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.     

Lab-on-a-chip: applications in proteomics

Recent advances in chip-based separation of proteins provide methods that are faster and more convenient than conventional gel electrophoresis. Rapid and automated protein sizing on a chip is at the commercial stage and first attempts have been made to perform two-dimensional separation on a chip. Numerous designs have been described to interface a microfluidic chip to a mass spectrometer. Impressive integration efforts are demonstrated by the ability to perform on-chip trypsin digestion, separation and injection into a mass spectrometer with a single device.     

Plastic substrates based separation channels in electromigration techniques

Three types of plastic materials (polyester, polyurethane and polymethylmethacrylate) were tested as materials for manufacturing separation columns (polyester and polyurethane capillaries were used) or separation channels (polymethylmethacrylate) in the chip format. A set of 11 fluorescein isothiocyanate amino acid derivatives was used as the test mixture. Using alpha-cyclodextrin additive to the background electrolyte in the case of the chip separation was also tested. The main problem with all plastic separation media was the selectivity of the separation. The best results, practically identical with bare fused silica capillary, were obtained with the polymethylmethacrylate chip, provided that alpha-cyclodextrin in a concentration 40 mmol/l was added to the background electrolyte. An important observation was that in SDS containing background electrolyte all the plastic materials used exhibited a distinct electroosmotic flow, which was ascribe to the sorption of the negatively charged constituents of the background electrolyte to the capillary wall. Regarding the order in which the individual components of the test mixture were brought to the detector only a single change was observed. Histidine migrated in the polystyrene and polymethylmethacrylate separation channels more slowly than in the bare silica or polyurethane based capillaries.     

Development of a high-throughput IMS-IMS-MS approach for analyzing mixtures of biomolecules

A high-throughput approach for biomolecule analysis is demonstrated for a mixture of peptides from tryptic digest of four proteins as well as a tryptic digests of human plasma. In this method a chip based electrospray autosampler coupled to a hybrid ion mobility (IMS) mass spectrometer (MS) is utilized to achieve rapid sample analysis. This high-throughput measurement is realized by exploiting the direct infusion capability of the chip based electrospray with its rapid sample manipulating capability as well as a high sensitive IMS-MS with a recently developed IMS-IMS separation technique that can be multiplexed to provide greater throughput. From replicate IMS-MS runs of known mixtures, the average uncertainty of peak intensities is determined to be +/-7% (relative standard deviation), and a detection limit in the low attomole range is established. The method is illustrated by analyzing 124 human plasma protein samples in duplicate, a measurement that required 16.5 h. Current limitations as well as implications of the high-throughput approach for complex biological sample analysis are discussed.     

The design of a novel complementary metal oxide semiconductor detection system for biochemical luminescence

We designed a complementary metal oxide semiconductor (CMOS) chip with accompanied accessories as a system for the detections and quantifications of biochemical luminescence. This is the first of such instruments that has been reported. The semiconductor chip was manufactured through a 0.25 microm CMOS standard process. A current mirror was designed in integrated circuit (IC) to amplify the signal current that was induced by chemiluminescence. Horseradish peroxidase (HRP)-luminol-H2O2 system was used as an example to constitute a useful platform for coupling to chemiluminescence reactions which produce H2O2. Glucose-glucose oxidase (GOD) reaction was coupled with HRP-luminol-H2O2 reaction to demonstrate the ability of the novel CMOS base instrument for quantifying the biological luminescence of a variety of valuable clinical assays. Our results illustrated that the combination of the specifically designed CMOS IC and commercially available electronic devices established a simple and useful bioanalytical tool.     

基于MEMS技术的毛细管电泳芯片

基于MEMS技术的毛细管电泳芯片具有体积小、成本低、便于携带、分析速度快、所需样品和试剂少等优点,是一种新型的微型分析实验装置。介绍该芯片的结构、进样方式、材料选取、制作工艺、键合方法、样品检测方法等方面的研究进展和存在的问题,展望了应用前景 。     

微流控芯片技术用于精子与上皮细胞分离的研究

为研究建立使用微流控芯片技术分离精子与阴道上皮细胞的方法,选用制作工艺简单的玻璃-PDMS芯片,对混合样本进行分离。加样前分别在进、出口池中加入7此和lO此缓冲液,然后在进样口加入2此混合样本。至少静置8nlin后,从出口池中取出3此形成重力驱动的微流体后开始分离,每隔5min在进样口补加1此缓冲液。达到理想分离效果时,用移液器从出口池取出分离出的精子,核酸酶去除游离DNA,经过提取、扩增和电泳分离脸测等步骤得到精子的分型结果。结果显示,使用基于重力驱动微流体原理的微流控芯片可在30min内分离出精子,不会有上皮细胞进入分离通道;通过核酸酶对分离出的精子液的去游DNA处理,可得到单一、完整的精子分型。与传统的差异裂解法相比,这种方法在很大程度上节省了检验时间,在性侵案件中具有一定的法医物证分析价值。     

Chip-based separation devices coupled to mass spectrometry

The hyphenation of miniaturized separation techniques like chip electrophoresis or chip chromatography to mass spectrometry (MS) is a highly active research area in modern separation science. Such methods are particularly attractive for comprehensive analysis of complex biological samples. They can handle extremely low sample amounts, with low solvent consumption. Furthermore they provide unsurpassed analysis speed together with the prospect of integrating several functional elements on a single multifunctional platform. In this article we review the latest developments in this emerging field of technology and summarize recent trends to face current and future challenges in chip-based biochemical analysis.     

