微流控芯片检测技术进展

介绍了目前微流控芯片应用的3种主要检测手段:质谱检测器、电化学检测器和光学检测器。微流控芯片是微全分析系统(μ-TAS)中最活跃的领域和发展前沿。人们在微流控芯片的研究中已经取得了很大的进展,研制出了多种微型化、集成化的芯片,而与微流控芯片配套的高灵敏度微型检测系统更是研制的热点。     

一种新的与微型化自发电池整合的电化学发光检测芯片研究

为实现微流控芯片电化学发光检测的微型化,开展了微型自发电池与微流控芯片的整合研究.设计并制作出一种简易、实用的微型化电化学发光检测芯片.初步的分析应用说明了以上设计的可行性.本文结果对催生完全自主性的微型化芯片实验室具有积极的意义.     

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.     

基于微流体脉冲驱动控制技术的电化学微流控芯片制备方法

基于微流体脉冲驱动控制技术搭建了电化学微流控芯片的制备系统.首先将纳米银墨水和甘油溶液分别微喷射到玻璃基底表面形成微电极图形和微流道液体阳模图形;然后分别进行烧结和聚二甲基硅氧烷(PDMS)模塑工艺制得微电极和微流道;最后将微电极和微流道键合形成电化学微流控芯片.研究了系统参量对液滴产生的影响以及液滴直径和重叠率对液滴成线的影响,制得的微电极最小线宽为45 μm、厚度为2.2 μm、电阻率为5.2 μΩ·cm,制得的微流道最小线宽为35 μm,流道表面光滑.采用制得的电化学微流控芯片进行了葡萄糖浓度的电化学流动检测.结果表明,葡萄糖溶液的浓度与响应电流具有较高的线性关系,可对一定浓度范围内的葡萄糖溶液进行定量检测.基于微流体脉冲驱动控制技术的电化学微流控芯片制备方法具有微喷射精度高、重复性好,制备系统结构简单、成本低廉等优点,可用于生化分析、生物传感器等领域的芯片制备.     

CO2激光-化学腐蚀制作金阵列微电极

微电极的制作是微流控芯片电化学检测的关键技术.本文提出CO2激光烧蚀结合化学腐蚀快速制作微流控芯片阵列微电极的方法.在溅射Au/Cr的玻璃基片上涂敷指甲油作牺牲层,利用CO2激光烧蚀开窗口,经化学腐蚀后获得阵列电极,电极宽度为100μm.考察了激光加工参数及牺牲层对电极加工质量的影响,对由键合包封制作的微流控芯片,循环伏安及流动注射分析测试表明,该电极芯片可用于微流控芯片的安培检测.     

微流控芯片电泳的研究进展

该文综述了微流控芯片电泳的制备、结构和应用,比较了不同材料微流控芯片电泳的制备机理、表面改性和性能特点,归纳和总结了不同结构微流控芯片电泳的进样、分离和检测系统以及不同类型微流控芯片电泳在荧光物质、金属离子、糖、药物、核酸、DNA、氨基酸、多肽和蛋白质分析中的应用,并对微流控芯片电泳的未来发展方向做了展望.     

用于磁珠法核酸提取的微流控芯片及自动化平台

基于磁珠法核酸提取原理,设计并制作出旋转驱动式核酸提取微流控芯片及自动化平台。微流控芯片包括裂解腔、清洗腔以及洗脱腔等结构,步进电机带动微流控芯片旋转,通过电磁铁吸附微流控芯片内的磁珠,实现磁珠在各腔室转移,完成核酸提取和纯化。对芯片表面疏水性、磁力大小、磁珠分散程度以及核酸洗脱时间进行优化。结果表明,当磁力大小为250 N时,可实现磁珠转移;磁铁放置于芯片上方1 mm时,腔室内磁珠分散程度最好。洗脱时间为20 min时,芯片上提取大肠杆菌的核酸浓度较高。微流控芯片与磁珠核酸提取技术相结合提取的核酸样本,可直接应用于后续聚合酶链式反应扩增环节,有利于实现核酸自动提取及扩增的一体化。     

基于微流控芯片的72重单核苷酸多态性族群推断系统的构建

建立了常染色体单核苷酸多态性（SNPs）复合检测芯片体系,用于未知个体的族群来源推断。基于前期筛选的74-SNPs组合,采用竞争性等位基因特异性聚合酶链式反应（PCR）的原理构建SNPs的扩增体系,在微流控芯片的每个反应孔内完成一个SNP的检测,通过高通量PCR微流控芯片实现了其中72个SNPs的同步检测。芯片的扩增由平板PCR仪完成,反应孔的荧光信号通过激光共聚焦扫描仪检测,最终通过提取的荧光值进行结果分析。使用该芯片检测获得52份样本的SNPs分型,分型结果的准确率为100%。以57个人群的3628个样本为参考人群数据库,进行20份样本的族群来源推断,推断结果与样本的实际来源一致。本研究建立的常染色体72个SNPs微流控芯片体系可以有效地进行SNP多态性分析检测,基于参考数据库,20份检测样本族群推断的准确性为100%。     

