微流控芯片在水环境污染分析中的应用

近年来,一种新型技术——微流控芯片技术因其分析速度快、消耗低、体积小、操作简单等特点而备受世界各国的广泛重视.该技术以微通道网络为基本特征,以微机电系统(MEMS)工艺为技术依托,将整个实验室的功能集成在微小芯片上,即构成所谓“芯片实验室”.本文从该技术的基本情况出发,介绍了微流控芯片的发展,并从仪器小型化、系统集成化、不同的芯片材料以及多种检测技术等方面,着重讨论了其在水环境污染分析方面的实际应用和发展前景,指出了它当前所面临的一些问题.随着微流控芯片的不断发展,高速多通道检测装置、低成本设备以及集成了多种方法的高通用性微流控检测芯片,都将成为未来研究的热点.     

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。     

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。     

微流控芯片技术在食品领域中的应用

微流控芯片技术是一种全新的微量分析技术。介绍了微流控芯片技术的基本原理、特点及分类,并深入讨论了该技术在食品安全、营养、加工和风味等食品领域中的应用,包括有害化学物质、食品添加剂、转基因食品和食源性致病微生物等的检测,营养物质和功能成分的分析鉴定,食品工艺参数的调控以及食品风味成分的检测,展望了微流控芯片技术在食品领域的广阔应用前景。     

微流控分析芯片在医学领域的应用

微全分析系统(μ_TAS)又称为芯片实验室,自从Manz等于20世纪90年代首次提出这一概念以来,经过十余年的发展μ_TAS已成为生物分析的一个独立领域并被学术界所认可。微流控分析芯片作为μ_TAS发展的主要方向以其快速、高效分析,低消耗和微型化等特点发展非常迅速。在此结合微流控分析芯片在医学领域的应用状况,着重从基因检测、蛋白质分析和细胞分析等方面,对该技术在医学领域里的应用及其未来发展趋势作一综述。     

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。     

基于微流控芯片的核酸等温扩增技术研究进展

核酸等温扩增技术是一种在恒温体系内对核酸进行高效扩增的分子扩增技术,它能够在短时间内实现目的基因的指数增长。微流控芯片(microfluidic chip)技术是把研究样品制备、核酸富集、纯化和检测等多个操作步骤集成到一块"微型化"的芯片上,经自动化处理,得出实验结果,即"样品进,结果出"。将核酸等温扩增技术与微流控芯片相结合,不仅可以实现核酸快速扩增,还可以降低对实验器材的依赖。在床边即时诊断、病原体快速筛查中具有广阔的应用前景。综合国内外相关研究报道,综述了各种等温扩增技术原理,以及基于微流控芯片的核酸等温扩增技术应用,展望了集成化微流控芯片的发展趋势和应用前景。     

条形码微流控芯片在分泌蛋白检测方面的应用

微流控芯片具有液体流动可控、消耗试样少、分析速度快等特点,它可以在几分钟甚至更短的时间内进行上百个样品的同时分析,并且可以实现在线样品的预处理及分析全过程。一种条形码微流控芯片能够以高密度的单链DNA为模板,从而克服了传统蛋白质微流控芯片固定在固体表面容易变性的缺点,既解决了稳定性的要求,又满足芯片平行处理大量数据的要求,可以用来大量的、快速的定量检测细胞的分泌蛋白。条形码微流控芯片因其对样品要求简单、低耗高效、高通量等特点正在成为分泌蛋白检测的最具吸引力的分析工具,在样品分析与检测以及临床检测研究等领域得到了广泛的应用。     

基于微流控芯片的秀丽隐杆线虫的研究进展

微流控芯片技术作为近年来最前沿的分析技术之一,已经在化学、生物学、医药学等研究领域取得了突破性的进展.微流控芯片具有高通量、微型化和多功能集成化等独特优势,已经成为生物医学研究的新平台之一,被越来越多地应用于秀丽隐杆线虫的研究.综述了基于微流控芯片上的秀丽隐杆线虫在生物医学领域中的研究进展,侧重介绍了微流控芯片在线虫的自动化固定、行为学、衰老与发育学、神经学、药物筛选及基因筛选等六大方面所取得的最新进展,并展望了微流控芯片的应用前景.     

聚合物微流控芯片消毒灭菌技术研究进展

聚合物微流控芯片成本低、易加工,目前在医药、生物检测和化学合成等领域得到了普遍应用。以热塑性聚合物聚甲基丙烯酸甲酯(polymethylmethacrylate,PMMA)和热固型聚合物聚二甲基硅氧烷(polydimethy lsiloxane,PDMS)为基材的高分子聚合物材料因具有较好的生物相容性和光学透明性,已逐渐成为聚合物微流控芯片加工的主导材料,被广泛应用于生物医药类微流控芯片的制备。鉴于该类芯片应用场景的特殊性,需在使用前进行消毒灭菌处理以避免微生物干扰。目前,针对PMMA和PDMS的消毒灭菌方法包括高压蒸汽灭菌、紫外线灭菌、电子束、60Co γ射线辐射灭菌、超临界二氧化碳灭菌、乙醇消毒、环氧乙烷灭菌、过氧化氢低温等离子体灭菌、绿原酸消毒、清洗剂消毒。本文从基本原理、消毒灭菌方法、应用场景等方面,回顾和总结了相关技术在PMMA和PDMS基体微流控芯片中的实现方法,并在芯片材质、适用范围等方面分析了所适用的消毒灭菌方法,为以聚合物为基材的生物医药类微流控芯片的消毒灭菌提供有益参考。     

