蛋白质微阵列芯片技术及其在抗体筛选中的应用

以兔IgG为模式蛋白质,对其在醛基修饰玻片表面的固定浓度、固定时间和温度等条件进行了优化,结果表明：在室温下,当固定蛋白质的浓度为1g／L、固定时间为4h时,可获得理想的蛋白质固定效果;蛋白质的定量检测范围为1μg／L～10mg／L。按优化的蛋白质微阵列芯片制作条件将规模化制备的抗体制作成抗体微阵列芯片,通过与荧光标记的人球蛋白和人白蛋白的相互作用,实现了对不同抗体株抗球蛋白和抗白蛋白活性的快速筛选与比较。     

Detection of E. coli using a microfluidics-based antibody biochip detection system

This work demonstrates the detection of E. coli using a 2-dimensional photosensor array biochip which is efficiently equipped with a microfluidics sample/reagent delivery system for on-chip monitoring of bioassays. The biochip features a 4 x 4 array of independently operating photodiodes that are integrated along with amplifiers, discriminators and logic circuitry on a single platform. The microfluidics system includes a single 0.4 mL reaction chamber which houses a sampling platform that selectively captures detection probes from a sample through the use of immobilized bioreceptors. The independently operating photodiodes allow simultaneous monitoring of multiple samples. In this study the sampling platform is a cellulosic membrane that is exposed to E. coli organisms and subsequently analyzed using a sandwich immunoassay involving a Cy5-labeled antibody probe. The combined effectiveness of the integrated circuit (IC) biochip and the immunoassay is evaluated for assays performed both by conventional laboratory means followed by detection with the IC biochip, and through the use of the microfluidics system for on-chip detection. Highlights of the studies show that the biochip has a linear dynamic range of three orders of magnitude observed for conventional assays, and can detect 20 E. coli organisms. Selective detection of E. coli in a complex medium, milk diluent, is also reported for both off-chip and on-chip assays.     

Detection of E. coli using a microfluidics-based antibody biochip detection system

This work demonstrates the detection of E. coli using a 2-dimensional photosensor array biochip which is efficiently equipped with a microfluidics sample/reagent delivery system for on-chip monitoring of bioassays. The biochip features a 4 × 4 array of independently operating photodiodes that are integrated along with amplifiers, discriminators and logic circuitry on a single platform. The microfluidics system includes a single 0.4 mL reaction chamber which houses a sampling platform that selectively captures detection probes from a sample through the use of immobilized bioreceptors. The independently operating photodiodes allow simultaneous monitoring of multiple samples. In this study the sampling platform is a cellulosic membrane that is exposed to E. coli organisms and subsequently analyzed using a sandwich immunoassay involving a Cy5-labeled antibody probe. The combined effectiveness of the integrated circuit (IC) biochip and the immunoassay is evaluated for assays performed both by conventional laboratory means followed by detection with the IC biochip, and through the use of the microfluidics system for on-chip detection. Highlights of the studies show that the biochip has a linear dynamic range of three orders of magnitude observed for conventional assays, and can detect 20 E. coli organisms. Selective detection of E. coli in a complex medium, milk diluent, is also reported for both off-chip and on-chip assays. Received: 13 October 2000 / Revised: 13 November 2000 / Accepted: 13 November 2000     

Gold patterned biochips for on-chip immuno-MALDI-TOF MS: SPR imaging coupled multi-protein MS analysis

Matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI-TOF-MS) analysis of immuno-captured target protein efficiently complements conventional immunoassays by offering rich molecular information such as protein isoforms or modifications. Direct immobilization of antibodies on MALDI solid support enables both target enrichment and MS analysis on the same plate, allowing simplified and potentially multiplexing protein MS analysis. Reliable on-chip immuno-MALDI-TOF MS for multiple biomarkers requires successful adaptation of antibody array biochips, which also must accommodate consistent reaction conditions on antibody arrays during immuno-capture and MS analysis. Here we developed a facile fabrication process of versatile antibody array biochips for reliable on-chip MALDI-TOF-MS analysis of multiple immuno-captured proteins. Hydrophilic gold arrays surrounded by super-hydrophobic surfaces were formed on a gold patterned biochip via spontaneous chemical or protein layer deposition. From antibody immobilization to MALDI matrix treatment, this hydrophilic/phobic pattern allowed highly consistent surface reactions on each gold spot. Various antibodies were immobilized on these gold spots both by covalent coupling or protein G binding. Four different protein markers were successfully analyzed on the present immuno-MALDI biochip from complex protein mixtures including serum samples. Tryptic digests of captured PSA protein were also effectively detected by on-chip MALDI-TOF-MS. Moreover, the present MALDI biochip can be directly applied to the SPR imaging system, by which antibody and subsequent antigen immobilization were successfully monitored.     