Biophysical measurement of red blood cells by laboratory on print circuit board chip

Microfluidic impedance pulse sensor has emerged as an easily handled and low‐cost platform in the electrical analysis of biological cells. In the conventional method, impedance sensor demanded expensive patterning metal electrodes on the substrate, which are directly in touch with electrolytes in order to measure the microfluidic channel impedance change. In this article, a cost‐effective microfluidic impedance sensor built upon a dielectric film coated printed circuit board is introduced. Impedance electrodes are protected by a dielectric film layer from electrochemical erosion between electrodes and electrolyte. Human red blood cells from adult and neonatal were utilized to demonstrate the feasibility of the proposed device in the electroanalysis of biological cells.     

A microfluidic biosensor for rapid detection of Salmonella typhimurium based on magnetic separation,enzymatic catalysis and electrochemical impedance analysis

Rapid screening of foodborne pathogens is of great significance to ensure food safety.A microfluidic biosensor based on immunomagnetic separation,enzyme catalysis and electrochemical impedance analysis was developed for rapid and sensitive detection of S.typhimurium.First,the bacterial sample,the magnetic nanoparticles （MNPs） modified with capture antibodies,and the enzymatic probes modified with detection antibodies and glucose oxidase （GOx） were simultaneously injected into the microfluidic ch...     

Enhancing signals of microfluidic impedance cytometry through optimization of microelectrode array

Microfluidic impedance cytometry shows a great value in biomedical diagnosis. However, the crosstalk between neighboring microelectrodes strongly weakens the impedance signal. Hereby, we demonstrate a novel microfluidic impedance cytometer consisted of sensing electrodes and ground electrodes (GNDs). The simulation reveals a signal enhancement by more than five times with GNDs compared to that without ones. We also found that the linear correlation between the impedance at a high frequency and that at a low frequency varies as microparticle size changes, which can be used for microparticle classification. The study can help with microelectrode optimization and signal processing for microfluidic impedance analysis.     

微流控技术在生命分析化学中的应用进展

微流控分析系统与宏观条件下的分析体系相比,具有样品和试剂消耗小、传质传热效率高、生物相容性较好、高通量并行分析、功能单元集成化、微型化及自动化控制等特点,在分析化学尤其是生命分析化学领域得到了广泛应用。本文以涉及细胞的微流控技术为切入点,主要介绍了近五年来微流控芯片相关技术的发展,如芯片材料与制作技术、表面改性技术和液滴技术等,并简单总结微流控技术在药物筛选和细胞分析等生命分析化学领域的研究应用进展。     

A new floating electrode structure for generating homogeneous electrical fields in microfluidic channels

In this article a new parallel electrode structure in a microfluidic channel is described that makes use of a floating electrode to get a homogeneous electrical field. Compared to existing parallel electrode structures, the new structure has an easier production process and there is no need for an electrical connection to both sides of the microfluidic chip. With the new chip design, polystyrene beads suspended in background electrolyte have been detected using electrical impedance measurements. The results of electrical impedance changes caused by beads passing the electrodes are compared with results in a similar planar electrode configuration. It is shown that in the new configuration the coefficient of variation of the impedance changes is lower compared to the planar configuration (0.39 versus 0.56) and less dependent on the position of the beads passage in the channel as a result of the homogeneous electrical field. To our knowledge this is the first time that a floating electrode is used for the realization of a parallel electrode structure. The proposed production method for parallel electrodes in microfluidic channels can easily be applied to other applications.     

Crossing microfluidic streamlines to lyse, label and wash cells

We present a versatile method for continuous-flow, on-chip biological processing of cells, large bio-particles, and functional beads. Using an asymmetric post array in pressure-driven microfluidic flow, we can move particles of interest across multiple, independent chemical streams, enabling sequential chemical operations. With this method, we demonstrate on-chip cell treatments such as labeling and washing, and bacterial lysis and chromosomal extraction. The washing capabilities of this method are particularly valuable because they allow many analytical or treatment procedures to be cascaded on a single device while still effectively isolating their reagents from cross-contamination.     

