Determination of carbendazim in tea using surface enhanced Raman spectroscopy

Surface-enhanced Raman scattering(SERS) is applied to detect the concentration of carbendzim(CBZ) in tea leaves. Au colloid is selected and used for active surfaces, and the extraction conditions are optimized in the experiment. The linearity range for the SERS intensity and the concentration of CBZ is found to be0.5 to 8 mg kgà1. The detection limit for CBZ is 0.1 mg kgà1and its recovery in tea samples is 72.3%. The detection results for CBZ using this method are compared with those of HPLC, and no obvious difference can be found. In addition, by dripping the condensed Au colloid on the tea leaves, the proposed SERS approach could be used to the in-situ determination of the half life period of CBZ on tea leaves.     

表面增强拉曼光谱法快速检测中成药中吡罗昔康

建立中成药中吡罗昔康的表面增强拉曼光谱快速筛查方法。选取乙酸乙酯为提取剂,以20 mg石墨碳化黑+10 mg N-丙基乙二胺为净化剂,利用拉曼表面增强试剂对吡罗昔康拉曼光谱信号进行增强,进而对中成药中的吡罗昔康进行检测。该方法适用于胶囊、片剂、口服液、固体冲泡颗粒以及凉茶等多种中成药基质中吡罗昔康的检测,检出限为0.5~1.0 mg/kg。该方法检出限低,分析范围广,操作简便、快速,可用于中成药中违禁添加抗风湿解热镇痛类药物吡罗昔康的快速检测。     

DNA detection by dye labeled oligonucleotides using surface enhanced Raman spectroscopy

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基于表面增强拉曼光谱技术对医疗美容产品中正壬酸香草酰胺的快速检测

以银纳米线为拉曼基底,运用表面增强拉曼光谱技术(SERS)建立了对发热剂中正壬酸香草酰胺的检测方法。采用简便有效的两步滴加多元醇法制备了具有SERS活性的银纳米线,利用扫描电镜和紫外-可见光谱仪对银纳米线进行了表征。对正壬酸香草酰胺进行了SERS研究并对正壬酸香草酰胺的SERS谱带进行了归属。正壬酸香草酰胺的质量浓度在1～1.0×10^-8mg/L范围内与其在1588 cm^-1处的SERS特征峰强度有良好的线性关系,方法的最低检出浓度可达0.66 pg/L。对样品进行前处理后,运用加标回收法考察其回收率。该方法可以用于发热剂中正壬酸香草酰胺的检测。     

基于聚合物／金属纳米结构镶嵌型柔性基底的表面增强拉曼光谱技术

表面增强拉曼光谱（SERS）技术可极大增强传统拉曼光谱的信号强度,从而拓展拉曼光谱的应用范围．针对SERS技术在分析对象、分析环境的普适性和分析效率方面的限制,本文设计并发展了一种透明、柔性、自支撑SERS基底的制备、保存和使用方法．该基底由聚合物聚甲基丙烯酸甲酯（PMMA）和在其表面镶嵌的金属纳米结构组成,可以通过背入射法用于任意形貌样品表面的直接和在线检测．柔性SERS（Ag）基底在R6G水溶液表面的检测限小于1pmol／L．     

An optofluidic device for surface enhanced Raman spectroscopy

We have developed an optofluidic device that improves the sensitivity of surface enhanced Raman spectroscopy (SERS) when compared to other SERS approaches. This device has a pinched and step microchannel-nanochannel junction that can trap and assemble nanoparticles/target molecules into optically enhanced SERS active clusters by using capillary force. These SERS active clusters provide an electromagnetic enhancement factor of approximately 10(8). In addition, due to the continuous capillary flow that can transport nanoparticles/target molecules into the junction sites, the numbers of nanoparticles/target molecules and SERS active sites are increased. As a result, the detection limit of SERS for adenine molecules was better than 10 pM.     

On-chip ultra-thin layer chromatography and surface enhanced Raman spectroscopy

We demonstrate that silver nanorod (AgNR) array substrates can be used for on-chip separation and detection of chemical mixtures by combining ultra-thin layer chromatography (UTLC) and surface enhanced Raman spectroscopy (SERS). The UTLC-SERS plate consists of an AgNR array fabricated by oblique angle deposition. The capability of the AgNR substrates to separate the different compounds in a mixture was explored using a mixture of four dyes and a mixture of melamine and Rhodamine 6G at varied concentrations with different mobile phase solvents. After UTLC separation, spatially-resolved SERS spectra were collected along the mobile phase development direction and the intensities of specific SERS peaks from each component were used to generate chromatograms. The AgNR substrates demonstrate the potential for separating the test dyes with plate heights as low as 9.6 μm. The limits of detection are between 10(-5)-10(-6) M. Furthermore, we show that the coupling of UTLC with SERS improves the SERS detection specificity, as small amounts of target analytes can be separated from the interfering background components.     