Design of Sensitive Biocompatible Quantum‐Dots Embedded in Mesoporous Silica Microspheres for the Quantitative Immunoassay of Human Immunodeficiency Virus‐1 Antibodies

A novel sandwich‐type electrochemiluminescence (ECL) immunosensor was developed to enable the sensitive detection of HIV‐1 antibodies. This system incorporated mesoporous silica (mSiO₂) complexed with quantum dots (QDs) and nano‐gold particles, which were assembled to enhance signal detection. Magnetic beads were used by immobilizing the secondary anti‐IgG antibody. This was first employed to capture HIV‐1 antibody (Ab) to form a Fe₃O₄/anti‐IgG/Ab complex. A high loading and signal‐enhanced nanocomposite (hereafter referred to as Au‐mSiO₂‐CdTe) was used as a HIV‐1 antigen label. The Au‐mSiO₂‐CdTe nanocomposite was conjugated with the Fe₃O₄/anti‐IgG/Ab complex to form an immunocomplex (hereafter referred to as Fe₃O₄/anti‐IgG/Ab/HIV‐1/CdTe‐mSiO₂‐Au). This complex could be further separated by an external magnetic field to produce ECL signals. Due to the large specific surface area and pore volume of mSiO₂, the loading of the CdTe QDs was markedly increased. Thus, the loaded QDs released a powerful chemiluminescent signal with a concordantly increased sensitivity of the immunosensor. The immunosensor was highly sensitive, and displayed a linear range of responses for HIV‐1 antibody across a dilution range of 1 : 1500 through 1 : 50 with the detection limit of 1 : 4500. The immunoassay can be a promising candidate in early diagnosis of HIV infection.     

Miniature biochip system for detection of Escherichia coli O157:H7 based on antibody-immobilized capillary reactors and enzyme-linked immunosorbent assay

In this work, we report Escherichia coli O157:H7 detection using antibody-immobilized capillary reactors, enzyme-linked immunosorbent assay (ELISA), and a biochip system. ELISA selective immunological method to detect pathogenic bacteria. ELISA is also directly adaptable to a miniature biochip system that utilizes conventional sample platforms such as polymer membranes and glass. The antibody-immobilized capillary reactor is a very attractive sample platform for ELISA because of its low cost, compactness, reuse, and ease of regeneration. Moreover, an array of capillary reactors can provide high-throughput ELISA. In this report, we describe the use of an array of antibody-immobilized capillary reactors for multiplex detection of E. coli O157:H7 in our miniature biochip system. Side-entry laser beam irradiation to an array of capillary reactors contributes significantly to miniaturized optical configuration for this biochip system. The detection limits of E. coli O157:H7 using the ELISA and Cy5 label-based immunoassays were determined to be 3 and 230 cells, respectively. This system shows capability to simultaneously monitor multifunctional immunoassay and high sensitive detection of E. coli O157:H7.     

Demonstration of a surface plasmon-coupled emission (SPCE)-based immunoassay in the absence of a spacer layer

The technique of surface plasmon-coupled emission (SPCE) involves the coupling of light which is emitted from a fluorophore into the surface plasmon of an adjacent thin metal film, giving rise to highly directional emission. We have combined the advantages of SPCE with the high light collection efficiency of supercritical angle fluorescence by carrying out an immunoassay on a paraboloid array biochip in the absence of the conventional SPCE spacer layer normally used to minimize metal quenching of the fluorescence. In this work, we have successfully demonstrated an SPCE-based assay by utilizing the protein assay layer as the spacer layer. A novel 3 × 3 injection molded polymer biochip with paraboloid elements was used. The paraboloid elements served to enhance the light collection efficiency while the top surface was coated with a gold layer to use excitation of surface plasmons and detection of SPCE emission. Theoretical modeling of the gold-protein layer structure showed that the surface plasmon resonance angles were located in the detection range of the paraboloid biochip. The polarization dependence of SPCE emission was also demonstrated. Finally, a human IgG sandwich immunoassay was carried out which exhibited a limit of detection of ~10 ng/ml using 3σ. The results demonstrate the potential of the SPCE-based paraboloid array biochip as a novel platform for high-throughput analysis of biomolecular interactions.     

