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。     

微流控技术对细胞微环境的模拟及应用研究

细胞微环境是一个多因素组成的、时空可变的复杂集合,对细胞的行为和功能发挥起着决定性作用。但传统的细胞生物学研究方法很难在体外为细胞提供这样一个复杂的、微尺度的生长环境,致使许多体外研究结果与在体情况相差甚远。近年来,微流控技术与细胞培养技术的结合为细胞微环境的模拟和控制提供了可能。文章通过提炼微环境的重要参数及其特征,介绍微流控技术是如何满足这些参数的需求,探讨了微流控技术在体外模拟细胞微环境的可行性,并总结了近年来该技术在微环境体外模拟研究中取得的成果,对微流控技术在细胞微环境构建中的发展方向和应用前景进行了展望。     

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。     

微流控芯片分析技术在生化研究中的应用进展

综述了微流控芯片分析技术在生物和化学领域中进展,主要从药物筛选、PCR、细胞研究和微流控芯片电泳4个方面总结目前的进展。     

阵列光镊与微流控芯片技术的结合与应用

在生物医学研究领域中,阵列光镊与微流控芯片的结合已经成为进行细胞操纵、转移以及少量细胞样品分选等方面最有希望的方法之一。光镊技术对样品具有非接触弹性控制、无机械损伤、可无菌操作等优势,以及微流控芯片分析的高效、多功能、微型化、低成本等优势,成为芯片实验室(Lab-on-a-Chip)的重要研究方面。该文概述了阵列光镊技术的形成与研究现状以及微流控芯片技术的发展与应用现状,分析了在不同阵列光镊形成方法下结合微流控芯片可实现的功能与应用,并对其发展趋势进行了展望。     

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。     

微流控芯片在昆虫研究中的应用

与昆虫学相关的研究是生命科学最早的研究领域之一,在害虫防治、资源昆虫利用和模式生物（例如黑腹果蝇Drosophila melanogaster）等研究领域有重要意义。微流控芯片（Microfluidic chip）也称作“芯片实验室”（Lab-on-a-chip）,是21世纪一项重要的技术发明,目前被广泛应用于细胞生物学、发育生物学、体外诊断等领域。随着微流控芯片技术发展的不断深入,与昆虫研究相关的微流控芯片不断出现,促进了昆虫细胞、胚胎发育、昆虫行为和害虫防治等研究领域的发展。本文针对应用于昆虫学领域的微流控芯片研究进行综述。     

用于肿瘤标志物检测的电化学免疫传感器

联合检测几种肿瘤标志物,在肿瘤早期诊断中具有重要的临床应用价值。随着纳米技术、流动注射分析技术、微流控技术以及丝网印刷术的迅猛发展,电化学免疫传感器可以在肿瘤标志物的检测中扮演越来越重要的角色。本文主要介绍了电化学免疫传感器的原理及其在肿瘤蛋白标志物检测中的应用情况,并介绍了纳米材料、流动注射分析、微流控等技术在肿瘤标志物免疫传感器中的运用,展望了电化学免疫传感器的前景。     

微流控芯片在植物细胞研究中的应用进展

植物细胞的传统分析方法是将植物细胞在土壤或者琼脂平板上生长,然后在温室或植物生长室内观察植物的表型。这种方法耗时耗力,且结果分辨率比较低。微流控芯片具有微型化、体积小和高通量等特点,且可在微米水平精确控制植物细胞生长的微环境。因此,能够降低实验成本,缩短实验时间,并且可以达到单细胞水平的分析和鉴定。首先介绍了微流控芯片的加工材料和制备方法,总结了用于植物细胞研究的微流控芯片,重点阐述了近年来微流控芯片在植物根、花粉管、原生质体和细胞壁动力学等植物细胞研究中的应用进展,并展望了微流控芯片在植物细胞研究的应用前景。     

微流控芯片在干细胞研究中的应用

干细胞以其多潜能性和自我更新能力成为人类早期胚胎研究、干细胞治疗和组织工程修复中的主要细胞来源和种子细胞。但传统细胞研究方法难以提供干细胞生长和分化所需的复杂多层次的微环境,使研究结果与体内真实情况相差甚远,尽可能模拟和精确调控干细胞培养微环境,进而控制干细胞自我更新或分化命运,成干细胞研究的难点。微流控芯片可以更真实地模拟干细胞小生境(niche);实时可控的对单个干细胞加载剪切力和生长因子;其透明的装置可对细胞行为进行跟踪观察等研究细胞微环境中占有优势,从而受到越来越多干细胞研究者的关注。结合对微流控技术研究经验,对干细胞微环境构建所需条件进行了综述,总结了微流控在干细胞研究中所取得的成果,并展望了微流控技术在干细胞研究中的应用前景。     

