新型荧光光纤免疫磁珠流动分析系统研究（Ⅰ）

将荧光免疫分析技术、光纤传感技术、流动注射技术和免疫磁珠分离技术联用,建立了一种新型荧光光纤免疫磁珠流动分析系统,并采用荧光素异硫氰酸酯（FITC）对系统性能进行考察,结果表明该分析系统设计合理,性能可靠,在临床、环保等领域有广泛的应用前景。     

新型荧光光纤免疫磁珠流动分析系统研究（I）

将荧光免疫分析技术、光纤传感技术、流动注射技术和免疫磁珠分离技术联用,建立了一种新型荧光光纤免疫磁珠流动分析系统,并采用荧光素异硫氰酸酯（ＦＩＴＣ）对系统性能进行考察,结果表明该分析系统设计合理,性能可靠,在临床、环保等领域有广泛的应用前景。     

测定人血清白蛋白的荧光光纤流动免疫分析系统

用新型荧光光纤免疫传感流动分析测试系统,对人血清白蛋白（HSA）进行测试;将偶联于微晶纤维素表面形成的HSA固相抗体与待测HSA（抗原）、荧光标记抗原（FTTC－HSA）竞争性结合。经稀碱液处理,固相载体与抗原抗体复合物分离,用新型荧光光纤免疫传感流动分析系统测定解析液的荧光值,以求得待测HSA的含量;该法检出限为0．1g/L,日内RSD0．91％－6．4％,日间RSD1．8％－8．0％,加标回收率91％－120％;用该法测定注射用HSA,与临床检验常用的溴甲酚绿化对照,具有良好的相关性（r=0.9808)。     

倏逝波全光纤免疫传感器的开发及性能研究

利用倏逝波与荧光免疫分析原理,研制了一种倏逝波全光纤免疫传感器。该系统利用单多模光纤耦合器,使得激发光的传输、荧光的收集与传输均通过光纤来实现,减少了系统的光学分离元件,结构简单、紧凑、可实现仪器小型化;同时该系统光传递效率高、损耗低、信噪比高;单多模光纤耦合器和探头之间采用可拆卸的连接结构,可以实现多种样品的顺序检测。研究表明:光纤探头的最佳锥角度为0.37;系统对Cy5.5荧光染料的检测灵敏度可达到10-9mol/L;系统检测Cy5.5标记的羊抗大鼠IgG的最低浓度为10μg/L,检测时间为10min。     

微流控免疫芯片检测方法的研究进展

微流控免疫芯片以其微型化、高通量、快速检测及低消耗等优点成为近年来分析领域的研究热点. 检测技术是微流控芯片的重要组成部分之一. 本文重点综述了近年来微流控免疫芯片的微系统研究及相应的检测方法和技术, 包括电化学检测及荧光检测、紫外-可见吸收光谱检测、化学发光和生物发光检测、表面增强拉曼散射检测、光纤检测、表面等离子体共振谱检测、热透镜显微镜检测和比色检测等光学检测及其它新型检测方面的进展, 并展望了其发展前景.     

芯片式流通池用于顺序注射可更新表面荧光免疫法测定人血清中的IgG

采用芯片式流通池作为非均相免疫反应和原位固相荧光检测的场所,用双岔光纤将芯片式流通池与荧光光度计耦联,以双抗夹心式非均相免疫反应的模式,研究建立了测定人血清中IgG的顺序注射可更新表面非均相免疫分析新方法.     

小型连续注样电泳芯片及集成化的激光诱导荧光检测系统

通过在芯片进样通道上设计一微孔进样阀,将连续进样系统耦联到芯片上,实现了试样的连续注人.并以小型半导体激光器为光源,借助光纤耦合技术,通过在芯片上设计光纤通道,将自组装的光纤耦合激光诱导荧光检测系统集成到芯片上.还研制了一种小型集成化的连续注样-激光诱导荧光检测电泳芯片分析系统.     

荧光偏振免疫分析技术的研究进展

对荧光偏振免疫分析技术的研究进展作了详细的评述。介绍了荧光偏振免疫分析技术的基本原理和研究热点,评述了它在临床检验、环境与食品监测和农药残留量分析等领域中的应用,对荧光偏振免疫分析方法的优缺点作了总结,引文献45篇。     

新型荧光光纤免疫磁珠流动分析系统研究(Ⅱ)

采用荧光素异硫氰酸酯 ( FITC)对新建立的荧光光纤免疫磁珠流动分析系统参数及性能进行了考察。不同泵速下测定流量的恒定性 ,其 RSD为 0 .2 3%～0 .76 % ( n=2 4 ) ;对 1× 1 0 -5～ 1× 1 0 -2 mol·L-1FITC溶液 ,线性相关系数 0 .986～ 0 .999;连续测定 1 2次 ,RSD为 0 .73%～ 0 .95% ;2 h内基线不产生飘移。     

