Analysis of inflammatory biomarkers from tissue biopsies by chip-based immunoaffinity CE

To aid in the biochemical analysis of human skin biopsies, a semiautomatic chip-based CE system has been developed for measuring inflammatory biomarkers in microdissected areas of the biopsy. Following solubilization of the dissected tissue, the desired biomarkers were isolated by immunoaffinity capture using a panel of 12 antibodies, immobilized on a disposable glass fiber disk, within the extraction port of the chip. The captured analytes were labeled with a 635 nm light-emitting laser dye and electroeluted into the separation channel. Electrophoretic separation of all of the analytes was achieved in 2.2 min with quantification of each peak being performed by online LIF detection and integration of each peak area. Comparison of the results obtained from the chip-based system to those obtained using commercially available high-sensitivity immunoassays demonstrated that the chip-based assay provides a fast, accurate procedure for studying the concentrations of inflammatory biomarkers in complex biological materials. The degree of accuracy and precision achieved by the chip-based CE is comparable to conventional immunoassays and the system is capable of analyzing circa six samples per hour. With the ever-expanding array of antibodies that are commercially available, this chip-based system can be applied to a wide variety of different biomedical analyses.     

Rapid analysis of inflammatory cytokines in cerebrospinal fluid using chip-based immunoaffinity electrophoresis

A chip-based capillary electrophoresis system has been designed for rapidly measuring the concentrations of inflammatory cytokines in the cerebrospinal fluid of patients with head trauma. Isolation of the reactive cytokines was achieved by immunoaffinity capture using a panel of six immobilized antibodies, directly attached to the injection port of the chip. The captured cytokines were labeled in situ with a red light-emitting laser dye and electroeluted into the separation channel. Separation of the isolated cytokines was achieved by electrophoresis in under 2 min with quantification of the resolved peaks being achieved by on-line laser-induced fluorescence and integration of each peak area. Comparison of the results to commercially available high-sensitivity immunoassays demonstrates that the chip-based assay provides a fast, accurate procedure for studying the concentrations of these analytes in complex biological materials. The degree of accuracy and precision achieved by the chip-based CE is comparable to conventional immunoassays, the system being able to analyze between 10-12 samples per hour. With the ever-expanding array of antibodies that are commercially available, this chip-based system can be applied to a wide variety of different analyses.     

Measurement of neuropeptides in clinical samples using chip-based immunoaffinity capillary electrophoresis

The current interest in micro-fabrication has extended to the clinical arena where there is a growing lobby for promoting these for point-of-care purposes. The advantages of such devices are their relative speed of analysis, lower reagent costs, and their application to clinical screening and diagnosis. Two chip-based capillary electrophoresis systems have been designed and their performance evaluated for rapidly measuring the concentrations of inflammatory neuropeptides in tissue fluids of patients with neuropeptide-associated muscle pain. Both chips were manufactured to fit a commercially available chip electrophoresis system. One chip was designed to perform electrokinetic flow immunoassays while the other utilized an immunoaffinity port, containing an array of immobilized antibodies, to capture the analytes of interest. Comparison of the results to commercially available high-sensitivity immunoassays demonstrated that both chip-based systems could provide a relatively fast, accurate procedure for studying inflammatory biomarkers in complex biological fluids. However, the immunoaffinity capture system proved the superior of the two chips. Using this system, twelve different inflammation-associated mediators could be determined in approximately 2 min as compared to 30 min when using the flow immunoassay chip. With the ever-expanding array of antibodies that are commercially available, this chip-based system can be applied to a wide variety of different analyses.     

Development of a new hybrid technique for rapid speciation analysis by directly interfacing a microfluidic chip-based capillary electrophoresis system to atomic fluorescence spectrometry