Nondestructive quality control for microarray production

The use of microarrays to monitor gene expression has become a standard research tool at both academic and industrial research institutions. Quality control of common printing defects during DNA deposition onto glass substrates is critical to maintaining data integrity and preventing the needless consumption of precious RNA, labeling reagents, and time. Here we demonstrate a nondestructive method for monitoring the quality of every spot on every chip of a microarray production run. We have identified many common manufacturing defects, while not perturbing the attachment of our oligonucleotide target to the substrate or altering further hybridization. This protocol is simple, fast, and inexpensive.     

硅-玻璃聚合酶链式反应微芯片对β-葡糖苷酸酶基因的扩增

聚合酶链式反应（PCR）微芯片是基于微机电系统（MEMS）制作,在微芯片上进行PCR反应,实现生物样品扩增的一项新技术.介绍了硅-玻璃PCR微芯片的设计和制作、微反应腔的清洗和表面处理、借助外置温度控制系统进行PCR扩增反应以及扩增产物在琼脂糖凝胶电泳下的检测分析,实现了对β-葡糖苷酸酶（GUS）基因的有效扩增,扩增时间由原来的90 min缩短到现在的37 min.     

Enhanced thin-layer chromatographic separation of GM1b-type gangliosides by automated multiple development

Enhancement in separation of gangliosides on silica gel precoated high-performance TLC plates has been obtained by automated multiple development chromatography. A less polar mixture of the standard solvent chloroform-methanol-20 mM aqueous CaCl₂ (120:85:20, v/v) was used. Lowering the water content achieved separation of two complex monosialoganglioside fractions, isolated from murine YAC-1 T lymphoma and MDAY-D2 lymphoreticular cells. Three-fold chromatography in the solvent chloroform-methanol-20 mM aqueous CaCl₂ (120:85:14, v/v) resulted in TLC separation of G_M1b-type gangliosides, substituted with C₂₄ and C₁₆ fatty acids and with Neu5Ac and Neu5Gc as well, which could not be achieved by undirectional standard chromatography. Compared to conventional single chromatography, the technique described allows high-resolution separation of extremely heterogenous ganglioside mixtures and offers a convenient tool for both analytical and preparative TLC.     

双色荧光杂交芯片在检测 P 1A 1M P I 基C 因多态性中的应用

目的：应用一种新的高通量SNP检测方法-双色荧光杂交芯片技术检测CYPIA1 MspI基因多态性。方法：收集江苏汉族人群原发性肺癌患者75例和相应对照77例,应用双色荧光杂交芯片技术检测了152例样本的CYPIAI基因MspI基因多态性,并应用PCR-RFLP技术验证双色荧光杂交芯片的特异性。结果：152例样本的CYPIAI基因双色荧光杂交芯片技术分型结果与PCR-RFLP结果完全相符,两种方法的基因型分型结果具有很好的一致性。结论：双色荧光杂交芯片技术是一个高通量SNP检测的良好工具,特异性高,在大规模人群SNP筛检中具有良好的发展前案。     

Influence of tool rotation on 3D surface topography at the nanometric scale

The influence of the tool rotation on the 3D surface topography produced by the nano-cutting process is investigated using molecular dynamics simulations. The least square mean method is utilized to model the evaluation criteria for the surface roughness parameters. The effects of the tool rotation on the cutting force and the chip formation at the nano-metric scale are also evaluated. It is found that the chip formation produced with tool rotation is dominated by the ploughing and the shearing forces. With increase of the adopted rotation velocity, the cutting force is sharply increased and the smaller elastic recovery of the machined surface is observed. The 3D surface roughness parameters at the nano-metric scale are significantly influenced by the tool rotation velocity and the feed speed, and the surface quality can be improved by decreasing the tool rotation velocity and the feed speed.     

Enhancing the Detection of Giardia duodenalis Cysts in Foods by Inertial Microfluidic Separation

The sensitivity and specificity of current Giardia cyst detection methods for foods are largely determined by the effectiveness of the elution, separation, and concentration methods used. The aim of these methods is to produce a final suspension with an adequate concentration of Giardia cysts for detection and a low concentration of interfering food debris. In the present study, a microfluidic device, which makes use of inertial separation, was designed and fabricated for the separation of Giardia cysts. A cyclical pumping platform and protocol was developed to concentrate 10-ml suspensions down to less than 1 ml. Tests involving Giardia duodenalis cysts and 1.90-μm microbeads in pure suspensions demonstrated the specificity of the microfluidic chip for cysts over smaller nonspecific particles. As the suspension cycled through the chip, a large number of beads were removed (70%) and the majority of the cysts were concentrated (82%). Subsequently, the microfluidic inertial separation chip was integrated into a method for the detection of G. duodenalis cysts from lettuce samples. The method greatly reduced the concentration of background debris in the final suspensions (10-fold reduction) in comparison to that obtained by a conventional method. The method also recovered an average of 68.4% of cysts from 25-g lettuce samples and had a limit of detection (LOD) of 38 cysts. While the recovery of cysts by inertial separation was slightly lower, and the LOD slightly higher, than with the conventional method, the sample analysis time was greatly reduced, as there were far fewer background food particles interfering with the detection of cysts by immunofluorescence microscopy.     