环境激素邻苯二甲酸二丁酯免疫检测Ⅱ——抗体的制备

邻苯二甲酸二丁酯(DBP)半抗原衍生物通过偶氮键与载体蛋白BSA偶合后作为免疫原,免疫新西兰大白兔,得到合格的DBP抗血清,双向琼脂扩散方法测定血清效价为1∶32～1∶64,间接荧光免疫法检测效价为1∶6 400～1∶12 800。通过兔颈部采血、抗血清纯化,得到的抗邻苯二甲酸二丁酯多克隆抗体IgG冻干后,分装在-20℃低温保存。建立了间接荧光免疫法检测纯化抗体的方法。间接竞争荧光免疫法考察交叉反应试验结果显示,纯化抗邻苯二甲酸二丁酯抗体与邻苯二甲酸二甲酯、邻苯二甲酸二乙酯、邻苯二甲酸二丙酯、邻苯二甲酸二环己酯、邻苯二甲酸二戊酯、邻苯二甲酸二(2-乙基己基)酯等邻苯二甲酸酯类环境激素的交叉反应均小于10%。制备的抗体可应用于环境激素DBP的荧光免疫分析。     

A ratiometric approach for pH optosensing with a single fluorophore indicator

A new fiber-optic prototype of luminometer has been designed in order to perform ratiometric-based measurements for optical sensing purposes. The coupling of a pH-selective sensing phase to the fiber-optic prototype has been evaluated for robust pH optosensing in drinking water. The pH-sensitive material has been synthesized by entrapping a pH-sensitive luminescent indicator (mercurochrome) in a sol-gel inorganic matrix. The pH optosensing is based on the detection of pH-induced reversible changes in the mercurochrome fluorescent emission and in the light reflected by the sensing phase.The instrument has been constructed using low-cost and simple optoelectronic components. The active phase was excited by means of a visible 470 nm high intensity light emitting diode (LED). The radiant power of the LED was modulated using a sinusoidal function so that scattered light due to light sources of different frequency than the modulating signal (e.g. sunlight) can be easily removed by adequate electronic filtering of the emission signal. Both the fluorescence emission from the dye and the sensing phase reflected light were collected in a bifurcated fiber-optic to allow the ratiometric measurement.Two different ratiometric approaches have been evaluated. The analytical performance of the pH optrode using both measurement methods have been compared, between them and with simple fluorescence intensity measurements, in terms of sensitivity, measurement range, response time, repeatability and insensitivity to changes in excitation light intensity.The applicability of the developed pH optrode and methods has been tested for pH analysis in tap and bottled still mineral water samples. The results obtained showed good agreement with the corresponding pH values provided by a commercial glass electrode.In this work, pH was selected as a model analyte to evaluate the performance of the proposed methodology, although other optical sensors for different applications/analytes could benefit of this approach.     

Development of a lateral flow fluorescent microsphere immunoassay for the determination of sulfamethazine in milk

The fluorescent microsphere has been increasingly used as detecting label in immunoassay because of its stable configuration, high fluorescence intensity, and photostability. In this paper, we developed a novel lateral flow fluorescent microsphere immunoassay (FMIA) for the determination of sulfamethazine (SMZ) in milk in a quantitative manner with high sensitivity, selectivity, and rapidity. A monoclonal antibody to SMZ was covalently conjugated with the carboxylate-modified fluorescent microsphere, which is polystyrene with a diameter of 200 nm. Quantitative detection of SMZ in milk was accomplished by recording the fluorescence intensity of microspheres captured on the test line after the milk samples were diluted five times. Under optimal conditions, the FMIA displays a rapid response for SMZ with a limit of detection of as low as 0.025 ng mL^?1 in buffer and 0.11 μg L^?1 in milk samples. The FMIA was then successfully applied on spiked milk samples and the recoveries ranged from 101.1 to 113.6 % in the inter-batch assay with coefficient of variations of 6.0 to 14.3 %. We demonstrate here that the fluorescent microsphere-based lateral flow immunoassay (LFIA) is capable of rapid, sensitive, and quantitative detection of SMZ in milk.

A fluorescent polymer dots positive readout fluorescent quenching lateral flow sensor for ractopamine rapid detection

A fluorescent polymer dots positive readout and sensitive lateral flow assay (LFA) based on fluorescent quenching has been developed to detect ractopamine (Rac), a chemical residue in food, harmful to human health. Compared with traditional LFA strips, these fluorescent quenching LFA (FQLFA) strips provide a positive correlation method that allows users to obtain results from a weak fluorescent signal. The immunoassay strip scheme is based on the fact that fluorescent polymer dots (FPDs) in close proximity to gold nanoparticles (AuNPs) represent a strong fluorescent quenching. We show that the FQLFA strips can be used as a source to quantitatively analyze Rac in phosphate buffers (PB), swine urine and muscle tissue samples. The lowest detection limitation of the FQLFA was 0.16 ng mL⁻¹. Our results indicated that this novel scheme was more suitable for rapid detection of small molecules.     