This paper represents the first study on direct interfacing of microfluidic chip-based capillary electrophoresis (chip-CE) to a sensitive and selective detector, atomic fluorescence spectrometry (AFS) for rapid speciation analysis. A volatile species generation technique was employed to convert the analytes from the chip-CE effluent into their respective volatile species. To facilitate the chip-CE effluent delivery and to provide the necessary medium for subsequent volatile species generation, diluted HCl solution was introduced on the chip as the makeup solution. The chip-CE-AFS interface was constructed on the basis of a concentric "tube-in-tube" design for introducing a KBH4 solution around the chip effluent as sheath flow and reductant for volatile species generation as well. The generated volatile species resulting from the reaction of the chip-CE effluent and the sheath flow were separated from the reaction mixture in a gas-liquid separator and swept into the AFS atomizer by an argon flow for AFS determination. Inorganic mercury (Hg(II)) and methylmercury (MeHg(I)) were chosen as the targets to demonstrate the performance of the present technique. Both mercury species were separated as their cysteine complexes within 64 s. The precision (relative standard deviation, RSD, n = 5) of migration time, peak area, and peak height for 2 mg.L(-1) Hg(II) and 4 mg.L(-1) MeHg(I) (as Hg) ranged from 0.7 to 0.9%, 2.1 to 2.9%, and 1.5 to 1.8%, respectively. The detection limit was 53 and 161 microg.L(-1) (as Hg) for Hg(II) and MeHg(I), respectively. The recoveries of the spikes of mercury species in four locally collected water samples ranged from 92 to 108%.     

Parallel separation of multiple samples with negative pressure sample injection on a 3-D microfluidic array chip

A simple and powerful microfluidic array chip-based electrophoresis system, which is composed of a 3-D microfluidic array chip, a microvacuum pump-based negative pressure sampling device, a high-voltage supply and an LIF detector, was developed. The 3-D microfluidic array chip was fabricated with three glass plates, in which a common sample waste bus (SW(bus)) was etched in the bottom layer plate to avoid intersecting with the separation channel array. The negative pressure sampling device consists of a microvacuum air pump, a buffer vessel, a 3-way electromagnet valve, and a vacuum gauge. In the sample loading step, all the six samples and buffer solutions were drawn from their reservoirs across the injection intersections through the SW(bus) toward the common sample waste reservoir (SW(T)) by negative pressure. Only 0.5 s was required to obtain six pinched sample plugs at the channel crossings. By switching the three-way electromagnetic valve to release the vacuum in the reservoir SW(T), six sample plugs were simultaneously injected into the separation channels by EOF and electrophoretic separation was activated. Parallel separations of different analytes are presented on the 3-D array chip by using the newly developed sampling device.     

An automated electrokinetic continuous sample introduction system for microfluidic chip-based capillary electrophoresis

An automated and continuous sample introduction system for microfluidic chip-based capillary electrophoresis (CE) was developed in this work. An efficient world-to-chip interface for chip-based CE separation was produced by horizontally connecting a Z-shaped fused silica capillary sampling probe to the sample loading channel of a crossed-channel chip. The sample presentation system was composed of an array of bottom-slotted sample vials filled alternately with samples and working electrolyte, horizontally positioned on a programmable linearly moving platform. On moving the array from one vial to the next, and scanning the probe, which was fixed with a platinum electrode on its tip, through the slots of the vials, a series of samples, each followed by a flow of working electrolyte was continuously introduced electrokinetically from the off-chip vials into the sample loading channel of the chip. The performance of the system was demonstrated in the separation and determination of FITC-labeled arginine and phenylalanine with LIF detection, by continuously introducing a train of different samples. Employing 4.5 kV sampling voltage (1000 V cm(-1) field strength) for 30 s and 1.8 kV separation voltage (400 V cm(-1) field strength) for 70 s, throughputs of 36 h(-1) were achieved with <1.0% carryover and 4.6, 3.2 and 4.0% RSD for arginine, FITC and phenylalanine, respectively (n = 11). Net sample consumption was only 240 nL for each sample.     

Simultaneous Determination of β2-Microglobulin and Ig E Using Real-Time Biospecific Interaction Analysis (BIA)

Abstract

Real-time biospecific interaction analysis (real time BIA) based on Surface Plasmon Resonance (SPR) has been used to measure the concentration of β2-microglobulin (β2-μ) and Ig E, used as a model system, simultaneously in buffer and plasma. The method relies on specific binding of β2-microglobulin and Ig E to a sensor chip surface where the monoclonal antibodies anti-β2-microglobulin and anti-Ig E were covalently immobilized. The primary binding of the analytes to the surface is followed by the injection, in sequence, of secondary antibodies, each one specific for a different epitope of β2-microglobulin and Ig E, respectively. The binding between the antibodies and the analytes is recorded as an increase in the SPR signal expressed in Resonance Units (RU). The SPR signal is directly related to the amount of β2-microglobulin and Ig E bound to the surface, and depends upon the concentration of the analytes in the sample. The analysis was performed in buffer and serum to show any non-specific binding due to serum proteins. The concentration range 0.35-5.55 nM for both analytes is covered, with good precision and close correlation with an independent standard concentration measurement.     

