共查询到19条相似文献,搜索用时 203 毫秒
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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。 相似文献
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微流控分析芯片在医学领域的应用 总被引:5,自引:0,他引:5
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。 相似文献
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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。 相似文献
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微流控芯片技术是指一种将生物、化学等诸多领域的样品从制备、反应到分离检测等多种操作单元高度集成在一块芯片上的技术,由网络状微通道构成,可以通过流体操控整个系统。相比构建模型的传统方法, 具有便携性、高通量、可模拟在体微环境等优势,在研究疾病的诊断、发病机理研究以及药物筛选等方面有着广阔的应用前景。肺部炎性疾病是临床常见的多发病,通常由于细菌、病毒、真菌感染引起。早期肺炎常缺乏明显的呼吸系统症状且症状多不典型,但病情进展快,难以诊断。近年来,微流控芯片技术已经逐渐用于肺部炎性疾病的研究中。尤其是可以再现人肺泡毛细血管界面 (即活肺的基本功能单元) 的关键结构、功能和机械性质的“芯片肺”模型的应用,很好地在体外呈现了肺泡-毛细血管界面模型的生理相关性。相比细胞和动物模型,这种多功能微实验平台具有非常大的优势。文中针对微流控芯片技术在肺部炎性疾病研究和诊断中的进展进行了综述,旨在为肺部炎性疾病的研究和诊断提供新思路。 相似文献
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磁珠以其比表面积大、易与生物分子耦联、操控方便等优点,在生命科学中得到了广泛应用。随着微机电系统(MicroElectroMechanicalSystems,MEMS)技术的发展,将磁珠应用到微流控芯片中构建磁珠微流控分析系统,为生物样品分离、检测提供了一种全新方法。新一代植物志iFlora融入现代DNA测序技术.应用高速发展的信息、网络技术及云计算分析平台,收集、整合和管理植物物种相关信息,以实现物种智能鉴定和数据提取,而包括DNA条形码在内的遗传信息及其获取技术在iFlora中的作用至关重要。本文重点概述了基于纳米磁珠的微流控芯片技术及其在分子生物学领域中的应用,提出构建基于纳米磁珠微流控芯片的iFlora遗传信息采集系统,在微芯片上完成从DNA提取到测序全过程,实现物种遗传信息的快速、高效获取。 相似文献
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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。 相似文献
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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. 相似文献
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微流控芯片技术在药物研究尤其是天然产物活性成分高通量筛选方面得到越来越广泛的应用,本文主要讨论了微流控芯片技术的发展以及在天然产物研究与开发方面的应用,并对其应用现状进行了分析。 相似文献
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This study reports the development of an on-chip enzyme-mediated primer extension process based on a microfluidic device with microbeads array for single-nucleotide discrimination using quantum dots as labels. The functionalized microbeads were independently introduced into the arrayed chambers using the loading chip slab. A single channel was used to generate weir structures to confine the microbeads and make the beads array accessible by microfluidics. The applied allele-specific primer extension method employed a nucleotide-degrading enzyme (apyrase) to achieve specific single-nucleotide detection. Based on the apyrase-mediated allele-specific primer extension with quantum dots as labels, on-chip single-nucleotide discrimination was demonstrated with high discrimination specificity and sensitivity (0.5 pM, signal/noise > 3) using synthesized target DNA. The chip-based signal enhancement for single-nucleotide discrimination resulted in 200 times higher sensitivity than that of an off-chip test. This microfluidic device successfully achieved simultaneous detection of two disease-associated single-nucleotide polymorphism sites using polymerase chain reaction products as target. This apyrase-mediated microfluidic primer extension approach combines the rapid binding kinetics of homogeneous assays of suspended microbeads array, the liquid handling capability of microfluidics, and the fluorescence detection sensitivity of quantum dots to provide a platform for single-base analysis with small reagent consumption, short assay time, and parallel detection. 相似文献
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Microfluidics has become an important tool in diagnosing many diseases, including neurological and genetic disorders. Alzheimer's
disease (AD) is a neurodegenerative disease that irreversibly and progressively destroys memory, language ability, and thinking
skills. Commonly, detection of AD is expensive and complex. Fluorescence in situ hybridization (FISH)-based microfluidic chip
platform is capable of diagnosing AD at an early stage and they are effective tools for the diagnosis with low cost, high
speed, and high sensitivity. In this review, we tried to provide basic information on the diagnosis of AD via FISH-based microfluidics.