Local monitoring of surface chemistry with Raman spectroscopy

The efficiency of Raman scattering from molecules in some nano-resonators can increase by many orders of magnitude. Sometimes, in Raman measurements carried out with such resonators, it is possible to record a spectrum from only a few (or even a single) molecules. In this contribution, we show that resonator-enhanced Raman scattering is very useful for analysis of the electrochemically formed carbon. Carbon material has been formed on the surface of the copper-modified silver electrode during the electrochemical reduction of CO₂. The Raman spectra measured were often from only a few carbon clusters. By the analysis of a large series of such spectra, we managed to identify large graphite-like rings and polyenes with various lengths. Some other applications of resonator-enhanced Raman scattering to local characterisation of electrode surfaces (e.g. studies of CO adsorption on gold) are also presented. Contribution to the Fall Meeting of the European Materials Research Society, Symposium D: 9th International Symposium on Electrochemical/Chemical Reactivity of Metastable Materials, Warsaw, 17th–21st September, 2007     

Single-molecule surface enhanced resonance Raman spectroscopy of the enhanced green fluorescent protein

In the present contribution, we demonstrated that surface-enhanced resonance Raman scattering spectra from single green fluorescent proteins (GFPs) were obtained. The most important findings are the direct detection of the conversion between a deprotonated and a protonated form of the chromophore at the single-molecule level via the corresponding vibrational fingerprints, and the fact that the enhanced green fluorescent protein (EGFP) also shows a high surface enhanced resonance Raman scattering (SERRS) signal. Our findings show the potential of the technique to study structural dynamics of protein molecules at a single-molecule level.     

Protein-nanoparticle labelling probed by surface enhanced resonance Raman spectroscopy

A benzotriazole dye has been attached to a heme protein via a Michael addition and the unique potential of surface enhanced resonance Raman scattering (SERRS) to provide informative in situ recognition of more than one label on one protein demonstrated.     

Reproducible discrimination between gram-positive and gram-negative bacteria using surface enhanced Raman spectroscopy with infrared excitation

The on time diagnostics of bacterial diseases is one of the essential steps in the foregoing treatment of such pathogens. Here we sought to present an easy to use and robust method for the discrimination between Gram-positive (Enterococcus faecalis and Streptococcus pyogenes) and Gram-negative (Acinetobacter baumannii and Klebsiella pneumoniae) bacterial genera based on surface enhanced Raman scattering (SERS) spectroscopy. The robustness of our approach lies in the novel method for the production of the SER substrate based on silver nanoparticles and their subsequent re-crystallization in solutions containing high concentrations of chloride ions. The method presented here could be an interesting alternative both to commonly used histochemical approaches and commercial SERS substrates.     

Immunoassay for P38 MAPK using surface enhanced resonance Raman spectroscopy (SERRS)

A micro-bead sandwich assay for P38 mitogen-activated protein kinase using surface enhanced resonance Raman spectroscopy (SERRS) detection is reported. Monoclonal capture antibodies were immobilised on a solid phase of magnetic micro-beads with secondary detection using a rhodamine-labelled antibody. Quantitative SERRS detection of the secondary antibody was possible with a limit of detection of 9.5 x 10(-12) mol dm(-3). The sandwich assay was quantitative and sensitive to 6 ng ml(-1). The mechanism of the SERRS detection in the immunoassay was investigated. The addition of SERRS aggregating agents causes the dissociation of the immuno-complex from the magnetic beads. Scanning electron microscopy images indicate that the colloidal suspension rather than adsorbed silver nanoparticles on the beads provide the SERRS signals, that the aggregate size is partially controlled and that there is some inhomogeneity in the distribution of organic matter on the nanoscale.     

Monitoring cell culture media degradation using surface enhanced Raman scattering (SERS) spectroscopy

The quality of the cell culture media used in biopharmaceutical manufacturing is a crucial factor affecting bioprocess performance and the quality of the final product. Due to their complex composition these media are inherently unstable, and significant compositional variations can occur particularly when in the prepared liquid state. For example photo-degradation of cell culture media can have adverse effects on cell viability and thus process performance. There is therefore, from quality control, quality assurance and process management view points, an urgent demand for the development of rapid and inexpensive tools for the stability monitoring of these complex mixtures. Spectroscopic methods, based on fluorescence or Raman measurements, have now become viable alternatives to more time-consuming and expensive (on a unit analysis cost) chromatographic and/or mass spectrometry based methods for routine analysis of media. Here we demonstrate the application of surface enhanced Raman scattering (SERS) spectroscopy for the simple, fast, analysis of cell culture media degradation. Once stringent reproducibility controls are implemented, chemometric data analysis methods can then be used to rapidly monitor the compositional changes in chemically defined media. SERS shows clearly that even when media are stored at low temperature (2–8 °C) and in the dark, significant chemical changes occur, particularly with regard to cysteine/cystine concentration.     

