化学发光二维两点检测微流控芯片系统

化学发光二维两点检测微流控芯片系统设计集成了一种可用于分离检测氨基酸、多肽和蛋白质等复杂样品的化学发光二维两点检测微流控芯片系统.该系统采用双检测器同时检测第一维和第二维的分离峰信息,可获得样品的二维分离谱图,满足了对多种复杂结构微流控芯片分离特性进行研究的要求.     

纸芯片微流控技术的发展及应用

纸芯片微流控技术是一种新型微流控技术。相比于以玻璃、石英、高聚物等为基底的传统微流控芯片,纸芯片具有成本低、易操作、可携带、耗样量小等优点。该文介绍了纸芯片的发展及常用的制作方法,并举例说明了光度法、荧光法、化学发光及电化学发光法和电化学法在纸芯片检测中的应用;归纳了纸芯片技术在临床诊断、环境监控以及食品安全分析等方面的应用;最后对纸芯片微流控的应用前景进行了展望。     

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.     

化学发光联用技术在兽药残留分析中的应用进展

本文对近年来化学发光联用技术在兽药残留分析中的应用进展进行了评述,主要包括化学发光免疫分析、分子印迹-化学发光分析、微流控芯片-化学发光检测等,引用文献31篇.     

高灵敏的化学发光微流控电泳芯片检测系统的研究

化学发光检测具有灵敏度高、光学构型简单和背景低等特点,非常适合于毛细管电泳和微流控芯片检测.毛细管电泳-化学发光检测方法已成功地用于氨基酸、蛋白质、ATP、过渡金属离子和镧系元素离子等的检测,对金属离子的检测限达到l0¹²mol/L.     

微流控芯片荧光检测系统的研究进展北大核心CSCD

微流控芯片又称芯片实验室,具有检测高效、消耗试剂少、高通量、微型化和集成化等特点,许多检测方式(如光学检测、电化学检测)已经集成于微流控芯片上,而荧光检测是微流控芯片检测技术的常见手段之一。为此,在介绍了荧光检测技术的基本原理和光路结构的基础上,从激发光源、光传辅助手段和检测器等方面综述了微流控芯片荧光检测系统的研究进展,并对其发展进行了展望(引用文献55篇)。     

微流控芯片化学发光检测系统的设计及其应用

通过标准光刻、化学刻蚀及热键合技术制作微流控电泳芯片,在芯片上集成流通式化学发光检测池,实现样品的芯片电泳分离化学发光检测.采用双(2,4,6-三氣苯基)草酸酯(TCPO)-过氧化氢化学发光体系,通过微泵输送化学发光试剂.单酰化苯并氨基酸和单酰化肌氨酸在该系统中得以成功地分离检测,其检测限分别达到2.8和3.2 μmol/L.     

微流控芯片直接化学发光检测方法研究

基于Ru(bipy)₃²⁺的化学发光反应,建立了一种新型微流控芯片化学发光检测方法.以草酸为研究对象,探讨了表面活性剂CTAB的浓度、化学发光反应酸度以及Ru(bipy)₃²⁺浓度等因素对峰形以及检测灵敏度和重现性的影响.草酸的线性范围为1.0×10^-4~5.0×10^-6mol/L,检测限达到2.0×10^-6mol/L.该方法的建立为微流控芯片分离检测某些有机酸、药物、环境物质及核酸等提供了新方法.     

微流控玻璃芯片毛细管电泳鞘流型紫外光度检测系统

目前,微流控芯片分析系统中常用的检测方法有激光诱导荧光检测、质谱、化学发光、电化学和光度法等.其中应用最多的是激光诱导荧光检测器,但其所测样品大部分需要衍生.     

微流控芯片操纵传输及实时监测单细胞量子释放

微流控芯片技术用于细胞生化分析已引起了广泛关注.Harrison等首次在微流控芯片上对细胞群体进行操纵、传输及反应.yang等在微流控芯片上操纵细胞群体的排列,并用荧光检测细胞群体摄取钙的反应.至今还未见到微流控芯片对单个细胞进行操纵传输、定位及实时监测的报道.单细胞受激释放的监测对探索生物体神经传导具有重要意义.     

