用

表面增强拉曼散射(surface-enhanced Raman scattering,SERS)技术由于其灵敏度高、检测速度快、高特异性和无损等优点,在病原菌检测领域受到了广泛的关注。主要总结了近年来基于纳米信号标签的SERS方法在检测病原菌领域中的研究进展,并介绍了多功能SERS检测平台的构建及在病原菌检测中的应用。最后,对SERS这一技术作为实时、高效和可靠的病原菌检测工具的未来发展进行了展望。     

表面增强拉曼光谱在DNA检测中的应用

随着光学技术的发展,表面增强拉曼光谱(SERS)作为一种新兴的技术被逐渐应用于生物医学领域。SERS波谱作为一种振动波谱,能够反应被测物质的内部信息,具有指纹识别特征;具备高灵敏度、高效能的特点,且能实现复合样本的同时测定;带标记的SERS技术能进一步提高SERS检测的特异性。目前SERS技术已被广泛用于体内外DNA、蛋白分子的检测,为生物分子的分析检测提供了一种崭新、高效的手段。     

表面增强拉曼光谱技术在肿瘤病理中的应用

表面增强拉曼散射（Surface-enhanced Raman Scattering,SERS）技术作为鉴定生物分子种类最有力的分析工具之一,具有灵敏度高、特异性强、稳定性好及检测条件温和等优点。目前,SERS技术在肿瘤病理领域的应用尚处于起步阶段,但已显现出良好的应用前景和发展空间。该文简要介绍了SERS的机理、特性及活性基底,并对SERS技术在肿瘤病理的研究进展、局限性及潜在应用价值方面做较为全面的综述。     

鼻咽癌细胞组织与血液的SERS光谱研究进展

基于表面增强拉曼光谱(SERS)技术对于人体细胞组织与血液的检测和研究,SERS光谱技术能够发现正常组织与病变组织的差异性,为医学临床上实现癌症的早期诊断提供了科学依据。由于鼻咽癌不具有明显的病变特征、病灶的位置难以通过常规医学手段检测。因此利用SERS光谱技术,应用于鼻咽癌细胞组织与血液的研究,可提高鼻咽癌患者的生存率。对鼻咽癌细胞组织与血液SERS光谱分析和诊断的探索研究,有助于SERS光谱技术发展成为一种在生物医学领域中的分析检测手段,在医学临床诊断上具有潜在的应用前景。     

在银溶胶中甘氨酸和甘氨酸二肽的表面增强拉曼散射

甘氨酸及Gly-Gly和Gly-L-Pro二肽的表面增强拉曼散射谱与溶液内的普通拉曼谱的对比研究表明,银胶对COO、NH_2、C-N和C-C基团的振动有明显的增强.对CH_2基团无增强.Gly-Gly的SERS与pH有关,接近中性pH值时增强效果好,在酸性和碱性溶液内效果差.在 Gly-L-Pro的SERS谱中有强的酰胺Ⅰ带,而 Gly-Gly则几乎观察不到.     

SERS标记方法在生化分析中的应用

表面增强拉曼散射(SERS)标记方法结合现代生物标记方法与SERS光谱技术,使吸附到金或银等贵金属表面的标记分子的拉曼信号显著增强,并将其作为标记示踪信号,具有生物兼容性好、灵敏度高、分子特征性强和快速简便等优点,已成为新颖的标记示踪技术的研究热点之一。本文综述近年来SERS标记技术应用于基因分析、蛋白质检测、微生物检测、肿瘤靶向和小分子物质的最新进展,着重介绍蛋白质和小分子物质的检测,并展望了今后的发展方向。     

