三种细胞共培养微流控芯片的设计和制作

设计一种具有“微坝”和“微缝”结构的微流控芯片,能够物理隔离不同细胞,而且培养基中小分子营养物质可以自由流通。实验结果表明在芯片上可以共培养人肺腺癌细胞(A549)、人胚肺成纤维细胞(HLF-1)和人内皮细胞(HUVECs)三种细胞,在72 h培养后三种细胞生长状态良好,具有细胞图形化的特点和功能,为下一步开展多种细胞相互作用等相关研究提供重要的技术平台。     

基于微流控芯片的细胞-细菌相互作用光电检测技术

细胞/细菌及其相互作用研究对于生命科学、药物研发、医学诊疗等领域的研究具有重要意义。微流控芯片分析技术因微环境可控、生物相容性好、检测并行性、微型化等特性，正发展成为细胞/细菌及其相互作用研究的高效手段。本文在简要介绍基于微流控芯片分析技术的细胞-细菌分析方法和技术基础之上，对微流控芯片上细胞-细菌相互作用模型的建立进行了讨论，重点针对细胞-细菌及其相互作用过程的芯片检测进行了综述，尤其对芯片集成的光电检测技术及其测试效果进行总结和比较。通过芯片集成微流体控制、多种光电传感监测模块，使微流控芯片分析技术成为细胞/细菌及其相互作用过程分析和检测的支撑平台和优势手段。最后，对微流控光电检测技术在细胞-细菌相互作用检测中面临的挑战及发展趋势进行了讨论和展望。     

基于微流控芯片构建三维基质支架中的多细胞球体模型

抗癌药物在进行动物和临床试验以前,需要用体外肿瘤组织模型评估药效.由于三维(3D)多细胞球体(multicellular tumor spheroids MCTSs)在抗药性和组织结构等方面与体内肿瘤组织相似,常被用作体外肿瘤组织模型.为监测MCTSs在形成过程中,肿瘤细胞之间和肿瘤细胞与基质之间的相互作用,基于微流控技术基础上自行设计和构建MCTSs模型.该肿瘤MCTSs模型实验结果表明,在3D微环境下,血清能够诱导MDA-MB-231形成直径为289μm的MCTSs,肿瘤细胞MCTSs之间有相互靠近的趋势,并且发现凋亡细胞多分布在MCTSs之间.肿瘤坏死因子(tumor necrosis factor-α,TNF-α)诱导MDA-MB-231形成MCTSs之间没有相互靠近的趋势,并且MCTSs直径的长度很难达到100μm.以上结果表明,该模型有望为研究肿瘤形成MCTSs机制和药物筛选提供有用的体外肿瘤模型.     

微流控芯片细胞捕获分离方法概述

细胞捕获分离是免疫学、诊断检测、病理研究等学科经常用到的生物学实验方法.近年来,微流控芯片平台的细胞捕获分离方式花样繁多,层出不穷,它具有可快速检测、所需样本量少、节约试剂、成本低廉等优势.本文主要对近年来多种微流控细胞捕获分离的方法,以免疫捕获分离和无标签细胞分离两类对其进行介绍.免疫捕获分离是较为传统的细胞捕获分离方式,它的特异性好、捕获分离后的细胞纯度较高.无标签细胞分离是近几年热门发展的技术手段,它采用物理学与生物学相结合的方式,能较好地保持细胞的完整性和生物活性.细胞捕获分离在微流控平台的应用虽然发展迅速,但其在工业化生产和微型化整合等方面还存在一些问题,只有解决生产问题,细胞捕获分离在微流控平台的应用才真正具有实际价值,可以真正作为一种技术手段用于日常的实验操作和医学检测中.就目前而言,细胞捕获分离在微流控芯片中仍具有很大的发展前景.     

微流控芯片在细胞分析中的应用

细胞是生物体和生命活动的基本单位,细胞分析对于细胞结构和功能的研究、生命活动规律和本质的探索、疾病的诊断与治疗、药物的筛选与设计等都具有十分重要的意义.自微流控芯片面世以来,以其微型化、集成化、自动化和便携化等优势越来越多地应用在细胞分析领域.现就微流控芯片在细胞操纵、细胞培养和细胞内组分分析三个方面上的应用进行综述.     