基于单螺旋微流控芯片的细菌气溶胶的高效富集

设计了一种单螺旋通道的聚二甲基硅氧烷(Poly(dimethylsiloxane),PDMS)微流控芯片,用于副溶血性弧菌气溶胶的快速有效富集。该芯片的特征在于其通道呈螺旋分布,且通道内部含有均匀分布的鱼骨形结构。结果表明,在不同富集时间段内,采用该芯片方法捕获的细菌总数均远高于传统落板法。对于传统落板法无法有效捕获的低浓度样本(10~4CFU/mL)的缺陷,该方法的优势在于:芯片内部的螺旋通道可增大对气溶胶中微生物的离心力;鱼骨形结构的设计增加了待测样品与芯片内壁间的接触几率。此外,以无鱼骨形的螺旋芯片作为对照,验证了鱼骨形结构对于高效富集的意义。此芯片设计巧妙、易于制备、高效便携、富集效果较好,在气溶胶污染严重的水产加工等场所具有较大的应用前景。     

微流控纸芯片在环境分析检测中的应用

近年来,微流控纸芯片由于低成本、便携化、检测快等优点,在需要快速检测的环境分析领域中展现出了巨大的应用前景。该综述从微流控纸芯片在环境分析中的应用角度,总结归纳了微流控纸芯片在环境分析中的最新研究进展,并展望了其在未来的发展趋势与挑战。论文内容引用150余篇源于科学引文索引(SCI)与中文核心期刊中的相关论文。该综述包括微流控纸芯片在环境检测中的优势与制造方法介绍;电化学法、荧光法、比色法、表面增强拉曼法、集成传感法等基于纸芯片的先进分析方法介绍;根据环境分析目标物种类,如重金属离子、营养盐、农药、微生物、抗生素以及其他污染物等,对纸芯片的最新应用现状进行了举例评述;基于微流控纸芯片的环境分析研究的未来发展趋势和前景展望。通过综述近期相关研究,表明微流控纸芯片从提出至今虽然只有十几年的发展历程,但其在环境分析研究中的发展却十分迅速。微流控纸芯片可以根据不同的环境条件和检测要求灵活选择制作与分析方法,实现最佳的检测效果。但是微流控纸芯片也面临一些挑战,如纸张机械强度不足、流体控制程度不佳等问题。这些问题指出了微流控纸芯片在环境检测领域的发展趋势,相信随着不断深入的研究,纸芯片将会在未来的环境分析中发挥更大作用。     

On-chip sample pretreatment using a porous polymer monolithic column for solid-phase microextraction and chemiluminescence determination of catechins in green tea

A porous polymer monolithic column for solid-phase microextraction and chemiluminescence detection was integrated into a simple microfluidic chip for the extraction and determination of catechins in green tea. The porous polymer was prepared by poly(glycidyl methacrylate-co-ethylene dimethacrylate) and modified with ethylenediamine. Catechins can be concentrated in the porous polymer monolithic column and react with potassium permanganate to give chemiluminescence. The microfluidic chip is reusable with high sensitivity and very low reagent consumption. The on-line preconcentration and detection can be realized without an elution step. The enrichment factor was calculated to be about 20 for catechins. The relative chemiluminescence intensity increased linearly with concentration of catechin from 5.0 × 10(-9) to 1.0 × 10(-6) M and the limit of detection was 1.0 × 10(-9) M. The proposed method was applied to determine catechin in green tea. The recoveries are from 90% to 110% which benefits the actual application for green tea samples.     

基于微流控芯片的微阵列分析

微阵列芯片具有高通量、微量化和自动化等特点,已经在很多领域得到广泛应用。但是微阵列芯片仍然具有不足之处,如所需设备昂贵、分析时间较长、灵敏度不高、多样品平行分析能力不足等。微流控芯片微米级的通道具有相对较大的比表面积和较短的扩散距离,能够显著加快分析速度、提高检测效率、增强分析性能,并且能够加工大量的平行通道用于多样品分析。目前已经有大量文献报道将微流控芯片和微阵列芯片相结合,发展了独特的杂交方式并在实验和理论上分别证明了两者相结合的优势,本文综述了将微流控芯片技术应用于微阵列分析的研究进展,着重介绍了在微流控芯片上进行微阵列分析时的杂交方式、促进杂交的措施以及杂交过程的数学建模,同时也介绍了其他分析步骤方面的进展。最后分析了目前微流控芯片技术在进行微阵列杂交应用方面的不足及其原因,并指出这两项技术相结合的优势和未来。     

微流控芯片在食品安全分析中的应用进展

微流控芯片技术可以实现从样品处理到检测的微型化、自动化、集成化及便携化,因而在食品安全检测方面展现出强大的发展活力。目前微流控芯片技术在农药残留、兽药残留、重金属、食品添加剂等食品安全检测方面已取得了一系列重要进展。该文着重介绍了微流控芯片技术在食品安全分析中的研究进展,并展望了其在食品安全分析中的应用前景。     