基于固态基底的SERS免疫检测新方法研究

目的:通过引入新型表面增强拉曼散射(SERS)检测探针(Au-DTNB-Tyr NPs)和金标银染技术,建立基于固态硅片基底的SERS免疫检测新技术。方法:羊抗人IgM-HRP作为检测抗体,在硅片基底上检测不同浓度的人IgM,HRP催化SERS检测探针沉积,利用金标银染技术增强SERS信号。结果:所建立的SERS免疫检测新方法检测人IgM的检测限为10 pg/mL,且SERS信号强度与人IgM浓度具有良好的线性关系(R2=0.993)。结论:基于硅片基底的SERS免疫检测新技术可高灵敏地定量检测人IgM,为实现固态硅片基底对多种抗原的高通量集成化检测奠定了基础。     

基于银纳米棒的表面增强拉曼基底探究土霉素对植物乳杆菌的影响

【背景】土霉素属四环素类抗生素,在医疗制药和动物养殖行业应用广泛。抗生素的滥用与残留极易导致环境中的益生菌产生耐药,各类益生菌通过食物进入机体后,可将耐药基因转移给致病菌。目前的耐药菌株筛选方法耗时较长,最小抑菌浓度测定结果也可能存在偏差,而且无法在抗菌机理及耐药机制方面提供线索。【目的】采用表面增强拉曼光谱（surface enhanced Raman spectroscopy,SERS）技术探究土霉素与植物乳杆菌之间的相互作用,以期为微生物耐药菌株的快速筛选提供理论基础,并为研究抗菌机理及耐药机制提供思路及方法。【方法】组装银纳米棒与石英后得到一种具有良好、稳定的SERS增强效应的固相基底;在植物乳杆菌菌液中加入不同浓度土霉素后各自分别孵育30、60和90 min,利用组装好的固相基底对细菌细胞进行SERS信号测定,拉曼光谱的出峰位置和峰强度变化可以体现不同土霉素浓度及作用时间条件下植物乳杆菌细胞成分的差异,可进一步推断土霉素对植物乳杆菌生长的影响。【结果】0.5×MIC土霉素会造成SERS光谱强度的降低;1.0×MIC土霉素作用90 min后,SERS在1 612、1 630 c...     

银胶浓度对电穿孔获取细胞内表面增强拉曼光谱的影响

探究了银胶浓度对于电穿孔导入银纳米粒子获取细胞内表面增强拉曼光谱(SERS)的影响.对6组含有不同浓度银胶的鼻咽癌细胞C666进行电穿孔,测量电穿孔后活细胞内表面增强拉曼光谱.以测得的SERS信号、光谱强度积分值和谱线重复性为指标,研究银胶浓度对电穿孔获取细胞内SERS的影响,对电穿孔后活性C666细胞内SERS平均光谱进行初步谱峰归属.在脉冲电场强度875 V/cm,脉冲持续时间1 ms,电脉冲2次的条件下,每500μl电击缓冲液中含有50μl银胶时测得的细胞内SERS光谱信噪比高,且光谱具有较好的重复性.结果说明,正确选择银胶浓度可以提高电穿孔-SERS效果,获取高质量的活细胞内SERS信号.此研究有助于扩展表面增强拉曼光谱的应用,包括实时检测分析活细胞内生化成分及分布,实时监测细胞生化变化过程等.     

胃癌血清的表面增强拉曼光谱研究

表面增强拉曼光谱技术在癌症诊断领域已经有了广泛的研究和应用,本文利用金纳米溶胶为增强基底,采用便携式近红外拉曼光谱系统,对89例胃癌患者及正常人血清样本进行了SERS光谱探测。结果表明,血清的特征峰主要归属于氨基酸,其次是核酸、糖类及脂类。相比于正常人血清SERS光谱,胃癌血清中归属于核酸的特征峰强度都较高,大部分归属于蛋白质的特征峰强度较低,与医学研究结论相符。说明SERS技术可以有效地反映胃癌患者和正常人血清的差异,为后期SERS技术快速诊断胃癌提供了实验基础。     

Characterization of multilayer-enhanced surface-enhanced raman scattering (SERS) substrates and their potential for SERS nanoimaging