用于药物筛选的微流控细胞阵列芯片

细胞区域分布培养以及如何有效地对微流体进行操控是微流控阵列芯片在细胞药物研究中的关键技术。本研究介绍了一种利用SU-8负性光刻胶模具和PDMS制作双层结构的微流控细胞阵列芯片的方法,该芯片通过C型的坝结构将进样细胞拦截在芯片的细胞培养的固定区域,键合双层PDMS构成阀控制层,阀网络的开关作用成功实现了芯片通道内微流体的操控,同时芯片设计了药物浓度梯度网络,产生6个不同浓度的药物刺激细胞。通过对芯片3种共培养细胞活性的检测和药物伊立替康(CTP-11)对肝癌细胞的浓度梯度刺激等实验结果验证该芯片在细胞研究和药物筛选等方面的可行性。     

基于微流控技术的微生物细胞梯度稀释分离方法

随着微流控分析技术的快速发展,集成化的微流控芯片在满足实验高通量的同时,还在微生物细胞分离领域呈现出独特的优势。本研究基于微流控技术,制备了以聚二甲基硅氧烷(PDMS)、玻片为材料的细菌细胞梯度稀释分离芯片。该芯片的核心是通过一系列复杂的梯度网络来实现对细菌悬液的连续稀释,最终被分离的细菌细胞进入通道末端的存储孔内。结果显示,该方法能分离出的最少细菌细胞数低于10个。此芯片平台操作简单、耗时短、成本低,为微生物单细胞研究提供了新的途径。     

微流控与细胞迁移技术的研究进展

细胞迁移在多种生理、病理过程中扮演着重要角色。在细胞迁移研究中,琼脂糖平板法、transwell小室法等因操作简单、重现性好被广泛运用于细胞迁移的体外建模。但传统方法大多是检测单因素条件下的细胞迁移情况,却忽略了血流这一重要因素对细胞迁移的影响。微流控芯片的出现不仅解决了上述难题,并能保证迁移试验在多参数条件下一步到位的完成并及进行实时观测。因此,微流控芯片将带来一场细胞迁移技术及相关领域的革命。对近10年微流控技术在细胞迁移研究中运用进行了总结。     

超大表面积自驱动微流控芯片的设计与制备

目的:利用新型纳米森林材料,构建一种操作简单、检测快速、灵敏度高的用于现场检测的自驱动微流控芯片。方法:利用MEMS加工技术制备出具有优良光学性能和大表面积的石英纳米森林结构微流道,对该纳米森林结构的高度、宽度/横向尺寸、密度、表面积、光学性能、毛细驱动效果、荧光增敏效果做出评价,利用双抗体夹心的方法进行蓖麻毒素的检测。结果:纳米纤维锥底直径200～300nm,高度约1. 0μm,纳米森林的密度约为10个/μm~2,估测表面积比底面积达5∶1以上。其在波长为680nm处的透光率达89. 5%,驱动流速约5mm/s,与平面结构相比,其饱和荧光显色成倍提高。蓖麻毒素的检测限低于10pg/ml,在10～6 250pg/ml范围内具有较好线性关系。结论:基于纳米森林结构,成功构建了一种具有超大表面积和高灵敏度的毛细自驱动微流控芯片。     

基于微流控芯片的体外血脑屏障模型构建

目的:利用微流控芯片技术构建易调控、接近在体微环境的体外血脑屏障模型。方法:微流控芯片体外模型采用上下双培养池结构,由多聚碳酸酯膜分隔,两套流路系统控制流体。细胞采用原代分离纯化的大鼠脑血管内皮细胞和星形胶质细胞,免疫荧光技术进行鉴定,分别按次序注入微流控芯片上下培养池,按1μl/min的流速进行灌注培养,构建体外血脑屏障模型,并对此模型进行鉴定和评价。结果:原代分离纯化得到两种细胞,免疫荧光法鉴定细胞纯度达95%以上。共培养3天紧密连接开始形成,5天达到峰值,超微结构观察显示内皮细胞之间形成紧密连接,且荧光素钠渗透实验和TEER值测量表明屏障形成良好。结论:成功构建微流控芯片体外血脑屏障模型,可成为一个新的平台应用于药物筛选、神经系统基础等多项研究中。     

Laser-scanning lithography (LSL) for the soft lithographic patterning of cell-adhesive self-assembled monolayers

We report the development of laser-scanning lithography (LSL), which employs a laser-scanning confocal microscope to pattern photoresists that can be utilized, for example, in the fabrication of masters for use in soft lithography. This convenient technique provides even exposure across the entire view field and facilitates accurate alignment of successive photoresist exposures. Features on the scale of 3 microm have been achieved to date with a 10x objective (NA 0.45). Virtual masks, instructions for laser irradiation, were drawn using the Region of Interest (ROI) function of a Zeiss LSM 510 microscope. These regions were then exposed to a 458 nm argon laser for 32 micros (0.9 mW/microm(2)). Differential interference contrast (DIC) imaging was utilized with a non-destructive 514 nm argon laser as an immediate quality check of each exposure, to align successive exposures, and to reduce chromatic aberration between imaging and exposure. Developed masters were replica-molded with poly(dimethylsiloxane) (PDMS); these masters were then utilized for microcontact printing of cell-adhesive self-assembled monolayers (SAMs) to demonstrate the utility of this process. Initial studies confirmed that human dermal fibroblast adhesion and spreading were limited to cell-adhesive SAM areas. LSL is a rapid, flexible, and readily available technique that will accelerate master design and preparation; moreover, it can be applied to additional forms of photolithography and photopolymerization for studies in cell biology, biomaterials design and evaluation, materials science, and surface chemistry.     