Microfluidic chip electrophoresis for biochemical analysis

Microfluidic chip electrophoresis has been widely employed for separation of various biochemical species owing to its advantages of low sample consumption, low cost, fast analysis, high throughput, and integration capability. In this article, we reviewed the development of four different modes of microfluidics‐based electrophoresis technologies including capillary electrophoresis, gel electrophoresis, dielectrophoresis, and field (electric) flow fractionation. Coupling detection schemes on microfluidic electrophoresis platform were also reviewed such as optical, electrochemical, and mass spectrometry method. We further discussed the innovative applications of microfluidic electrophoresis for biomacromolecules (nucleic acids and proteins), biochemical small molecules (amino acids, metabolites, ions, etc.), and bioparticles (cells and pathogens) analysis. The future direction of microfluidic chip electrophoresis was predicted.     

Dielectrophoretic separation of microalgae cells in ballast water in a microfluidic chip

The composition of the ship's ballast water is complex and contains a large number of microalgae cells, bacteria, microplastics, and other microparticles. To increase the accuracy and efficiency of detection of the microalgae cells in ballast water, a new microfluidic chip for continuous separation of microalgae cells based on alternating current dielectrophoresis was proposed. In this microfluidic chip, one piece of 3‐dimensional electrode is embedded on one side and eight discrete electrodes are arranged on the other side of the microchannel. An insulated triangular structure between electrodes is designed for increasing the inhomogeneity of the electric field distribution and enhancing the dielectrophoresis (DEP) force. A sheath flow is designed to focus the microparticles near the electrode, so as to increase the suffered DEP force and improve separation efficiency. To demonstrate the performance of the microfluidic separation chip, we developed two species of microalgae cells (Platymonas and Closterium) and a kind of microplastics to be used as test samples. Analyses of the related parameters and separation experiments by our designed microfluidic chip were then conducted. The results show that the presented method can separate the microalgae cells from the mixture efficiently, and this is the first time to separate two or more species of microalgae cells in a microfluidic chip by using negative and positive DEP force simultaneously, and moreover it has some advantages including simple operation, high efficiency, low cost, and small size and has great potential in on‐site pretreatment of ballast water.     

Chemiluminescence response of murine macrophages on multilayer microfluidic chips

We have demonstrated an integrated platform for microfluidics and chemiluminescence (CL) detection that is capable of parallel cell culture, convenient liquid manipulation, and sensitive chemiluminescent detection. Luminol-dependent CL responses induced by three different stimuli, phytohemagglutinin (PHA), concanavalin A (ConA), and lipopolysaccharides (LPS), which can evoke a CL response in macrophages, were evaluated on this microfluidic chip. We studied the dose-dependent effect of these three stimuli on CL response in murine macrophages. PHA produced the highest CL response compared to LPS and ConA. The CL intensity produced by PHA was 6.85 and four times higher than that by LPS and ConA, respectively, at the low concentration of 100 μg/ml. We have found microfluidic based CL to be a very useful screening tool, which is less laborious and more sensitive. This microfluidic system is disposable and capable of rapid device prototyping; it may prove to be very useful in clinical and pharmaceutical applications.     

On-chip electrochemical detection of CdS quantum dots using normal and multiple recycling flow through modes

A flexible hybrid polydimethylsiloxane (PDMS)-polycarbonate (PC) microfluidic chip with integrated screen printed electrodes (SPE) was fabricated and applied for electrochemical quantum dots (QDs) detection. The developed device combines the advantages of flexible microfluidic chips, such as their low cost, the possibility to be disposable and amenable to mass production, with the advantages of electrochemistry for its facility of integration and the possibility to miniaturize the analytical device. Due to the interest in biosensing applications in general and particularly the great demand for labelling alternatives in affinity biosensors, the electrochemistry of cadmium sulfide quantum dots (CdS QDs) is evaluated. Square wave anodic stripping voltammetry (SWASV) is the technique used due to its sensitivity and low detection limits that can be achieved. The electrochemical as well as the microfluidic parameters of the developed system are optimized. The detection of CdS QDs in the range between 50 to 8000 ng mL(-1) with a sensitivity of 0.0009 μA/(ng mL(-1)) has been achieved. In addition to the single in-chip flow through measurements, the design of a recirculation system with the aim of achieving lower detection limits using reduced volumes (25 μL) of sample was proposed as a proof-of-concept.