基于环介导等温扩增技术的微流控芯片在病原菌检测方面的研究进展

环介导等温扩增(LAMP)技术是一种新兴的核酸恒温扩增技术,与微流控芯片技术相结合,可实现对病原菌的快速检测,具有特异性强、灵敏度高、操作简单等优点。本文根据不同终产物的检测方法对目前检测病原菌的相关微流控LAMP芯片进行了分类与介绍,并对技术的改进和存在的问题进行了分析,以期为后续的相关研究提供参考。     

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。     

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。     

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...     

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。     

基于核酸等温扩增的病原微生物微流控检测技术

病原微生物的快速检测对疫情的预防控制至关重要。基于PCR的病原微生物核酸检测方法克服了传统病原微生物培养方法耗时长、免疫学检测存在窗口期等问题,已成为目前最主要的病原微生物筛查方法。然而,对精确控温热循环仪的依赖却严重限制了其在资源匮乏地区的应用。虽然基于核酸等温扩增的病原微生物检测方法可摆脱对高精度温控设备的依赖,但仍需要进行样本核酸分离提取、扩增与检测等步骤。近年来,微流控技术与核酸等温扩增技术相结合,诞生了多种病原微生物等温扩增微流控检测技术。该技术通过设计芯片结构、优化进样模式及检测方式,实现了病原微生物核酸提取、扩增与检测一体化,并具备多重检测、定量检测等功能,具有对仪器依赖度小、对操作人员要求不高、样本量需求小和自动化程度高等优点,适合于在多种环境下的病原微生物快速检测。本文从核酸等温扩增原理、进样方式、检测方式等方面对核酸等温扩增病原微生物微流控检测技术进行了综述,以期为病原微生物的快速筛查提供更多的方案思路,提升公共卫生领域对传染性疾病的防控能力。     

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。     

快速STR分型在法医DNA分析中的应用研究进展

STR分型是目前世界通用的DNA指纹分析方法.传统的分型方法包括DNA提取、DNA定量、PCR扩增和对扩增后的STR片段进行检测和分析,耗时较长(8¹0 h).一些情况下很难满足案件的实际需求.法医学家们在加快STR分型的方法研究一直不懈努力.现从快速提取DNA、无提取直接PCR、快速PCR、微流控芯片技术在STR快速分型方面的应用四方面,对近年来出现的可进行快速STR分型的新技术、新方法进行综述.     

用于新型冠状病毒检测的核酸等温扩增技术研究进展

核酸检测作为新型冠状病毒肺炎(COVID-19)筛查诊断和病情监测的主要手段,在疫情防控中发挥了重要作用。虽然实时荧光定量PCR被认为是新型冠状病毒(SARS-CoV-2)核酸检测的金标准,但其依赖荧光定量PCR仪且扩增检测时间较长,难以实现现场快速检测。因此许多基于核酸等温扩增的SARS-CoV-2检测方法相继诞生。等温扩增对仪器温控要求不高,通过与微流控芯片和可视化检测技术结合,可进一步简化操作、降低成本,为SARS-CoV-2现场快速筛查提供有力的技术支撑。本文围绕已报道的SARS-CoV-2等温扩增检测方法原理、检测性能及优缺点进行探讨,为进一步发展SARS-CoV-2现场快速检测平台提供参考。     

连续流动式PCR微流控装置的研究

介绍了基于薄膜加热器的新型连续流动式PCR微流控装置的设计与制作;讨论了退火温度、PCR反应试剂(引物、Mg2 、dNTPs以及Taq DNA聚合酶)浓度以及PCR溶液的流动速度等对连续流动式PCR反应的影响;结果发现反应试剂影响连续流动式微流控PCR扩增的行为不同于它们影响传统PCR的行为,在较宽的浓度范围内都不会引起非特异性扩增。除此之外,在15 min内能成功对249 bp的人类β-肌动蛋白基因进行扩增,扩增速度比传统PCR快;通过低热容量的薄膜加热器来维持三个温度区带的恒温,完成33个循环的连续流动式PCR扩增能量消耗小于0.0088 kW.h,比传统PCR仪低得多,新研制的PCR微流控装置有可能成为便携式装置。     

几种新型生物芯片的研究进展

随着生物芯片技术的迅速发展,一些新型生物芯片,如生物电子芯片、凝胶元件微阵列芯片、药物控释芯片、毛细管电泳或层析芯片、PCR芯片及生物传感芯片等应运而生,这些芯片不同于常规的分子微阵列芯片,而是以各种结构微阵列为基础,用于分子杂交与扩增,以检测突变、分析多态性及测序,通过电泳及层析分离生物样品,控制药物释放以治疗疾病,作为生物传感器检测分子行为等,具有分析速度快、效率高、样品消耗少等特点,将成为生命科学与医学领域的新工具.     