A MEMS based amperometric detector for E. coli bacteria using self-assembled monolayers.

We developed a system for amperometric detection of Escherichia coli (E. coli) based on the integration of microelectromechanical systems (MEMS), self-assembled monolayers (SAMS), DNA hybridization, and enzyme amplification. Using MEMS technology, a detector array was fabricated which has multiple electrodes deposited on a Si wafer and was fully reusable. Using SAMs, a monolayer of the protein streptavidin was immobilized on the working electrode (Au) surface to capture rRNA from E. coli. Three different approaches can be used to immobilize streptavidin onto Au, direct adsorption of the protein on bare Au, binding the protein to a biotinylated thiol SAM on Au, and binding the protein to a biotinylated disulfide monolayer on Au. The biotinylated thiol approach yielded the best results. High specificity for E. coli was achieved using ssDNA–rRNA hybridization and high sensitivity was achieved using enzymatic amplification with peroxidase as the enzyme. The analysis protocol can be conducted with solution volumes on the order of a few microliters and completed in 40 min. The detection system was capable of detecting 1000 E. coli cells without polymerase chain reaction with high specificity for E. coli vs. the bacteria Bordetella bronchiseptica.     

基于液滴微流控的细胞凝胶微球研究进展

液滴微流控技术在微纳米尺度上对多种流体的流动进行精确控制,从而能够以高通量的方式生成结构可调和成分可控的微纳米液滴。通过结合合适的水凝胶材料和制造方法,可以将单个或多个细胞高效地封装进水凝胶中,制备细胞凝胶微球。细胞凝胶微球可以为细胞的增殖、分化等提供一个三维的、相对独立可控的微环境,在三维细胞培养、组织工程与再生医学、干细胞研究和单细胞研究等生命科学领域具有重要价值。本文主要综述了基于液滴微流控技术的细胞凝胶微球的制备及其在生物医学领域的应用,并对未来的研究工作提出了展望。     

A MEMS based amperometric detector for E. Coli bacteria using self-assembled monolayers

We developed a system for amperometric detection of Escherichia coli (E. coli) based on the integration of microelectromechanical systems (MEMS), self-assembled monolayers (SAMS), DNA hybridization, and enzyme amplification. Using MEMS technology, a detector array was fabricated which has multiple electrodes deposited on a Si wafer and was fully reusable. Using SAMs, a monolayer of the protein streptavidin was immobilized on the working electrode (Au) surface to capture rRNA from E. coli. Three different approaches can be used to immobilize streptavidin onto Au, direct adsorption of the protein on bare Au, binding the protein to a biotinylated thiol SAM on Au, and binding the protein to a biotinylated disulfide monolayer on Au. The biotinylated thiol approach yielded the best results. High specificity for E. coli was achieved using ssDNA–rRNA hybridization and high sensitivity was achieved using enzymatic amplification with peroxidase as the enzyme. The analysis protocol can be conducted with solution volumes on the order of a few microliters and completed in 40 min. The detection system was capable of detecting 1000 E. coli cells without polymerase chain reaction with high specificity for E. coli vs. the bacteria Bordetella bronchiseptica.     

Controlled Cell Patterning on Bioactive Surfaces with Special Wettability

The ability to control cell patterning on artificial substrates with various physicochemical properties is of essence for important implications in cytology and biomedical fields.Despite extensive progress,the ability to control the cell-surface interaction is complicated by the complexity in the physiochemical features ofbioactive surfaces.In particular,the manifestation of special wettability rendered by the combination of surface roughness and surface chemistry further enriches the cell-surface interaction.Herein we investigated the cell adhesion behaviors of Circulating Tumor Cells (CTCs) on topographically patterned but chemically homogeneous surfaces.Hamessing the distinctive cell adhesion on surfaces with different topography,we further explored the feasibility of controlled cell patterning using periodic lattices of alternative topographies.We envision that our method provides a designer's toolbox to manage the extracellular environment.     