Microfluidic lab-on-a-chip for microbial identification on a DNA microarray

A lab-on-a-chip for the rapid identification of microbial species has been developed for a water monitoring system. We employed highly parallel DNA microarrays for the direct profiling of microbial populations in a sample. For the integration and minimization of the DNA microarray protocols for bacterial identification, rRNA was selected as a target nucleotide for probe:target hybridization. In order to hybridize target rRNA onto the probe oligonucleotide, intact rRNA extracted fromE. coli rRNA was fragmented via chemical techniques in the lab-on-a-chip platform. The size of fragmented rRNA was less than 400 base pairs, which was confirmed by polyacrylamide gel electrophoresis. The fragmented rRNA was also labeled using fluorescent chemicals. The lab-on-a-chip for fragmentation and labeling includes a PDMS chaotic mixer for efficient mixing, operated by flow pressure. In addition, the fragmented rRNA was hybridized successfully on a DNA microarray with sample recirculation on a microfluidic platform. Our fragmentation and labeling technique will have far-reaching applications, which require rapid but complicated chemical genetic material processing on a lab-on-a-chip platform.     

Adapting arrays and lab-on-a-chip technology for proteomics

The impact of proteomics as a discovery engine in life science and in drug discovery has increased tremendously over the last seven years. At the same time, proteomics has expanded from the initial trust as a two-dimensional gel based approach to cover more functional and structural properties of proteins. The development of lab-on-a-chip and protein arrays for proteomics will have to evolve with the changes in proteomics to stay relevant. Here, we review the changes in the field of proteomics and their impact on the development in protein arrays and lab-on-a-chip.     

Microfluidic device for bio analytical systems

Micro-fluidics is one of the major technologies used in developing micro-total analytical systems (μ-TAS), also known as “lab-on-a-chip”. With this technology, the analytical capabilities of room-size laboratories can be put on one small chip. In this paper, we will briefly introduce materials that can be used in micro-fluidic systems and a few modules (mixer, chamber, and sample prep. modules) for lab-on-a-chip to analyze biological samples. This is because a variety of fields have to be combined with micro-fluidic technologies in order to realize lab-on-a-chip.     

Development of a lab-on-a-chip device for diagnosis of plant pathogens

A lab-on-a-chip system for rapid nucleic acid-based analysis was developed that can be applied for diagnosis of selected Phytophthora species as a first example for use in plant pathology. All necessary polymerase chain reaction process (PCR) and hybridization steps can be performed consecutively within a single chip consisting of two components, an inflexible and a flexible one, with integrated microchannels and microchambers. Data from the microarray is collected from a simple electrical measurement that is based on elementary silver deposition by enzymatical catalyzation. Temperatures in the PCR and in the hybridization zone are managed by two independent Peltier elements. The chip will be integrated in a compact portable system with a pump and power supply for use on site. The specificity of the lab-on-a-chip system could be demonstrated for the tested five Phytophthora species. The two Pythium species gave signals below the threshold. The results of the electrical detection of the microarray correspond to the values obtained with the control method (optical grey scale analysis).     

Grating on Plasmonic Nanosheet Structure for Multi-Stopband Filtering and Narrowband Emission

Plasmonics - Abstract The narrowband emission at microscale regime is a crucial technology need in view of nanophotonic networks and lab-on-a-chip applications. Considering the significance of...     

A microfluidic device for measuring cellular membrane potential

Recent developments in microfluidics have enabled the design of a lab-on-a-chip system capable of measuring cellular membrane potential. The chip accesses liquid samples sequentially by sipping from a microplate through a capillary, mixes the samples with cells flowing through a microchannel, contacts the cells with potential-sensitive dyes, and reads out cellular responses using fluorescence detection. The rate of cellular uptake of membrane-permeable, ionic fluorophores by THP-1 cells was found to depend strongly on membrane potential. The ratio of the fluorescence of the anionic dye DiBAC(4)(3) and the cationic dye Syto 62 taken up by cells was found to double for every 33 mV change in membrane potential. The utility of this approach was demonstrated by assaying ion channel activity in human T lymphocytes. Because of the high sensitivity, low cellular and reagent consumption, and high data quality obtained with the microfluidic device, the lab-on-a-chip system should be widely applicable in high-throughput screening and functional genomics studies.     