Ultra-rapid flow-through polymerase chain reaction microfluidics using vapor pressure

A novel flow-through polymerase chain reaction (PCR) microfluidic system using vapor pressure was developed that can achieve ultra-rapid, small-volume DNA amplification on a chip. The 40-cycle amplification can be completed in as little as 120 s, making this device the fastest PCR system in the world. The chip device is made of a pressure-sensitive polyolefin (PSP) film and cyclo-olefin polymer (COP) substrate which was processed by cutting-work to fabricate the microchannel. The enclosed structure of the microchannel was fabricated solely by weighing the PSP film on the COP substrate, resulting in superior practical application. The vapor pressure in the denaturation zone of the destabilizing flow source was applied to the flow force, and ultra-rapid, efficient amplification was accomplished with a minimal amount of PCR reagents for detection. The flowing rhythm created by vapor pressure minimized the residual PCR products, leading to highly efficient amplification. For field test analysis, airborne dust was collected from a public place and tested for the presence of anthrax. The PCR chip had sufficient sensitivity for anthrax identification. The fastest time from aerosol sampling to detection was theoretically estimated as 8 min.     

Isotachophoresis preconcentration integrated microfluidic chip for highly sensitive genotyping of the hepatitis B virus

The genotyping of hepatitis B virus (HBV) has become recently a valuable tool not only for epidemiological reasons but also for the clinical practice. Conventional methods for HBV genotyping typically include amplification of the target DNA sequences with a two-round nested PCR followed by separation of the amplified fragments by gel electrophoresis. A microfluidic chip that couples isotachophoresis (ITP) preconcentration and zone electrophoresis (ZE) separation may provide great advantages for sensitive, rapid and cost-effective clinical analysis. In this study, an HBV genotyping method with only one amplification round was developed by the application of the ITP-ZE chip. All the analysis steps of the ITP-ZE separation including sample injection, stacking and separation were performed continuously, controlled by sequential high-voltage switching. A 2.1cm sample plug was preconcentrated between discontinuous buffers in ITP process, followed by ZE separation. Sensitivity enhancement was obtained through the increase of sample loading volume. The average LOD value of the ITP-ZE microfluidic chip was determined to be 0.0021pg/muL. In a large-scale HBV genotyping test, single round PCR products were analyzed by ITP-ZE microfluidic chip, and the results were compared with that of the conventional method. Among the 200 cases studied, the classification rate obtained with microfluidic chip was 93%, which was 6% higher than that obtained with the conventional method. Method with ITP-ZE chip analysis provides HBV genotyping information in reduced PCR amplification time with higher detection rate when compared with conventional method. This method holds great potential for extrapolation to the abundance of similar molecular biology-based techniques in clinical diagnosis.     

Design of a multiplex PCR for genotyping 16 short tandem repeats in degraded DNA samples

The molecular genotyping of individuals and reconstruction of kinship through short and high polymorphic DNA markers, so-called short tandem repeats (STR), has become an important and efficient method in anthropology and forensic science. The here introduced experimental design describes a multiplex PCR capable of simultaneously amplifying 16 STRs and the sex determinant locus amelogenin in a short fragment lengths range from 84 bp to 275 bp. Thus, the design depends predominantly on the routines for DNA typing of historical samples with highly degraded ancient DNA. It is shown, that the newly designed multiplex PCR is suitable for successful typing of both forensic and historical material.     

应用RD-PCR技术制备HIV基因芯片探针

利用限制性显示 (RD PCR)技术快速分离HIV 1基因片段制备DNA芯片探针 .以Sau3AⅠ酶切HIV基因 ,得到许多大小适合芯片的限制性酶切片段 .然后在片段两端接上接头 ,根据酶切位点、接头的序列设计通用引物 .在该通用引物的 3′端分别延伸一个碱基后 ,通过引物间的两两组合 ,将PCR反应分成 10个亚组 .纯化各组PCR产物 ,克隆到T载体上 .阳性克隆经鉴定、扩大培养后提取质粒 .以质粒为模板扩增靶片段并进行序列分析 .每个亚型得到了十几个 10 0～ 10 0 0bp的HIV基因片段 .研究表明 ,RD PCR技术是一种有效的快速制备基因芯片探针的方法     

Plastic microfluidic chip for continuous-flow polymerase chain reaction: simulations and experiments