DNA mutation detection with chip-based temperature gradient capillary electrophoresis using a slantwise radiative heating system

A simple and robust chip-based temperature gradient capillary electrophoresis (TGCE) system was developed for DNA mutation/single-nucleotide polymorphism (SNP) analysis using a radiative heating system. Reproducible, stable and uniform temperature gradients were established along a 3 cm length of the electrophoretic separation channel using a single thermostated aluminium heater plate. The heater was slightly slanted relative to the plane of the glass chip at 0.2-1.3 degrees by inserting thin spacers between the plate and chip at one end to produce differences in radiative heating that created the temperature gradient. On-chip TGCE analyses of 4 mutant DNA model samples amplified from plasmid templates, each containing a single base substitution, with a wide range of melting temperatures, showed that mutations were successfully detected under a wide temperature gradient of 10 degrees C and within a short gradient region of about 3 cm (3.3 degrees C cm(-1) gradient). The radiative heating system was able to establish stable spatial temperature gradients along short microfluidic separation channels using simple peripheral equipment and manipulation while ensuring good resolution for detecting a wide range of mutations. Effectiveness of the system was demonstrated by the successful detection of K-ras gene mutations in 6 colon cancer cell lines.     

A microchip-based flow injection-amperometry system with mercaptopropionic acid modified electroless gold microelectrode for the selective determination of dopamine

A novel chip-based flow injection analysis (FIA) system has been developed for automatic, rapid and selective determination of dopamine (DA) in the presence of ascorbic acid (AA). The system is composed of a polycarbonate (PC) microfluidic chip with an electrochemical detector (ED), a gravity pump, and an automatic sample loading and injection unit. The selectivity of the ED was improved by modification of the gold working microelectrode, which was fabricated on the PC chip by UV-directed electroless gold plating, with a self-assembled monolayer (SAM) of 3-mercaptopropionic acid (MPA). Postplating treatment methods for cleaning the surface of electroless gold microelectrodes were investigated to ensure the formation of high quality SAMs. The effects of detection potential, flow rate, and sampling volume on the performance of the chip-based FIA system were studied. Under optimum conditions, a detection limit of 74 nmol L⁻¹ for DA was achieved at the sample throughput rate of 180 h⁻¹. A RSD of 0.9% for peak heights was observed for 19 runs of a 100 μmol L⁻¹ DA solution. Interference-free determination of DA could be conducted if the concentration ratio of AA–DA was no more than 10.     

基于微流控芯片的色谱系统的研究进展及其应用

近年来,基于微流控芯片的色谱技术研究取得了快速发展。本文对微流控芯片上色谱柱的加工方法、泵阀驱动控制装置的设计、集成及联用色谱系统的研制及其应用等方面予以综述,涉及文献66篇。     

Electrochromatography in microchips packed with conventional reversed-phase silica particles

This paper shows the applicability of a disposable and inexpensive microfluidic chip for electrochromatographic separations. The chip, recently developed by us for chip-based LC, was fabricated from PDMS incorporating conventional chromatographic RP silica particles (C18) without the use of frits. Three cephalosporin antibiotics were used to demonstrate the applicability of the chip-based chromatographic packing for electrochromatographic determinations. The used sample injection method utilizes hydrodynamic pressure, thereby, reducing the propensity for sample bias during the injection.     

Functional integration of DNA purification and concentration into a real time micro-PCR chip

Microfluidic devices for on-chip amplification of DNA from various biological and environmental samples have gained extensive attention over the past decades with many applications including molecular diagnostics of disease, food safety and biological warfare testing. But the integration of sample preparation functions into the chip remains a major hurdle for practical application of the chip-based diagnostic system. We present a PCR-based molecular diagnostic device comprised of a microfabricated chip and a centrifugal force assisted liquid handling tube (CLHT) that is designed to carry out concentration and purification of DNA and subsequent amplification of the target gene in a single chip. The reaction chamber of the chip contains an array of pillar structures to increase the surface area for capturing DNA from a raw sample of macro volume in the presence of kosmotropic agents. The CLHT was designed to provide an effective interface between sample preparation and the microfluidic PCR chip. We have characterized the effect of various fluidic parameters including DNA capture, amplification efficiency and centrifugal pressure generated upon varying sample volume. We also evaluated the performance of this system for quantitative detection of E. coli O157:H7. From the samples containing 10(1) to 10(4) cells per mL, the C(T) value linearly increased from 25.1 to 34.8 with an R(2) value greater than 0.98. With the effectiveness and simplicity of operation, this system will provide an effective interface between macro and micro systems and bridge chip-based molecular diagnosis with practical applications.     