Antibody development to testosterone and its application in capillary electrophoresis-based immunoassay

The present report describes a rapid, simple, and highly selective approach to perform testosterone competitive immunoassay by CE and LIF detection. The method involves using synthesized fluorescence-labeled testosterone as a tracer to compete with testosterone. Two polyclonal antibodies (antibody (Ab) arised from T-3-BSA (Ab(3)) and Ab arised from T-17-BSA (Ab(17))) and their respective tracers have been optimized and Ab(3) system is used for the quantification of testosterone by CE-based immunoassay. The method is developed with a wide working range of 3.70-2000 ng/mL and an LOD at 1.11 ng/mL. Tests for normal and positive urine samples show that this method has the potential to be applied in testosterone doping control.     

Catalytic mechanism of an abzyme displaying a beta-lactamase-like activity

A catalytic IgG (Ab2) displaying a beta-lactamase-like activity was previously obtained by using the antiidiotypic pathway: the particularity of this antibody is that it is a true antiidiotype of the beta-lactamase active site. We have previously demonstrated that this IgG has retained some of the structural information displayed by the beta-lactamase active site, evident from data that polyclonal anti-Ab2 antibodies (Ab3) recognize beta-lactamase. In this article, we investigated the catalytic mechanism of the abzyme compared to that of the enzyme. The experimental data allow us to hypothesize the catalytic residues required for catalysis.     

Evaluation of the molecular recognition of monoclonal and polyclonal antibodies for sensitive detection of 2,4,6-trinitrotoluene (TNT) by indirect competitive surface plasmon resonance immunoassay

Detection of TNT is an important environmental and security concern all over the world. We herein report the performance and comparison of four immunoassays for rapid and label-free detection of 2,4,6-trinitrotoluene (TNT) based on surface plasmon resonance (SPR). The immunosensor surface was constructed by immobilization of a home-made 2,4,6-trinitrophenyl–keyhole limpet hemocyanin (TNPh–KLH) conjugate onto an SPR gold surface by simple physical adsorption within 10 min. The immunoreaction of the TNPh–KLH conjugate with four different antibodies, namely, monoclonal anti-TNT antibody (M-TNT Ab), monoclonal anti-trinitrophenol antibody (M-TNP Ab), polyclonal anti-trinitrophenyl antibody (P-TNPh Ab), and polyclonal anti-TNP antibody (P-TNP Ab), was studied by SPR. The principle of indirect competitive immunoreaction was employed for quantification of TNT. Among the four antibodies, the P-TNPh Ab prepared by our group showed highest sensitivity with a detection limit of 0.002 ng/mL (2 ppt) TNT. The lowest detection limits observed with other commercial antibodies were 0.008 ng/mL (8 ppt), 0.25 ng/mL (250 ppt), and 40 ng/mL (ppb) for M-TNT Ab, P-TNP Ab, and M-TNP Ab, respectively, in the similar assay format. The concentration of the conjugate and the antibodies were optimized for use in the immunoassay. The response time for an immunoreaction was 36 s and a single immunocycle could be done within 2 min, including the sensor surface regeneration using pepsin solution. In addition to the quantification of TNT, all immunoassays were evaluated for robustness and cross-reactivity towards several TNT analogs.      

A Review of Multifunctions of Dielectrophoresis in Biosensors and Biochips for Bacteria Detection

This paper reviews the functions of dielectrophoresis (DEP) that have been applied to biosensor and biochip platforms for bacteria detection, including concentration of bacterial cells from continuous flows, separation of target bacterial cells from non-target cells, as well as the enhancement of antibody capture efficiency on biosensor and biochip surfaces. DEP could provide effective concentration and separation simultaneously in well-designed microfluidic biosensor and biochip systems. The integration of DEP with a detection system allows the integration of sample preparation and enrichment steps with detection, which has the potential to eliminate the traditionally used time-consuming culture-based enrichment steps and other multiple off-chip sample preparation steps. DEP is also useful in biosensor and biochips platforms for enhancing antibody capture efficiency in both flow-through and non-flow-through microdevices. The enhanced antibody capture efficiency could allow the sensor capture more cells and to be detected by the sensor, particularly in dealing with low number of cells. The integration of multifunctions of DEP into biosensor and biochip platform has the potential to improve the detection of bacterial cells.     