Stem cells in microfluidics

With the introduction of microtechnology and microfluidic platforms for cell culture, stem cell research can be put into a new context. Inside microfluidics, microenvironments can be more precisely controlled and their influence on cell fate studied. Microfluidic devices can be made transparent and the cells monitored real time by imaging, using fluorescence markers to probe cell functions and cell fate. This article gives a perspective on the yet untapped utility of microfluidic devices for stem cell research. It will guide the biologists through some basic microtechnology and the application of microfluidics to cell research, as well as highlight to the engineers the cell culture capabilities of microfluidics. © 2009 American Institute of Chemical Engineers Biotechnol. Prog., 2009     

“Connecting worlds – a view on microfluidics for a wider application”

From its birth, microfluidics has been referenced as a revolutionary technology and the solution to long standing technological and sociological issues, such as detection of dilute compounds and personalized healthcare. Microfluidics has for example been envisioned as: (1) being capable of miniaturizing industrial production plants, thereby increasing their automation and operational safety at low cost; (2) being able to identify rare diseases by running bioanalytics directly on the patient’s skin; (3) allowing health diagnostics in point-of-care sites through cheap lab-on-a-chip devices. However, the current state of microfluidics, although technologically advanced, has so far failed to reach the originally promised widespread use.In this paper, some of the aspects are identified and discussed that have prevented microfluidics from reaching its full potential, especially in the chemical engineering and biotechnology fields, focusing mainly on the specialization on a single target of most microfluidic devices and offering a perspective on the alternate, multi-use, “plug and play” approach. Increasing the flexibility of microfluidic platforms, by increasing their compatibility with different substrates, reactions and operation conditions, and other microfluidic systems is indeed of surmount importance and current academic and industrial approaches to modular microfluidics are presented. Furthermore, two views on the commercialization of plug-and-play microfluidics systems, leading towards improved acceptance and more widespread use, are introduced. A brief review of the main materials and fabrication strategies used in these fields, is also presented. Finally, a step-wise guide towards the development of microfluidic systems is introduced with special focus on the integration of sensors in microfluidics. The proposed guidelines are then applied for the development of two different example platforms, and to three examples taken from literature.With this work, we aim to provide an interesting perspective on the field of microfluidics when applied to chemical engineering and biotechnology studies, as well as to contribute with potential solutions to some of its current challenges.     

Layer-by-layer Collagen Deposition in Microfluidic Devices for Microtissue Stabilization

Although microfluidics provides exquisite control of the cellular microenvironment, culturing cells within microfluidic devices can be challenging. 3D culture of cells in collagen type I gels helps to stabilize cell morphology and function, which is necessary for creating microfluidic tissue models in microdevices. Translating traditional 3D culture techniques for tissue culture plates to microfluidic devices is often difficult because of the limited channel dimensions. In this method, we describe a technique for modifying native type I collagen to generate polycationic and polyanionic collagen solutions that can be used with layer-by-layer deposition to create ultrathin collagen assemblies on top of cells cultured in microfluidic devices. These thin collagen layers stabilize cell morphology and function, as shown using primary hepatocytes as an example cell, allowing for the long term culture of microtissues in microfluidic devices.     

System Integration - A Major Step toward Lab on a Chip

Microfluidics holds great promise to revolutionize various areas of biological engineering, such as single cell analysis, environmental monitoring, regenerative medicine, and point-of-care diagnostics. Despite the fact that intensive efforts have been devoted into the field in the past decades, microfluidics has not yet been adopted widely. It is increasingly realized that an effective system integration strategy that is low cost and broadly applicable to various biological engineering situations is required to fully realize the potential of microfluidics. In this article, we review several promising system integration approaches for microfluidics and discuss their advantages, limitations, and applications. Future advancements of these microfluidic strategies will lead toward translational lab-on-a-chip systems for a wide spectrum of biological engineering applications.     