Multilayer gold surface-enhanced Raman scattering (SERS) substrates, which consist of continuous gold films that are separated by self-assembled monolayers (SAMs) and cast over 430-nm diameter silica nanospheres on a glass slide, have been evaluated as a means of further enhancing the SERS signals produced from conventional metal film over nanostructure substrates. Evaluation of the effect of various SAMs, with different terminal functional groups, on the SERS enhancement factor were measured and compared to conventional single-layer gold film over nanostructure substrates, revealing relative enhancements as great as 22.4-fold in the case of 2-mercapto-ethanol spacer layers. In addition to evaluation of the effect of different terminal functionalities, the effect of spacer length was also investigated, revealing that the shorter chain length alcohols provided the greatest signals. Employing the optimal SERS multilayer geometry, SERS nanoimaging probes were fabricated and the SERS enhancement factor and variability in enhancement factor were measured over the SERS active imaging area, providing absolute enhancements similar to previous silver-based SERS nanoimaging probes (i.e., 1.2 × 10⁸). Varying the size of the multilayer gold islands that were deposited on the tip of the SERS active nanoimaging probe, it is possible to tune the optimal SERS excitation wavelength accurately and predictably over the range of approximately 450 to 600 nm, without coating the entire surface of the probe and significantly reducing the transmission and resulting signal-to-noise ratio of the images obtained.     

Surface‐enhanced Raman spectroscopy for on‐site analysis: A review of recent developments

On‐site identification and quantification of chemicals is critical for promoting food safety, human health, homeland security risk assessment, and disease diagnosis. Surface‐enhanced Raman spectroscopy (SERS) has been widely considered as a promising method for on‐site analysis due to the advantages of nondestructive, abundant molecular information, and outstanding sensitivity. However, SERS for on‐site application has been restricted not only by the cost, performance, and portability of portable Raman instruments, but also by the sampling ability and signal enhancing performance of the SERS substrates. In recent years, the performance of SERS for on‐site analysis has been improved through portable Raman instruments, SERS substrates, and other combined technologies. In this review, popular commercial portable Raman spectrometers and the related technologies for on‐site analysis are compared. In addition, different types of SERS substrates for on‐site application are summarized. SERS combined with other technologies, such as electrochemical and microfluidics are also presented. The future perspective of SERS for on‐site analysis is also discussed.     

表面增强拉曼光谱技术在微生物鉴定中的应用进展

拉曼光谱自20世纪20年代被发现以来,经过近90年的发展,产生了许多分支。其中表面增强拉曼光谱是利用被测物质与粗糙金属表面的相互作用来提高拉曼光谱的信噪比,从而得到敏感度和精确度更高的图谱,可以将样品在不经过预处理的情况下对其进行快速检测。本文综述了表面增强拉曼光谱技术的原理、分类及鉴定特点,总结了该技术在食品、化学、医药、工业、病原等微生物学科的临床应用,进一步阐述了研究该技术的必要性和应用前景,旨在为从事该领域的科研人员提供参考依据。     

Bioanalytical application of surface‐ and tip‐enhanced Raman spectroscopy

Due to its fingerprint specificity and trace‐level sensitivity, surface‐enhanced Raman spectroscopy (SERS) is an attractive tool in bioanalytics. This review reflects the research in this highly interesting topic of the last 3–4 years. The detection of the SERS signature of biomolecules up to microorganisms and cells is introduced. Labeling using modified nanoparticles (SERS tags) is also introduced. In order to establish biomedical applications, SERS analysis is performed in complex matrices such as body fluids. Furthermore, the SERS technique is combined with other methods such as microfluidic devices for online monitoring and scanning probe microscopy (i.e. tip‐enhanced Raman spectroscopy, TERS) to investigate nanoscaled features. The present review illustrates the broad application fields of SERS and TERS in bioanalytics and shows the great potential of these methods for biomedical diagnostics.     