一种基于磁性石墨烯的纸基电化学发光夹心免疫分析方法

基于电化学发光及磁悬浮免疫分析策略,结合磁性石墨烯独特的物理化学特性以及纸基电极价格低廉、样品用量少的优势,建立了一种新型免疫分析方法.以人免疫球蛋白G(IgG)为分析物,采用1-乙基-3-(3-二甲基氨丙基)-碳化二亚胺/N-羟基硫代琥珀酰亚胺(EDC/NHS)法将一抗(Ab1,捕获抗体)固定在磁性石墨烯上,通过直接标记法进行二抗(Ab2,信号抗体)的电化学发光试剂标记,采用磁悬浮夹心免疫技术最大程度减少非特异性吸附,通过纸基电化学发光检测技术测定目标物的浓度.考察了捕获抗体及信号抗体的固定(标记)效果,发现采用的磁性石墨烯不仅提高了免疫物质的负载量,还可以促进电子传递,构建的磁悬浮纸基电化学发光夹心免疫分析法的电化学发光响应峰面积在0.32~1000 ng/mL浓度范围内,与IgG浓度对数值呈良好的线性关系,检出限为6.4 pg/mL.本方法可实现IgG的定量检测,在低成本、快速免疫检测领域有一定的应用前景.     

Screen-printed microfluidic device for electrochemical immunoassay

In this paper, a new microfluidic array device has been fabricated with screen printing technology. In contrast to traditional microfabrication processes, our method is simple, inexpensive and also suitable for mass production. The device is used for sandwich-type electrochemical immunoassay, in which probes are covalently attached to the electrode surface via electropolymerized polypyrrole propylic acid (PPA) film. This novel microfluidic system enables the whole array preparation and detection processes, including the probe immobilization, sample injection, enzyme incubation and electrochemical detection, to be conducted in the sealed microchannels. For a demonstration, mouse IgG is selected as the target analyte and its detection is realized by sandwich ELISA with goat anti-mouse IgG, rat anti-mouse IgG (conjugated to alkaline phosphatase) and p-aminophenyl phosphate (PAPP) as the primary antibody, second antibody, and enzyme substrate, respectively. A detection limit of 10 ng mL(-1) (67 pM) is achieved with a dynamic range of 100 ng mL(-1)-10 microg mL(-1). In addition, anti-goat IgG is also immobilized as an alternative probe to test mouse IgG in the solution, in order to demonstrate the multiplexing capability as well as the specificity of the device. As expected, the electrochemical responses are much lower than that using anti-mouse IgG as the probe, indicating good selectivity of the immunoassay device. These results indicate a great promise toward the development of miniaturized, low-cost protein biochips for clinical, forensics, environmental, and pharmaceutical applications.     

Organic-inorganic matrix for electrochemical immunoassay: Detection of human IgG based on ZnO/chitosan composite

A new strategy to construct amperometric immunosensor for human IgG assay based on ZnO/chitosan composite as sensing platform has been described. This material, which combined the advantages of inorganic species, ZnO and organic polymer, chitosan, can maintain biological activity well. A sequential sandwich immunoassay format was performed on the ZnO/chitosan composite supported by glass carbon electrode (GCE) using goat-anti-human IgG antibody (IgG Ab) and human IgG as a model system. Amperometry was used to determine the amount of horse-radish peroxidase (HRP) fixed on the sensor surface, which was related to the content of the desired human IgG. Assay conditions that were optimized included the amount of labeled antibody, the incubation time and temperature, the pH of the substrate solution, etc. Using hydroquinone as a mediator, amperometric detection at −150 mV (versus SCE) resulted in a detection range 2.5-500 ng mL⁻¹, with a detection limit of 1.2 ng mL⁻¹. The simple manipulations of the construction of ZnO/chitosan composite, as well as low-cost and broad linear range, are the main features of the proposed immunosensing method.     

Electrochemical immunoassay platform for high sensitivity protein detection based on redox-modified carbon nanotube labels

We report a highly sensitive immunoassay protocol based on the use of redox-modified multi-walled carbon nanotubes (MWNTs) as electrochemical labels. The MWNTs were coated with methylene blue (MB) at an optically-determined loading of 3.41 × 10(-3) mol g(-1), and were then attached to secondary antibodies (Ab(2)) by adsorption. As a model analyte mouse IgG was collected by primary antibody (Ab(1))-coated magnetic beads. Following binding of the MB-MWNT-Ab(2) conjugates, IgG could be measured by MB reduction. Using differential pulse voltammetry for quantification, IgG was calibrated with a dynamic range of 0.1 pg mL(-1) to 100 pg mL(-1). Given the different possible Ab(1)-MB-MWNT-Ab(2) orientations on the magnetic beads, it was likely that not all the MB communicated with the electrode. A greater quantity of MB could be accessed by using the Fe(CN)(6)(3-/4-) redox couple as a solution phase mediator. This enabled us to lower the dynamic range down to 5 fg mL(-1) to 100 fg mL(-1).     