表面增强拉曼光谱在食品安全分析中的应用

拉曼光谱技术具有样品用量少、快速高效、无损分析等特点,表面增强拉曼光谱克服了常规拉曼光谱灵敏度低的缺点,可以获得更多物质结构信息,在现场快速筛查、检测和鉴别农兽残、限用或禁用添加剂分析检测中具有广阔的应用前景。本文综述了表面增强拉曼光谱在食品中农药残留、兽药残留和限/禁用添加剂检测中的研究进展,并展望了其发展前景。     

Quantitative monitoring of yeast fermentation using Raman spectroscopy

Compared to traditional IR methods, Raman spectroscopy has the advantage of only minimal interference from water when measuring aqueous samples, which makes this method potentially useful for in situ monitoring of important industrial bioprocesses. This study demonstrates real-time monitoring of a Saccharomyces cerevisiae fermentation process using a Raman spectroscopy instrument equipped with a robust sapphire ball probe. A method was developed to correct the Raman signal for the attenuation caused by light scattering cell particulate, hence enabling quantification of reaction components and possibly measurement of yeast cell concentrations. Extinction of Raman intensities to more than 50 % during fermentation was normalized with approximated extinction expressions using Raman signal of water around 1,627 cm^?1 as internal standard to correct for the effect of scattering. Complicated standard multi-variant chemometric techniques, such as PLS, were avoided in the quantification model, as an attempt to keep the monitoring method as simple as possible and still get satisfactory estimations. Instead, estimations were made with a two-step approach, where initial scattering correction of attenuated signals was followed by linear regression. In situ quantification measurements of the fermentation resulted in root mean square errors of prediction (RMSEP) of 2.357, 1.611, and 0.633 g/L for glucose, ethanol, and yeast concentrations, respectively.     

Efficient disc on pillar substrates for surface enhanced Raman spectroscopy

In this work, geometrical optimizations of Ag disc on pillar (DOP) hybrid plasmonic nanostructures were conducted and allowed us to achieve reproducible average enhancement factors of 1 × 10(9) and greater.     

Magnetic separation and immunoassay of multi-antigen based on surface enhanced Raman spectroscopy

A novel and highly sensitive immunoassay method based on surface enhanced Raman spectroscopy (SERS) and magnetic particles has been developed. This method exhibits great potential application in bio-separation and immunoassay.     

Time-dependent picture of the charge-transfer contributions to surface enhanced Raman spectroscopy

We reexamine the Herzberg-Teller theory of charge-transfer contributions to the theory of surface enhanced Raman scattering (SERS). In previous work, the Kramers-Heisenberg-Dirac framework was utilized to explain many of the observed features in SERS. However, recent experimental and theoretical developments suggest that we revise the theory to take advantage of the time-dependent picture of Raman scattering. Results are obtained for molecular adsorption on nanoparticles in both the strong confinement limit and the weak confinement limit. We show that the Herzberg-Teller contributions to the charge-transfer effect in SERS display a resonance at the molecule-to-metal or metal-to-molecule transition while retaining the selection rules associated with normal Raman spectroscopy (i.e., harmonic oscillator, as opposed to Franck-Condon overlaps). The charge-transfer contribution to the enhancement factor scales as Gamma(-4), where Gamma is the homogeneous linewidth of the charge-transfer transition, and thus is extremely sensitive to the magnitude of this parameter. We show that the Herzberg-Teller coupling term may be associated with the polaron-coupling constant of the surface phonon-electron interaction. A time-dependent expression for the Raman amplitude is developed, and we discuss the implications of these results for both metal and semiconductor nanoparticle surfaces.     

Temperature dependent surface enhanced Raman spectroscopy of piperidine in AgBr sol

The temperature dependent surface enhanced Raman (SER) spectra of piperidine in AgBr sols are presented with emphasis on the study of the intensity variation as the temperature increases. Most of the SER intensities decrease as the temperature increases. This is interpreted as due to the increase of the adsorption distance from the sol particle surface. It is also inferred from the various slopes of the decrease in intensity of various modes that there is variation of the SER effect in the dimension of a single bond, i.e. in 1.5 Å. Moreover, from the temperature dependent SER spectra, it is concluded that due to thermal agitation, both axial and equatorial piperidine molecules are adsorbed on the sol particle surface as the temperature increases. The energy difference between these two forms are calculated to be around 20 kcal/mol which is believed to be larger than that in solution due to the adsorption effect. Besides, two peaks at 1390 and 1231 cm⁻¹ show an anomalous positive thermal effect which could be due to the very complicated SERS mechanism. Finally, it is discussed that the temperature dependent SERS study possesses potentiality in revealing the chemical structure near the sol particle and noble metal electrode surfaces.