Surface-Enhanced Raman Scattering from Individual Au Nanoparticles on Au Films

We investigated the effect of optical thick metal films on the surface-enhanced Raman scattering (SERS) activity of individual Au nanoparticle (NP) monomers and dimers. The film presence is revealed to be positive for the SERS activity of individual NP monomers, while it is not always positive for the electromagnetic enhancement at hot spots for SERS of the dimer, which is explained well by our numerical simulations. The polarized SERS signals from the NP dimer are elucidated well in terms of the plasmon hybridization of the dimer. SERS contributions both from individual NP surfaces and the junction between the NP and its supporting substrate were discussed as well.     

Protein separation and identification using magnetic beads encoded with surface-enhanced Raman spectroscopy

This article presents a prototype of a surface-enhanced Raman spectroscopy (SERS)-encoded magnetic bead of 8 μm diameter. The core part of the bead is composed of a magnetic nanoparticle (NP)-embedded sulfonated polystyrene bead. The outer part of the bead is embedded with Ag NPs on which labeling molecules generating specific SERS bands are adsorbed. A silica shell is fabricated for further bioconjugation and protection of SERS signaling. Benzenethiol, 4-mercaptotoluene, 2-naphthalenethiol, and 4-aminothiophenol are used as labeling molecules. The magnetic SERS beads are used as substrates for protein sensing and screening with easy handling. As a model application, streptavidin-bound magnetic SERS beads are used to illustrate selective separation in a flow cytometry system, and the screened beads are spectrally recognized by Raman spectroscopy. The proposed magnetic SERS beads are likely to be used as a versatile solid support for protein sensing and screening in multiple assay technology.     

Rapid detection of food- and waterborne bacteria using surface-enhanced Raman spectroscopy coupled with silver nanosubstrates

Development of rapid and sensitive methods to detect pathogens is important to food and water safety. This study aimed to detect and discriminate important food- and waterborne bacteria (i.e., Escherichia coli O157:H7, Staphylococcus epidermidis, Listeria monocytogenes, and Enterococcus faecelis) by surface-enhanced Raman spectroscopy (SERS) coupled with intracellular nanosilver as SERS substrates. An in vivo molecular probing using intracellular nanosilver for the preparation of bacterial samples was established and assessed. Satisfactory SERS performance and characteristic SERS spectra were obtained from different bacterial samples. Distinctive differences were observed in SERS spectral data, specifically in the Raman shift region of 500–1,800 cm⁻¹, and between bacterial samples at the species and strain levels. The detection limit of SERS coupled with in vivo molecular probing using silver nanosubstrates could reach the level of single cells. Experiments with a mixture of E. coli O157:H7 and S. epidermidis for SERS measurement demonstrate that SERS could be used for classification of mixed bacterial samples. Transmission electron microscopy was used to characterize changes of morphology and cellular composition of bacterial cells after treatment of intracellular nanosilver. The results indicate that SERS coupled with intracellular silver nanosubstrates is a promising method for detection and characterization of food- and waterborne pathogenic and non-pathogenic bacterial samples.     

Interface-Induced Ag Monolayer Film for Surface-Enhanced Raman Scattering Detection of Water-Insoluble Enrofloxacin

Water-insoluble molecules usually show poor surface-enhanced Raman scattering (SERS) signals, because they are hardly adsorbed on the surface of most commonly used SERS substrates, such as aqueous Ag or Au colloids. In this work, a highly sensitive and reproducible Ag monolayer film (Ag MLF) SERS substrate prepared by self-assembly of Ag nanoparticles (Ag NPs) on water/oil interface can realize the trace SERS detection of water-insoluble enrofloxacin. The positively charged phase transfer catalyst can transfer the negatively charged Ag nanoparticles in aqueous solution to the water/oil interface. At the same time, the water-insoluble enrofloxacin can also be attracted to the interface because of its lipophilic group. The type/volume of the oil phase and phase transfer catalyst and the vortex mixing time were all optimized to maximize the SERS effect of Ag MLF. Results showed that trace water-insoluble enrofloxacin can be identified by Ag MLF and its detection sensitivity was significantly improved. The proposed novel Ag MLF can be further applied to detect other water-insoluble molecules in SERS.