Negative pressure pinched sample injection for microchip-based electrophoresis

A simple method for injecting well-defined non-biased sample plugs into the separation channel of a microfluidic chip-based capillary electrophoresis system was developed by a combination of flows generated by negative pressure, electrokinetic and hydrostatic forces. This was achieved by using only a single syringe pump and a single voltage supply at constant voltage. In the loading step, a partial vacuum in the headspace of a sealed sample waste reservoir was produced using a syringe pump equipped with a 3-way valve. Almost instantaneously, sample was drawn from the sample reservoir across the injection intersection to the sample waste reservoir by negative pressure. Simultaneously, buffer flow from the remaining two buffer reservoirs pinched the sample flow to form a well-defined sample plug at the channel intersection. In the subsequent separation stage, the vacuum in headspace of the sample waste reservoir was released to terminate all flows generated by negative pressure, and the sample plug at the channel intersection was electrokinetically injected into the separation channel under the potential applied along the separation channel. The liquid levels of the four reservoirs were optimized to prevent sample leakage during the separation stage. The approach considerably simplified the operations and equipment for pinched injection in chip-based CE, and improved the throughput. Migration time precisions of 3.3 and 1.5% RSD for rhodamine123 (Rh123) and fluorescein sodium (Flu) in the separation of a mixture of Flu and Rh123 were obtained for 56 consecutive determinations with peak height precisions of 6.2% and 4.4% RSD for Rh123 and Flu, respectively.     

Novel multi-depth microfluidic chip for single cell analysis

A novel multi-depth microfluidic chip was fabricated on glass substrate by use of conventional lithography and three-step etching technology. The sampling channel on the microchip was 37 microm deep, while the separation channel was 12 microm deep. A 1mm long weir was constructed in the separation channel, 300 microm down the channel crossing. The channel at the weir section was 6 microm deep. By using the multi-depth microfluidic chip, human carcinoma cells, which easily aggregate, settle and adhere to the surface of the channel, can be driven from the sample reservoir to the sample waste reservoir by hydrostatic pressure generated by the difference of liquid level between sample and sample waste reservoirs. Single cell loading into the separation channel was achieved by applying a set of pinching potentials at the four reservoirs. The loaded cell was stopped by the weir and precisely positioned within the separation channel. The trapped cell was lysed by sodium dodecyl sulfate (SDS) containing buffer solution in 20s. This approach reduced the lysing time and improved the reproducibility of chip-based electrophoresis separations. Reduced glutathione (GSH) and reactive oxygen species (ROS) were used as model intracellular components in single human carcinoma cells, and the constituents were separated by chip-based electrophoresis and detected by laser-induced fluorescence (LIF). A throughput of 15 samples/h, a migration time precision of 3.1% RSD for ROS and 4.9% RSD for GSH were obtained for 10 consecutively injected cells.     

Native Protein Separation by Isoelectric Focusing and Blue Gel Electrophoresis-Coupled Two-Dimensional Microfluidic Chip Electrophoresis

The use of microfluidic chip-based two-dimensional separation holds great promise in the proteomics field, given its portability, simplicity, speed, efficiency, and throughput. However, inclusion of sodium dodecyl sulfate, reported to be necessary for increasing protein-resolving capability, was also accompanied by the loss of both protein conformation and biological function. Here, we describe separation of native proteins by introducing blue native gel electrophoresis into isoelectric focusing and gel electrophoresis (IEF/CGE)-coupled protein two-dimensional microfluidic chip electrophoresis. After assessing the influence of various experimental conditions, the best separation ability and reproducibility of blue native IEF/CGE (IEF/BN-CGE) chip electrophoresis achieved until now were demonstrated no matter whether with a simple simulated mixture or with a complex mixture of total Escherichia coli proteins. Finally, instead of theoretical calculations, the image analysis technique was also used for the first time to quantitatively evaluate the actual peak capacities of chip electrophoresis. According to the number of features abstracted in the electrophoresis patterns, the superiority of the IEF/BN-CGE two-dimensional microfluidic chip electrophoresis was then exhibited quantitatively. The high native protein separation performance makes this established chip electrophoresis method possible for further application in widely needed drug screening, analysis of bio-molecular function, and assays of protein–protein interactions.     