Picodroplet-deposition of enzymes on functionalized self-assembled monolayers as a basis for miniaturized multi-sensor structures

We are reporting on a novel approach for structured immobilisation of enzymes on gold surfaces modified with monolayers of functionalised alkylthiols. The formation of enzyme spots is achieved by shooting very small volumes of an appropriate enzyme solution (down to 100 pl) onto a thiol-monolayer modified gold surface using a micro-dispenser. Formation of enzyme patterns is obtained by moving the micro-dispenser relative to the modified gold surface using a micro-positioning device. Enzyme spots with typical lateral dimensions of 100 μm are obtained, but also, more complex structures, e.g. lines or meander structures, can be achieved by multiple droplets dispensed during the concomitant movement of the micro-dispenser. The first enzyme layer on top of the functionalised thiol-monolayer is subsequently covalently immobilised using either carbodiimide activation of carboxilic headgroups at the enzyme or via already introduced activated ester functions at the monolayer. Immobilised enzyme activities of glucose oxidase and lactate oxidase patterns have been characterised by means of scanning electrochemical microscopy. The product of the enzyme-catalysed reaction, H₂O₂, is detected with an micro-electrode in the presence of either or both substrates, glucose and lactate, leading to a visualisation of the corresponding enzyme pattern and the lateral enzymatic activity.     

Patterning of proteins and cells on functionalized surfaces prepared by polyelectrolyte multilayers and micromolding in capillaries

A method for protein and cell patterning on polyelectrolyte-coated surfaces using simple micromolding in capillaries (MIMIC) is described. MIMIC produced two distinctive regions. One contained polyethylene glycol (PEG) microstructures fabricated using photopolymerization that provided physical, chemical, and biological barriers to the nonspecific binding of proteins, bacteria, and fibroblast cells. The second region was the polyelectrolyte (PEL) coated surface that promoted protein and cell immobilization.

The difference in surface functionality between the PEL region and background PEG microstructures resulted in simple patterning of biomolecules. Fluorescein isothiocyanate-tagged bovine serum albumin, E. coli expressing green fluorescence protein (GFP), and fibroblast cells were successfully bound to the exposed PEL surfaces at micron scale. Compared with the simple adsorption of protein, fluorescence intensity was dramatically improved (by about six-fold) on the PEL-modified surfaces. Although animal cell patterning is prerequisite for adhesive protein layer to survive on desired area, the PEL surface without adhesive proteins provides affordable microenvironment for cells.

The simple preparation of functionalized surface but universal platform can be applied to various biomolecules such as proteins, bacteria, and cells.     

Colloid Lithography-Induced Polydimethylsiloxane Microstructures and their Application to Cell Patterning

Colloidal lithography was used to make a novel array (2-D) of micro-rings, dots, and interconnected-honeycomb structures. These geometries are controlled using the curing temperature-dependent rheological properties of the siloxane elastomer precursor. Serratia marcescens was patterned on the interconnected honeycomb microstructure demonstrating a potential application for microbioanalytical devices, microfluidics, and bio-micro-electromechanical systems. Received 26 August 2005; Revisions requested 23 September 2005; Revisions received 10 November 2005; Accepted 11 November 2005     

Locally Addressable Electrochemical Patterning Technique (LAEPT) applied to poly(L-lysine)-graft-poly(ethylene glycol) adlayers on titanium and silicon oxide surfaces

The protein-resistant polycationic graft polymer, poly(L-lysine)-g-poly(ethylene glycol) (PLL-g-PEG), was uniformly adsorbed onto a homogenous titanium surface and subsequently subjected to a direct current (dc) voltage. Under the influence of an ascending cathodic and anodic potential, there was a steady and gradual loss of PLL-g-PEG from the conductive titanium surface while no desorption was observed on the insulating silicon oxide substrates. We have implemented this difference in the electrochemical response of PLL-g-PEG on conductive titanium and insulating silicon oxide regions as a biosensing platform for the controlled surface functionalization of the titanium areas while maintaining a protein-resistant background on the silicon oxide regions. A silicon-based substrate was micropatterned into alternating stripes of conductive titanium and insulating silicon oxide with subsequent PLL-g-PEG adsorption onto its surfaces. The surface modified substrate was then subjected to +1800 mV (referenced to the silver electrode). It was observed that the potentiostatic action removed the PLL-g-PEG from the titanium stripes without inducing any polyelectrolyte loss from the silicon oxide regions. Time-of-flight secondary ions mass spectroscopy and fluorescence microscopy qualitatively confirmed the PLL-g-PEG retention on the silicon oxide stripes and its absence on the titanium region. This method, known as "Locally Addressable Electrochemical Patterning Technique" (LAEPT), offers great prospects for biomedical and biosensing applications. In an attempt to elucidate the desorption mechanism of PLL-g-PEG in the presence of an electric field on titanium surface, we have conducted electrochemical impedance spectroscopy experiments on bare titanium substrates. The results showed that electrochemical transformations occurred within the titanium oxide layer; its impedance and polarization resistance were found to decrease steadily upon both cathodic and anodic polarization resulting in the polyelectrolyte desorption from the titanium surface.