芯片液相色谱技术进展

微型化是现代分析仪器发展的重要趋势。微型化液相色谱仪器在提供与常规尺度液相色谱相同甚至更高分离效率的同时,可以有效减少溶剂和样品的消耗;在液相色谱-质谱联用中,低流速进样可以有效提高质谱离子源的离子化效率,提高质谱检测效率;对于极微量样品的分离,微型化的液相色谱可以有效减少样品稀释;液相色谱的微型化还有利于液相色谱仪器整体的模块化和集成化设计。芯片液相色谱是在微流控芯片上制备色谱柱并集成相应的流体控制系统和检测系统。芯片液相色谱是色谱仪器微型化的一种重要方式,受到学术界和产业界的普遍关注,但是这一方式也充满挑战。液相色谱微流控芯片需要在芯片基底材料、芯片色谱柱的结构设计、微流体控制技术、检测器技术等方面做出创新,使微流控芯片系统适配液相色谱分离技术的需要。目前芯片液相色谱领域面临的主要问题在于芯片基底材料的性质难以满足芯片液相色谱进一步微型化和集成化的需求;因此芯片液相色谱在未来的发展中需要着重关注新型微流控芯片基底材料的开发以及微流控芯片通道结构的统一设计。该文着重介绍了芯片液相色谱技术近年来的研究进展,并简要展示了商品化芯片色谱当前的发展情况。     

基于微流控芯片的色谱系统的研究进展及其应用

近年来,基于微流控芯片的色谱技术研究取得了快速发展。本文对微流控芯片上色谱柱的加工方法、泵阀驱动控制装置的设计、集成及联用色谱系统的研制及其应用等方面予以综述,涉及文献66篇。     

一种微流控芯片中大体积进样方法及专用芯片

本发明涉及微流控芯片系统的进样方法。在使用固定相的微流控芯片系统中,于芯片分离通道与流动相人口之间设置两个或两个以上的分流通道。通过控制其中流体的切换和截止,实现对微流控芯片系统的大体积进样。该方法适合于微流控芯片中电色谱、加压电色谱和液相色谱模式下的大体积进样。该方法的优点为：可实现微流控芯片中大体积样品的上样;克服了系统中的梯度延迟效应,     

基于微流控芯片的固相萃取技术的研究进展

作为近年来最前沿的分析技术之一,微流控芯片技术具有高通量、微型化、多功能和集成化等独特优势,目前,该技术主要以生命科学体系为研究对象。但由于生化样品存在基质效应与干扰组分,使得样品分析备受干扰。因此发展微流控芯片中的样品前处理技术,对于样品尤其是复杂的生物样品的纯化和富集极其重要,同时这也是微流控芯片系统走向集成化和微型化必须突破的瓶颈之一。本文针对应用广泛的固相萃取技术,重点综述了微流控芯片上固相萃取技术的几种不同模式即开管柱、填充柱以及整体柱的特点及优缺点,并对微流控芯片系统的发展做出了展望。     

蛋白质/多肽的微流控二维芯片电泳

在微流控芯片上构建多维分离系统,为蛋白质组学研究提供了一个有发展前景的高效分离分析技术平台。本文介绍了二维芯片电泳系统耦联模式选取及正交性评价的方法;综述了针对蛋白质/多肽分离分析的各种耦联模式微流控二维芯片电泳分析系统,如胶束电动力学色谱（MEKC）与毛细管区带电泳（CZE）,开管电色谱（OECE）与CZE,等电聚焦（IEF）与CZE, IEF与SDS毛细管凝胶电泳（CGE）, SDS-CGE与MEKC等。特别对二维电泳芯片切换接口的类型进行了分类,探讨了用于微流控二维芯片电泳系统的检测技术,并展望了微流控二维电泳芯片在蛋白质组学研究中的应用前景和发展方向。     

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)。     

微流控高通量试样引入技术的研究进展

如何实现外部宏观系统与芯片微观系统之间的衔接一直是微流控芯片分析领域中一个重要的研究课题。本文结合作者所在研究组的工作及成果,介绍了当前微流控高通量试样引入技术的研究进展。其中分别介绍了基于固定储液池、流通池和取样探针3种模式的微流控芯片系统试样引入系统,以及基于毛细管的微流控高通量试样引入系统。此外,还对该领域研究发展的前景进行了展望。     

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。     

微流控芯片上的免疫分析

近20年来,随着微流控芯片加工技术的不断发展,微流控分析已从一个概念发展为当前世界上最前沿的科技领域之一,微流控芯片上免疫分析的方法研究也取得重要进展。这些芯片包含传输流体的微通道和免疫分析程序中部分或全部的必要组件。微流控技术用于免疫分析在减少试剂用量、缩短分析时间、自动化等方面提高了分析性能。本文综述了微流控芯片上免疫分析的发展、分类,并评述了各类微流控免疫分析芯片的性能及优缺点。     

微流控芯片-质谱联用细胞分析方法研究进展

细胞分析和代谢物分析在生物系统中起着重要的作用。微流控技术已成为细胞生物学研究的一个重要工具。该文总结了最近微流控芯片在细胞和代谢物的分析,尤其是微流控芯片与质谱联用技术的应用。同时对微流控芯片上细胞的生物学研究提出了见解和看法,希望能对感兴趣者提供一些启发。     

Monolithic column plastic microfluidic device for peptide analysis using electrospray from a channel opening on the edge of the device

Electrospray from a channel exit at the edge of a fluorocarbon coated cycloolefin copolymer microfluidic device has been investigated. The fluorocarbon coating facilitated generation of a stable electrospray, thereby enhancing the detectability of electrospray ionization (ESI) mass spectrometry (MS). A microfluidic device of integrated ESI emitters and monolithic liquid chromatography columns has been fabricated on a cycloolefin copolymer chip. The monolithic columns were polymerized in situ using UV irradiation with a photomask to confine the porous polymer monolith to the desired regions of the channels. The monolithic stationary phase was homogenous and well bonded to the channel surfaces, which had been functionalized by graft polymerization. The ESI potential was applied within the channel via a carbon ink line. The performance of this microfluidic device was demonstrated by analysis of a tryptic digest of bovine serum albumin on an ion trap MS instrument.     