Novel application of Ag nanoclusters in fluorescent imaging of human serum proteins after native polyacrylamide gel electrophoresis (PAGE)

We have developed a novel application for DNA oligonucleotide-stabilized Ag nanoclusters in fluorescent imaging of human serum proteins after native polyacrylamide gel electrophoresis (PAGE). Oligonucleotide-stabilized Ag nanoclusters were used as fluorescent probes for direct detection of proteins after native PAGE. Some relatively low-abundance proteins, such as α-1-antichymotrypsin (ACT) and α-2-glycoprotein 1, zinc (ZAG) were easily detected by oligonucleotide-stabilized Ag nanocluster-based fluorescent imaging and identified by MS and MS/MS techniques, without the need of expensive antibodies or tedious immunoassay procedures. The pH condition for the oligonucleotide-stabilized Ag nanocluster solution was optimized and the possible mechanism of interaction between proteins and DNA oligonucleotide-stabilized Ag nanoclusters was analyzed. As a novel fluorescent detection method it is simple, fast, nontoxic and sensitive, and it shows great analytical potential in proteome research and in biochemistry.     

Wide-field lensless fluorescent microscopy using a tapered fiber-optic faceplate on a chip

We demonstrate lensless fluorescent microscopy over a large field-of-view of ~60 mm(2) with a spatial resolution of <4 μm. In this on-chip fluorescent imaging modality, the samples are placed on a fiber-optic faceplate that is tapered such that the density of the fiber-optic waveguides on the top facet is >5 fold larger than the bottom one. Placed on this tapered faceplate, the fluorescent samples are pumped from the side through a glass hemisphere interface. After excitation of the samples, the pump light is rejected through total internal reflection that occurs at the bottom facet of the sample substrate. The fluorescent emission from the sample is then collected by the smaller end of the tapered faceplate and is delivered to an opto-electronic sensor-array to be digitally sampled. Using a compressive sampling algorithm, we decode these raw lensfree images to validate the resolution (<4 μm) of this on-chip fluorescent imaging platform using microparticles as well as labeled Giardia muris cysts. This wide-field lensfree fluorescent microscopy platform, being compact and high-throughput, might provide a valuable tool especially for cytometry, rare cell analysis (involving large area microfluidic systems) as well as for microarray imaging applications.     

A versatile platform for highly sensitive detection of protein: DNA enriching magnetic nanoparticles based rolling circle amplification immunoassay

A novel rolling circle amplification (RCA) immunoassay based on DNA enriching magnetic nanoparticles and assembled fluorescent DNA nanotags, magnetic nanoparticles-RCA immunoassay, is developed as a versatile fluorescence assay platform for highly sensitive proteins detection.     

Simple fiber-optic sensor based on immobilized β-cyclodextrin

A bifurcated fiber-optic sensor is reported that uses immobilized β-cyclodextrin (β-CD) as the sensing agent. The sensor forms moderately selective inclusion complexes between β-CD and many guest molecules. On complexation, a weakly fluorescent molecule often exhibits a significant increase in emission yield. The linear dynamic range of this sensor extends well over 2.5 orders of magnitude. Detection limits (signal-to-noise ratio=3) are as low as 4 nM for sample volumes as small as 15μl (60 fmol). This is an improvement of over two orders of magnitude compared with detection with a conventional “bare” fiber-optic probe. The sensor is simple to fabricate, has a useful lifetime of at least 5 months, is suitable for laser or arc lamp excitation sources and can be reconditioned rapidly.     

A solid-phase fluorescent biosensor for the determination of phenolic compounds and peroxides in samples with complex matrices

A solid-phase fluorescent biosensor for the determination of phenolic compounds (simple substituted phenols and catecholamines) and peroxides has been developed. The biosensor has a simple construction and the analytical signal is measured directly in a biosensitive layer {peroxidase-chitosan} on the sensor surface. This approach allowed analyzing samples with complex matrices (including water-insoluble samples and nontransparent solutions) without their preliminary pretreatment. Two novel fluorescent indicator reactions for the determination of the above-mentioned analytes in wide concentration ranges (from nmol l^?1 to mm l^?1) which provided an analytical signal registration on a solid phase were proposed. The developed sensor was applied successfully for the analysis of urine, cosmetics, pharmaceuticals preparations, etc.