A continuous flow polymerase chain reaction (CF-PCR) device comprises a single fluidic channel that is heated differentially to create spatial temperature variations such that a sample flowing through it experiences the thermal cycling required to induce amplification. This type of device can provide an effective means to detect the presence of a small amount of nucleic acid in very small sample volumes. CF-PCR is attractive for global health applications due to its less stringent requirements for temperature control than for other designs. For mass production of inexpensive CF-PCR devices, fabrication via thermoplastic molding will likely be necessary. Here we study the optimization of a PCR assay in a polymeric CF-PCR device. Three channel designs, with varying residence time ratios for the three PCR steps (denaturation, annealing, and extension), were modeled, built, and tested. A standardized assay was run on the three different chips, and the PCR yields were compared. The temperature gradient profiles of the three designs and the residence times of simulated DNA molecules flowing through each temperature zone were predicted using computational methods. PCR performance predicted by simulation corresponded to experimental results. The effects of DNA template size and cycle time on PCR yield were also studied. The experiments and simulations presented here guided the CF-PCR chip design and provide a model for predicting the performance of new CF-PCR designs prior to actual chip manufacture, resulting in faster turn around time for new device and assay design. Taken together, this framework of combined simulation and experimental development has greatly reduced assay development time for CF-PCR in our lab.     

Gene-based identification of bacterial colonies with an electric chip

A method for the identification of bacterial colonies based on their content of specific genes is presented. This method does not depend on DNA separation or DNA amplification. Bacillus cereus carrying one of the genes (hblC) coding for the enterotoxin hemolysin was identified with this method. It is based on target DNA hybridization to a capturing probe immobilized on magnetic beads, followed by enzymatic labeling and measurement of the enzyme product with a silicon-based chip. An hblC-positive colony containing 10(7) cells could be assayed in 30 min after ultrasonication and centrifugation. The importance of optimizing the ultrasonication is illustrated by analysis of cell disruption kinetics and DNA fragmentation. An early endpoint PCR analysis was used to characterize the DNA fragmentation as a function of ultrasonication time. The first minutes of sonication increased the signal due to both increased DNA release and increased DNA fragmentation. The latter is assumed to increase the signal due to improved diffusion and faster hybridization of the target DNA. Too long sonication decreased the signal, presumably due to loss of hybridization sites on the targets caused by extensive DNA fragmentation. The results form a basis for rational design of an ultrasound cell disruption system integrated with analysis on chip that will move nucleic acid-based detection through real-time analysis closer to reality.     

Development of a novel nano-Invader DNA chip system

By taking advantage of a homogeneous Invader assay, a miniaturized genotyping chip system termed nano-Invader was developed. The system is sensitive to 0.1 zeptomole of genomic DNA per well without prior PCR amplification. Its accuracy was determined by comparing both the genomic DNA chip and probe chip formats to PCR-RFLP. To determine the assay's capabilities in large-scale analysis, DNA samples from the Coriell Cell Repository and an additional 62-probe sets were tested with the genomic DNA and probe chip nano-Invader formats, respectively. Several hundred samples were genotyped in less than an hour, from purified genomic DNA to data analysis. With its ease of handling, speed, accuracy, sensitivity and cost-effectiveness, this chip system, especially its probe chip format, will meet a demand for high-throughput multiple genotyping in the coming era of personalized medicine.     

Development of a novel nano-Invader DNA chip system

By taking advantage of a homogeneous Invader assay, a miniaturized genotyping chip system termed nano-Invader was developed. The system is sensitive to 0.1 zeptomole of genomic DNA per well without prior PCR amplification. Its accuracy was determined by comparing both the genomic DNA chip and probe chip formats to PCR-RFLP. To determine the assay's capabilities in large-scale analysis, DNA samples from the Coriell Cell Repository and an additional 62-probe sets were tested with the genomic DNA and probe chip nano-Invader formats, respectively. Several hundred samples were genotyped in less than an hour, from purified genomic DNA to data analysis. With its ease of handling, speed, accuracy, sensitivity and cost-effectiveness, this chip system, especially its probe chip format, will meet a demand for high-throughput multiple genotyping in the coming era of personalized medicine.     

新型Taq Man-MGB探针在结核分枝杆菌实时PCR检测中的应用

为建立一种比现有方法敏感、准确性高、重复性好的结核分枝杆菌DNA定性定量检测方法 ,以TaqMan探针技术为基础 ,运用TaqMan MGB探针 ,实时检测临床标本中的结核分枝杆菌DNA .用来自临床标本的DNA及克隆于载体的IS6 1 1 0序列检测所建立方法的有效性 .结果显示 ,所建立方法的最低检测限度为 1个基因拷贝 反应 ,在每反应 1 0 0 ～ 1 0 8拷贝范围内 ,Ct 值同DNA量的对数呈线性关系 .同一模板不同时间或同一时间不同管内扩增 ,所得Ct 值恒定 .用该方法检测 37例结核分枝杆菌培养阳性的痰液标本 ,敏感度为 1 0 0 % ;用该方法检测 1 6例TB系列阴性参考品 ,特异性为1 0 0 % .结果表明 ,所建立的方法是用于结核分枝杆菌定性定量检测较理想的方法