Helical spring template fabrication of cell‐laden microfluidic hydrogels for tissue engineering

Cell‐laden microfluidic hydrogels find great potential applications in microfluidics, tissue engineering, and drug delivery, due to their ability to control mass transport and cell microenvironment. A variety of methods have been developed to fabricate hydrogels with microfluidic channels, such as molding, bioprinting, and photopatterning. However, the relatively simple structure available and the specific equipment required limit their broad applications in tissue engineering. Here, we developed a simple method to fabricate microfluidic hydrogels with helical microchannels based on a helical spring template. Results from both experimental investigation and numerical modeling revealed a significant enhancement on the perfusion ability and cell viability of helical microfluidic hydrogels compared to those with straight microchannels. The feasibility of such a helical spring template method was also demonstrated for microfluidic hydrogels with complex three‐dimensional channel networks such as branched helical microchannels. The method presented here could potentially facilitate the development of vascular tissue engineering and cell microenvironment engineering. Biotechnol. Bioeng. 2013; 110: 980–989. © 2012 Wiley Periodicals, Inc.     

Simple and Versatile 3D Printed Microfluidics Using Fused Filament Fabrication

The uptake of microfluidics by the wider scientific community has been limited by the fabrication barrier created by the skills and equipment required for the production of traditional microfluidic devices. Here we present simple 3D printed microfluidic devices using an inexpensive and readily accessible printer with commercially available printer materials. We demonstrate that previously reported limitations of transparency and fidelity have been overcome, whilst devices capable of operating at pressures in excess of 2000 kPa illustrate that leakage issues have also been resolved. The utility of the 3D printed microfluidic devices is illustrated by encapsulating dental pulp stem cells within alginate droplets; cell viability assays show the vast majority of cells remain live, and device transparency is sufficient for single cell imaging. The accessibility of these devices is further enhanced through fabrication of integrated ports and by the introduction of a Lego^®-like modular system facilitating rapid prototyping whilst offering the potential for novices to build microfluidic systems from a database of microfluidic components.     

Applications of microfluidics in chemical biology

This review discusses the application of microfluidics in chemical biology. It aims to introduce the reader to microfluidics, describe characteristics of microfluidic systems that are useful in studying chemical biology, and summarize recent progress at the interface of these two fields. The review concludes with an assessment of future directions and opportunities of microfluidics in chemical biology.     

Ultrahigh-throughput screening of industrial enzyme-producing strains by droplet-based microfluidic system

Droplet-based microfluidics has emerged as a powerful tool for single-cell screening with ultrahigh throughput, but its widespread application remains limited by the accessibility of a droplet microfluidic high-throughput screening (HTS) platform, especially to common laboratories having no background in microfluidics. Here, we first developed a microfluidic HTS platform based on fluorescence-activated droplet sorting technology. This platform allowed (i) encapsulation of single cells in monodisperse water-in-oil droplets; (ii) cell growth and protein production in droplets; and (iii) sorting of droplets based on their fluorescence intensities. To validate the platform, a model selection experiment of a binary mixture of Bacillus strains was performed, and a 45.6-fold enrichment was achieved at a sorting rate of 300 droplets per second. Furthermore, we used the platform for the selection of higher α-amylase-producing Bacillus licheniformis strains from a mutant library generated by atmospheric and room temperature plasma mutagenesis, and clones displaying over 50% improvement in α-amylase productivity were isolated. This droplet screening system could be applied to the engineering of other industrially valuable strains.     

Disposable microfluidic devices: fabrication, function, and application

This review article describes recent developments in microfluidics, with special emphasis on disposable plastic devices. Included is an overview of the common methods used in the fabrication of polymer microfluidic systems, including replica and injection molding, embossing, and laser ablation. Also described are the different methods by which on-chip operations--such as the pumping and valving of fluid flow, the mixing of different reagents, and the separation and detection of different chemical species--have been implemented in a microfluidic format. Finally, a few select biotechnological applications of microfluidics are presented to illustrate both the utility of this technology and its potential for development in the future.     

Microfluidic: An innovative tool for efficient cell sorting

At first mostly dedicated to molecular analysis, microfluidic systems are rapidly expanding their range of applications towards cell biology, thanks to their ability to control the mechanical, biological and fluidic environment at the scale of the cells. A number of new concepts based on microfluidics were indeed proposed in the last ten years for cell sorting. For many of these concepts, progress remains to be done regarding automation, standardization, or throughput, but it is now clear that microfluidics will have a major contribution to the field, from fundamental research to point-of-care diagnosis. We present here an overview of cells sorting in microfluidics, with an emphasis on circulating tumor cells. Sorting principles are classified in two main categories, methods based on physical properties of the cells, such as size, deformability, electric or optical properties, and methods based on biomolecular properties, notably specific surface antigens. We document potential applications, discuss the main advantages and limitations of different approaches, and tentatively outline the main remaining challenges in this fast evolving field.