Multiplexing microelectrodes for dielectrophoretic manipulation and electrical impedance measurement of single particles and cells in a microfluidic device

This work presents a microfluidic device, which was patterned with (i) microstructures for hydrodynamic capture of single particles and cells, and (ii) multiplexing microelectrodes for selective release via negative dielectrophoretic (nDEP) forces and electrical impedance measurements of immobilized samples. Computational fluid dynamics (CFD) simulations were performed to investigate the fluidic profiles within the microchannels during the hydrodynamic capture of particles and evaluate the performance of single‐cell immobilization. Results showed uniform distributions of velocities and pressure differences across all eight trapping sites. The hydrodynamic net force and the nDEP force acting on a 6 μm sphere were calculated in a 3D model. Polystyrene beads with difference diameters (6, 8, and 10 μm) and budding yeast cells were employed to verify multiple functions of the microfluidic device, including reliable capture and selective nDEP‐release of particles or cells and sensitive electrical impedance measurements of immobilized samples. The size of immobilized beads and the number of captured yeast cells can be discriminated by analyzing impedance signals at 1 MHz. Results also demonstrated that yeast cells can be immobilized at single‐cell resolution by combining the hydrodynamic capture with impedance measurements and nDEP‐release of unwanted samples. Therefore, the microfluidic device integrated with multiplexing microelectrodes potentially offers a versatile, reliable, and precise platform for single‐cell analysis.     

Rapid Analysis of Oligonucleotides on a Planar Microfluidic Chip

State-of-the-art microfluidic analytical systems are briefly surveyed. Attention is focused on the use of microchip capillary electrophoresis. The main results obtained in the development of a prototype analytical system with a laser-induced fluorescence detector for electrophoresis on a glass microfluidic chip are presented. Experimental data on electroosmotic flow and the distribution of sample fluorescence intensity over the cross section of a microchannel are analyzed. A procedure for the rapid analysis of oligonucleotides on a microfluidic chip is described.     

Classification of cell types using a microfluidic device for mechanical and electrical measurement on single cells

This paper presents a microfluidic system for cell type classification using mechanical and electrical measurements on single cells. Cells are aspirated continuously through a constriction channel with cell elongations and impedance profiles measured simultaneously. The cell transit time through the constriction channel and the impedance amplitude ratio are quantified as cell's mechanical and electrical property indicators. The microfluidic device and measurement system were used to characterize osteoblasts (n=206) and osteocytes (n=217), revealing that osteoblasts, compared with osteocytes, have a larger cell elongation length (64.51 ± 14.98 μm vs. 39.78 ± 7.16 μm), a longer transit time (1.84 ± 1.48 s vs. 0.94 ± 1.07 s), and a higher impedance amplitude ratio (1.198 ± 0.071 vs. 1.099 ± 0.038). Pattern recognition using the neural network was applied to cell type classification, resulting in classification success rates of 69.8% (transit time alone), 85.3% (impedance amplitude ratio alone), and 93.7% (both transit time and impedance amplitude ratio as input to neural network) for osteoblasts and osteocytes. The system was also applied to test EMT6 (n=747) and EMT6/AR1.0 cells (n=770, EMT6 treated by doxorubicin) that have a comparable size distribution (cell elongation length: 51.47 ± 11.33 μm vs. 50.09 ± 9.70 μm). The effects of cell size on transit time and impedance amplitude ratio were investigated. Cell classification success rates were 51.3% (cell elongation alone), 57.5% (transit time alone), 59.6% (impedance amplitude ratio alone), and 70.2% (both transit time and impedance amplitude ratio). These preliminary results suggest that biomechanical and bioelectrical parameters, when used in combination, could provide a higher cell classification success rate than using electrical or mechanical parameter alone.     

Analytical and numerical study of Joule heating effects on electrokinetically pumped continuous flow PCR chips

Joule heating is an inevitable phenomenon for microfluidic chips involving electrokinetic pumping, and it becomes a more important issue when chips are made of polymeric materials because of their low thermal conductivities. Therefore, it is very important to develop methods for evaluating Joule heating effects in microfluidic chips in a relatively easy manner. To this end, two analytical models have been established and solved using the Green's function for evaluating Joule heating effects on the temperature distribution in a microfluidic-based PCR chip. The first simplified model focuses on the understanding of Joule heating effects by ignoring the influences of the boundary conditions. The second model aims to consider practical experimental conditions. The analytical solutions to the two models are particularly useful in providing guidance for microfluidic chip design and operation prior to expensive chip fabrication and characterization. To validate the analytical solutions, a 3-D numerical model has also been developed and the simultaneous solution to this model allows the temperature distribution in a microfluidic PCR chip to be obtained, which is used to compare with the analytical results. The developed numerical model has been applied for parametric studies of Joule heating effects on the temperature control of microfluidic chips.