Microfluidic device reads up to four consecutive base pairs in DNA sequencing-by-synthesis

We have developed the first fully integrated microfluidic system for DNA sequencing-by-synthesis. Using this chip and fluorescence detection, we have reliably sequenced up to 4 consecutive bps. The described sequencer can be integrated with other microfluidic components on the same chip to produce true lab-on-a-chip technology. The surface chemistry that was designed to anchor the DNA to elastomeric microchannels is useful in a broad range of studies and applications.     

DNA detection by integrable electronics

This paper presents a new electronic methodology to detect DNA hybridization for rapid identification of diseases, as well as food and environmental monitoring on a genetic base. The proposed solution exploits a new (electrical) capacitive measurement circuit, not requiring any prior labeling of the DNA (as it is often the case with the commonly employed optical detection). The sensitivity, the reliability, and the reproducibility of this device have been evaluated by experiments performed with a (non-integrated) prototype implementation, easily integrable in IC and/or micro-fabricated lab-on-a-chip.     

Skeletal myotube integration with planar microelectrode arrays in vitro for spatially selective recording and stimulation: a comparison of neuronal and myotube extracellular action potentials

Microelectrode array (MEA) technology holds tremendous potential in the fields of biodetection, lab-on-a-chip applications, and tissue engineering by facilitating noninvasive electrical interaction with cells in vitro. To date, significant efforts at integrating the cellular component with this detection technology have worked exclusively with neurons or cardiac myocytes. We investigate the feasibility of using MEAs to record from skeletal myotubes derived from primary myoblasts as a way of introducing a third electrogenic cell type and expanding the potential end applications for MEA-based biosensors. We find that the extracellular action potentials (EAPs) produced by spontaneously contractile myotubes have similar amplitudes to neuronal EAPs. It is possible to classify myotube EAPs by biological signal source using a shape-based spike sorting process similar to that used to analyze neural spike trains. Successful spike-sorting is indicated by a low within-unit variability of myotube EAPs. Additionally, myotube activity can cause simultaneous activation of multiple electrodes, in a similar fashion to the activation of electrodes by networks of neurons. The existence of multiple electrode activation patterns indicates the presence of several large, independent myotubes. The ability to identify these patterns suggests that MEAs may provide an electrophysiological basis for examining the process by which myotube independence is maintained despite rapid myoblast fusion during differentiation. Finally, it is possible to use the underlying electrodes to selectively stimulate individual myotubes without stimulating others nearby. Potential uses of skeletal myotubes grown on MEA substrates include lab-on-a-chip applications, tissue engineering, co-cultures with motor neurons, and neural interfaces.     

Bridging the bio-electronic interface with biofabrication

Advancements in lab-on-a-chip technology promise to revolutionize both research and medicine through lower costs, better sensitivity, portability, and higher throughput. The incorporation of biological components onto biological microelectromechanical systems (bioMEMS) has shown great potential for achieving these goals. Microfabricated electronic chips allow for micrometer-scale features as well as an electrical connection for sensing and actuation. Functional biological components give the system the capacity for specific detection of analytes, enzymatic functions, and whole-cell capabilities. Standard microfabrication processes and bio-analytical techniques have been successfully utilized for decades in the computer and biological industries, respectively. Their combination and interfacing in a lab-on-a-chip environment, however, brings forth new challenges. There is a call for techniques that can build an interface between the electrode and biological component that is mild and is easy to fabricate and pattern. Biofabrication, described here, is one such approach that has shown great promise for its easy-to-assemble incorporation of biological components with versatility in the on-chip functions that are enabled. Biofabrication uses biological materials and biological mechanisms (self-assembly, enzymatic assembly) for bottom-up hierarchical assembly. While our labs have demonstrated these concepts in many formats, here we demonstrate the assembly process based on electrodeposition followed by multiple applications of signal-based interactions. The assembly process consists of the electrodeposition of biocompatible stimuli-responsive polymer films on electrodes and their subsequent functionalization with biological components such as DNA, enzymes, or live cells. Electrodeposition takes advantage of the pH gradient created at the surface of a biased electrode from the electrolysis of water. Chitosan and alginate are stimuli-responsive biological polymers that can be triggered to self-assemble into hydrogel films in response to imposed electrical signals. The thickness of these hydrogels is determined by the extent to which the pH gradient extends from the electrode. This can be modified using varying current densities and deposition times. This protocol will describe how chitosan films are deposited and functionalized by covalently attaching biological components to the abundant primary amine groups present on the film through either enzymatic or electrochemical methods. Alginate films and their entrapment of live cells will also be addressed. Finally, the utility of biofabrication is demonstrated through examples of signal-based interaction, including chemical-to-electrical, cell-to-cell, and also enzyme-to-cell signal transmission. Both the electrodeposition and functionalization can be performed under near-physiological conditions without the need for reagents and thus spare labile biological components from harsh conditions. Additionally, both chitosan and alginate have long been used for biologically-relevant purposes. Overall, biofabrication, a rapid technique that can be simply performed on a benchtop, can be used for creating micron scale patterns of functional biological components on electrodes and can be used for a variety of lab-on-a-chip applications.