集成化液膜萃取-反萃取-毛细管电泳联用芯片

我们设计并制作了集成有支持液膜萃取-反萃取试样预处理的毛细管电泳(SLMEBE-CCE)微流控芯片. 分别以荧光素钠和丁基罗丹明B作为模型待测物和共存物, 在该芯片上进行了在线试样预处理与毛细管电泳联用的初步实验.     

A capillary electrophoresis chip for the analysis of print and film photographic developing agents in commercial processing solutions using indirect fluorescence detection

The separation and detection of both print and film developing agents (CD-3 and CD-4) in photographic processing solutions using chip-based capillary electrophoresis is presented. For simultaneous detection of both analytes under identical experimental conditions a buffer pH of 11.9 is used to partially ionise the analytes. Detection is made possible by indirect fluorescence, where the ions of the analytes displace the anionic fluorescing buffer ion to create negative peaks. Under optimal conditions, both analytes can be analyzed within 30 s. The limits of detection for CD-3 and CD-4 are 0.17 mM and 0.39 mM, respectively. The applicability of the method for the analysis of seasoned photographic processing developer solutions is also examined.     

Continuous cell introduction and rapid dynamic lysis for high-throughput single-cell analysis on microfludic chips with hydrodynamic focusing

A chip-based microfluidic system for high-throughput single-cell analysis is described. The system was integrated with continuous introduction of individual cells, rapid dynamic lysis, capillary electrophoretic (CE) separation and laser induced fluorescence (LIF) detection. A cross microfluidic chip with one sheath-flow channel located on each side of the sampling channel was designed. The labeled cells were hydrodynamically focused by sheath-flow streams and sequentially introduced into the cross section of the microchip under hydrostatic pressure generated by adjusting liquid levels in the reservoirs. Combined with the electric field applied on the separation channel, the aligned cells were driven into the separation channel and rapidly lysed within 33ms at the entry of the separation channel by Triton X-100 added in the sheath-flow solution. The maximum rate for introducing individual cells into the separation channel was about 150cells/min. The introduction of sheath-flow streams also significantly reduced the concentration of phosphate-buffered saline (PBS) injected into the separation channel along with single cells, thus reducing Joule heating during electrophoretic separation. The performance of this microfluidic system was evaluated by analysis of reduced glutathione (GSH) and reactive oxygen species (ROS) in single erythrocytes. A throughput of 38cells/min was obtained. The proposed method is simple and robust for high-throughput single-cell analysis, allowing for analysis of cell population with considerable size to generate results with statistical significance.     

微流控芯片流动注射气体扩散分离光度测定系统的研究

提出了纳升级进样量的微流控芯片流动注射气体扩散分离光度检测系统. 制作三层结构微流控芯片, 在玻璃片上加工微反应通道, 用聚二甲基硅氧烷[Poly(dimethylsiloxane), PDMS]加工气体渗透膜和具有接收气体微通道的底片, 实现了生成气体的化学反应、气-液分离和检测在同一微芯片上的集成化. 采用缝管阵列纳升流动注射进样系统连续进样, 用吸光度法测定NH+4以验证系统性能. 结果表明， 该系统对NH+4的检出限为140 μmol/L(3σ), 峰高精度为3.7%(n=9). 在进样时间12 s、注入载流48 s和每次进样消耗200 nL试样条件下, 系统分析通量可达60样/h. 若加大样品量到800 nL, 使接收溶液停流1 min, 该系统对NH+4的检出限可达到35 μmol/L(3σ), 但分析通量降低到20样/h.     

A new two-chip concept for continuous measurements on PMMA-microchips

A new concept for continuous measurements on microchips is presented. A PMMA (polymethylmethacrylate) based capillary electrophoresis chip with integrated conductivity detection is combined with a second chip, which undertakes the task of fluid handling and electrical connections. The combination of electrokinetic and hydrodynamic flows allows long-term continuous stable analyses with good reproducibilities of migration time and peak heights of analytes. The two-chip system is characterized in terms of stability and reproducibility of separation and detection of small ions. Relative standard deviations of <1% and 3% respectively for retention times and peak heights during long-term measurements can be achieved. The new system combines simple handling and automated analysis without the need for refilling, cleaning or removal of the separation chip after one or several measurements.