A chip‐based amide‐HILIC LC/MS platform for glycosaminoglycan glycomics profiling

A key challenge to investigations into the functional roles of glycosaminoglycans (GAGs) in biological systems is the difficulty in achieving sensitive, stable, and reproducible mass spectrometric analysis. GAGs are linear carbohydrates with domains that vary in the extent of sulfation, acetylation, and uronic acid epimerization. It is of particular importance to determine spatial and temporal variations of GAG domain structures in biological tissues. In order to analyze GAGs from tissue, it is useful to couple MS with an on‐line separation system. The purposes of the separation system are both to remove components that inhibit GAG ionization and to enable the analysis of very complex mixtures. This contribution presents amide–silica hydrophilic interaction chromatography (HILIC) in a chip‐based format for LC/MS of heparin, heparan sulfate (HS) GAGs. The chip interface yields robust performance in the negative ion mode that is essential for GAGs and other acidic glycan classes while the built‐in trapping cartridge reduces background from the biological tissue matrix. The HILIC chromatographic separation is based on a combination of the glycan chain lengths and the numbers of hydrophobic acetate (Ac) groups and acidic sulfate groups. In summary, chip based amide‐HILIC LC/MS is an enabling technology for GAG glycomics profiling.     

蛋白质芯片在蛋白质组学研究中的作用

蛋白质芯片是以高度并行性、高通量、微型化和自动化为特点的蛋白质组检测技术。本文综述了蛋白质芯片在蛋白质组学研究中的多种作用,包括普通蛋白质芯片在微量蛋白质分离、蛋白质与蛋白质之间以及蛋白质与其他小分子间相互作用和蛋白质定量检测方面的作用,普通蛋白质芯片通过与质谱技术、生物传感器技术的结合而拓展其应用范围,以及蛋白质组芯片、活性的蛋白质芯片在蛋白质组学研究中应用的进展。     

Ultrasensitive DNA chip: gene expression profile analysis without RNA amplification

We have developed a new DNA chip whose substrate has a unique minute columnar array structure made of plastic. The DNA chip exhibits ultrahigh sensitivity, up to 100-fold higher than that of reference DNA chips, which makes it possible to monitor gene expression profiles even with very small amounts of RNA (0.1-0.01 microg of total RNA) without amplification. Differential expression ratios obtained with the new DNA chip were validated against those obtained with quantitative real-time PCR assays. This novel microarray technology would be a powerful tool for monitoring gene expression profiles, especially for clinical diagnosis.     

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。     

Conformational screening of oligonucleotides by variable-temperature high performance liquid chromatography: dissecting the duplex-hairpin-coil equilibria of d(CGCGAATTCGCG)

This study probes the potential of variable-temperature high performance liquid chromatography (VT-HPLC) as a tool for dissecting and modulating nucleic acid structural transitions, using as a model the duplex-hairpin-coil transitions of d(CGCGAATTCGCG). It is demonstrated that VT-HPLC, combined with diode-array detection of the uv signal, enables, for the first time, a physical separation of spectroscopically distinct species that can be assigned to the duplex, hairpin, and coil forms of d(CGCGAATTCGCG). Although the species are spectroscopically distinguishable, they are not readily isolated. Hence, if fractions from the peaks for hairpin or duplex forms are collected and subsequently reinjected onto the cartridge, reequilibration occurs, and both hairpin and duplex peaks are observed. Area integration of the peaks corresponding to duplex and hairpin species provides a means to monitor the duplex to hairpin transition at effective concentrations in the nanomolar range, well below that accessible by conventional spectrophotometers. Concentration-dependent equilibrium constants, melting temperatures, and standard state enthalpies extracted from our measurements compare very well with previous literature results, and with our own results that take into account the effect of our solvent conditions [100 mM TEAA (triethylammonium acetate) and variable acetonitrile] on the melting behavior. By combining precise temperature control with separation based on size, physical behavior, and interaction free energies, VT-HPLC provides a powerful tool for both the modulation and the separation of nucleic acid conformations.     

Real time image processing with an analog vision chip system

A linear analog network model is proposed to characterize the function of the outer retinal circuit in terms of the standard regularization theory. Inspired by the function and the architecture of the model, a vision chip has been designed using analog CMOS Very Large Scale Integrated circuit technology. In the chip, sample/hold amplifier circuits are incorporated to compensate for statistic transistor mismatches. Accordingly, extremely low noise outputs were obtained from the chip. Using the chip and a zero-crossing detector, edges of given images were effectively extracted in indoor illumination.