微流控芯片实验室

 以作者所在课题组近年来的研究工作为基础,就芯片实验室平台建设及相应的以系统生物学为最终目标的功能化研究作一说明,对在分子和细胞层面,甚至是单分子、单细胞水平上实现以规模集成为特征的临床诊断和药物筛选的努力予以特别的关注。     

Lab-chip HPLC with integrated droplet-based microfluidics for separation and high frequency compartmentalisation

We demonstrate the integration of a droplet-based microfluidic device with high performance liquid chromatography (HPLC) in a monolithic format. Sequential operations of separation, compartmentalisation and concentration counter were conducted on a monolithic chip. This describes the use of droplet-based microfluidics for the preservation of chromatographic separations, and its potential application as a high frequency fraction collector.     

微流控芯片技术在蛋白质分析中的应用进展

近年来,微流控芯片技术取得了显著的发展。随着微电子及微机械等制作技术的不断进步,高通量、高效、快速、低成本的微流控分析芯片在蛋白质和多肽分析方面获得了令人瞩目的成果。本文主要介绍了微流控芯片在蛋白质组学分析研究的应用和发展。引用文献52篇。     

Recent development of monolithic stationary phases with emphasis on microscale chromatographic separation

The column technologies play a crucial role in the development of new methods and technologies for the separation of biological samples containing hundreds to thousands compounds. This review focuses on the development of monolithic technology in micro-column formats for biological analysis, especially in capillary liquid chromatography, capillary electrochromatography and microfluidic devices in the past 5 years (2002-2007) since our last review in 2002 on monoliths for HPLC and CEC. The fabrication and functionalization of monoliths were summarized and discussed, with the aim of presenting how monolithic technology has been playing as an attractive tool for improving the power of existing chromatographic separation processes. This review consists of two parts: (i) the recent development in fabrication of monolithic stationary phases from direct synthesis to post-functionalization of the polymer- and silica-based monoliths tailoring the physical/chemical properties of porous monoliths; (ii) the application of monolithic stationary phases for one- and multi-dimensional capillary liquid chromatography, fast separation in capillary electro-driven chromatography, and microfluidic devices.     

单细胞分析的研究

单细胞分析是分析化学、生物学和医学之间渗透发展形成的跨学科前沿领域。近年来,毛细管电泳及微流控芯片用于单细胞分析已取得显著进展,特别表现在微流控芯片用于细胞的培养、分选、操纵、定位、分离及检测细胞的组分,实时监测细胞释放,及高通量阵列检测等方面。芯片的单元操作可根据需要灵活组合,显示出其独特的优点。本文重点介绍作者研究组的工作,并对近三年来国内外在毛细管电泳及芯片毛细管电泳用于单细胞分析的新进展进行评论。最后从毛细管电泳与微流控芯片、微流控芯片与细胞界面以及量子点用于探测活细胞等方面,展望了单细胞分析的发展前景。     

电沉积技术制作高聚物微流控芯片模具

利用电沉积技术制作微流控芯片金属模具,方法是：使用新型超厚光刻胶SU-8胶作近紫外光刻,并在光刻后的图案上电沉积金属Ni,之后去胶,最终获得金属模具．该法减小了电沉积工作量．采用反向电流预处理基底、并适当增加电铸液的添加剂以及脱模后真空退火,即可明显提高电沉积微结构与基底的结合力．用此金属模具成功热压了PMMA,制成了微流控芯片．     

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.     

Microfluidic device for capillary electrochromatography-mass spectrometry

A novel microfabricated device that integrates a monolithic polymeric separation channel, an injector, and an interface for electrospray ionization-mass spectrometry detection (ESI-MS) was devised. Microfluidic propulsion was accomplished using electrically driven fluid flows. The methacrylate-based monolithic separation medium was prepared by photopolymerization and had a positively derivatized surface to ensure electroosmotic flow (EOF) generation for separation of analytes in a capillary electrochromatography (CEC) format. The injector operation was optimized to perform under conditions of nonuniform EOF within the microfluidic channels. The ESI interface allowed hours of stable operation at the flow rates generated by the monolithic column. The dimensions of one processing line were sufficiently small to enable the integration of 4-8 channel multiplexed structures on a single substrate. Standard protein digests were utilized to evaluate the performance of this microfluidic chip. Low- or sub-fmol amounts were injected and detected with this arrangement.     

化学发光检测在微流控芯片中的应用综述

综述了近年来化学发光检测在微流控芯片中的应用.指出微流控芯片(又称为"芯片实验室"或者"微型全分析系统")因具有小型化、集成化和自动化等特点而在近20年来日益受到关注,而化学发光检测具有仪器结构简单、背景噪音低、操作和维护成本低等优点,非常适合用作微流控芯片的检测手段.