Different sample preparations using a microfluidic chip for diagnosis of AD are highlighted. Moreover, rapid innovations in
nanotechnology for diagnosis are explained. This review will provide information on dynamic quantification methods for the
diagnosis and treatment of AD. The knowledge provided in this review will help develop new integration diagnostic techniques
based on FISH and microfluidics. 相似文献
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Carson L Cathcart GR Ceri H Walker B Gilmore BF 《Biochemical and biophysical research communications》2012,419(2):316-320
Nanospheres lithographic (NSL) method has been used to fabricate nano-structured arrays (NAs) of hexagonally close-packed gold (Au) using polystyrene beads [PS, diameter ~300 nm] as mask. The developed NA was incorporated with a customized and cheap microfluidics system to demonstrate its applicability as an alternative easy and efficient platform for multiplex analysis and Lab-on-a-Chip applications. The chip functionality was demonstrated with horseradish peroxidase (HRP) and anti-HRP antibody as model for recognition system. The enzyme-linked immunosorbent assay (ELISA) performed on fabricated protein biochip had a detection limit 100 pg/mL for HRP. The antibody chip was also checked for the shelf-life and it was found that these chips could be stored for 50 days when stored at 4°C without any significant loss of activity. Therefore, NAs based protein biochip with the correct microfluidics could find huge potential application in diagnostics and biosensing technology. 相似文献
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Microfluidics for single cell analysis 总被引:1,自引:0,他引:1
Substantial evidence shows that the heterogeneity of individual cells within a genetically identical population can be critical to their chance of survival. Methods that use average responses from a population often mask the difference from individual cells. To fully understand cell-to-cell variability, a complete analysis of an individual cell, from its live state to cell lysates, is essential. Highly sensitive detection of multiple components and high throughput analysis of a large number of individual cells remain the key challenges to realise this aim. In this context, microfluidics and lab-on-a-chip technology have emerged as the most promising avenue to address these challenges. In this review, we will focus on the recent development in microfluidics that are aimed at total single cell analysis on chip, that is, from an individual live cell to its gene and proteins. We also discuss the opportunities that microfluidic based single cell analysis can bring into the drug discovery process. 相似文献
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Yacoub-George E Hell W Meixner L Wenninger F Bock K Lindner P Wolf H Kloth T Feller KA 《Biosensors & bioelectronics》2007,22(7):1368-1375
The automated 10-channel capillary chip immunodetector (10K-IDWG) is a prototype, which has been developed for automatically operated biological agents (BA) point detection. The current technology uses a chemiluminescence capillary immunoassay (EIA) technique in combination with integrated microfluidics and allows the highly sensitive and rapid detection and preliminary identification of multiple BA in aqueous solutions in the laboratory. The chemiluminescence capillary EIA are performed within a disposable capillary chip containing 10 fused-silica capillaries arranged in parallel coated with selected capture antibodies. A multianode-photomultiplier array is used to detect chemiluminescence intensity in each capillary. Reservoirs for reagents and buffers and a waste disposal reservoir are integrated. This paper describes the technology of the 10K-IDWG and its evaluation with three different BA, the toxin staphylococcal enterotoxin B (SEB), the bacterial analyte Escherichia coli (E. coli) O157:H7 as a model for bacterial pathogens, and the bacteriophage M13 as a model for virus pathogens. The 10K-IDWG is able to detect the above mentioned three BA in an aqueous sample within 29 min (single analyte-detection and multiplexing). Limits of detection (LOD) are 0.1 ng/ml for SEB, 10(4)cfu/ml for E. coli O157:H7, and 5x10(5) pfu/ml for M13. Cross reactivities between the three assays were not observed. 相似文献
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Perfusion flow is one of the essential elements and advantages of organ-on-a-chip technology. For example, microfluidics have enabled implementation of perfusion flow and recapitulation of fluidic environment for vascular endothelial cells. The most prevalent method of implementing flow in a chip is to use a pump, which requires elaborate manipulation and complex connections, and accompanies a large amount of dead volume. Previously we devised a gravity-induced flow system which does not require tubing connections, but this method results in bidirectional flow to enable recirculation, which is somewhat different from physiological blood flow. Here, we have developed a novel microfluidic chip that enables gravity-induced, unidirectional flow by using a bypass channel with geometry different from the main channel. Human umbilical vein endothelial cells were cultured inside the chip and the effect of flow direction was examined. © 2018 American Institute of Chemical Engineers Biotechnol. Prog., 35: e2701, 2019 相似文献
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Anett Reichert Jana Felbel Mark Kielpinski Matthias Urban Benno Steinbrecht Thomas Henkel 《仿生工程学报(英文版)》2008,5(4):291-298
Chip-based flow-through PCR implements the PCR as a continuous process for nucleic acid analytics. The sample is transported in a winding channel through temperature zones required for denaturation, annealing and extension. Main fields of application are the monitoring of continuous processes for rapid identification of contaminants and quality control as well as high throughput screening of cells or microorganisms. A modular arrangement with five heating zones for flow-through PCR is discussed and evaluated. The special heater arrangement allows the implementation of up to 40 cycles on the footprint of a microscope slide, which is placed on top ofa 5 zones heating plate. Liquid/liquid two phase flow of PCR reaction mixture and mineral oil have been applied to create a segmented flow process scheme. In that way, the developed system may provide flow-through PCR as a unit operation for the droplet based microfluidics platform. The single use of disposable devices is commonly preferred due to the sensitivity of the PCR process to contaminations. All-glass microfluidic chips and disposable chip devices, made from polycarbonate as a replication with identically geometry, have been fabricated and tested. For the first time, microchannel geometries with nearly circular profile developed by all-glass technology have been transferred to mass fabrication by injection compression molding. Both devices have been successfully applied for the detection of the tumor suppressor gene p53. Although product yield and selectivity of the amplification process do not depend on the chip material, a well defined, reliable segmented flow regime could only be realized in the all-glass chip. 相似文献