Multichannel homogeneous immunoassay for detection of 2,4,6-trinitrotoluene (TNT) using a microfabricated capillary array electrophoresis chip

A high-throughput homogeneous immunoassay for the sensitive detection of 2,4,6-trinitrotoluene (TNT) has been developed using radial capillary array electrophoresis microdevices. Samples consisting of equilibrium mixtures of anti-TNT antibody (Ab), fluorescein-labeled TNT, and various concentrations of unlabeled TNT were electrokinetically injected into 48 channels of a radial capillary array electrophoresis microchannel plate. The rapid electrophoretic separation allows us to analyze the equilibrium ratio formed by the competition between the labeled and the unlabeled TNT for Ab binding. The simultaneous parallel TNT separations facilitate determination of a calibration curve for the TNT assay, which has high sensitivity (LOD, 1 ng/mL) and a wide dynamic range (1-300 ng/mL).     

基于微机电系统技术和纳米金自组装膜的安培型免疫传感器研究

基于微机电系统(MEMS)技术制备安培型免疫传感器,并利用基于硫醇单层膜的纳米金单层膜自组装技术设计传感器界面,用于固定人免疫球蛋白(IgG)抗体,研制了一种新型的安培型免疫传感器。采用MEMS技术,在硅片上制备微型的三电极系统以及SU-8反应池。基于自组装技术,先在金电极上自组装巯基乙胺单层膜,利用膜上氨基与纳米金共价结合组装纳米金单层膜,得到可用于固定抗体的界面。实验探讨了影响抗体固定的主要实验参数和条件;考察了采用此固定化方法传感器的响应性能,与金电极直接吸附固定法和戊二醛共价交联固定法进行了比较。对IgG检测的实验结果表明,采用纳米金自组装膜固定抗体,具有活性高、非特异性吸附小、检测线性范围宽等优点。并且,基于MEMS技术的安培型免疫传感器具有微型化、与集成电路工艺相兼容、易于实现传感器的阵列化和实时多参数检测等优点。     

Direct immobilization in poly(dimethylsiloxane) for DNA, protein and enzyme fluidic biochips

A new arraying method is presented based on the properties of poly(dimethylsiloxane) (PDMS) polymer to entrap beads bearing biologically active compounds. It is shown that such beads could be spotted and dried at the surface of a poly(vinyl chloride) master and subsequently transferred at the PDMS interface by direct moulding of the polymer on the mask. Moreover, the use of the PDMS-assisted-immobilization enables the development of either a low density array (100 spots) or a micro-channel biochip with a direct incorporation of the sensing element in a fluidic system for the quantitative detection of enzyme substrates, antigens and oligonucleotides, depending on the immobilized sensing element. All biochip formats were revealed by a chemiluminescent reaction detected with a charge coupled device camera.As a result, arrays of beads bearing active enzymes, antibodies and oligonucleotides were successfully obtained and enabled the achievement of biochips for the chemiluminescent detection of enzyme substrates, protein antigens and oligonucleotides sequence with detection limit of 1 μM, 1.5×10⁷ molecules and 10⁸ molecules, respectively.     

Part-per-trillion level detection of estradiol by competitive fluorescence immunoassay using DNA/dye conjugate as antibody multiple labels

Fluorescent organic dyes are currently the standard signal-generating labels used in microarray quantification. However, new labeling strategies are needed to meet the demand for high sensitivity in the detection of low-abundance proteins and small molecules. In this report, a long-chain DNA/dye conjugate was used to attach multiple fluorescence labels on antibodies to improve signal intensity and immunoassay sensitivity. Compared with the 30 base-pair (bp) oligonucleotide used in our previous work [Q. Zhang, L.-H. Guo, Bioconjugate Chem. 18 (2007) 1668-1672], conjugation of a 219 bp DNA in solution with a fluorescent DNA binder SYBR Green I resulted in more than sixfold increase in signal intensity, consistent with the increase in bp number. In a direct immunoassay for the detection of goat anti-mouse IgG in a mouse IgG-coated 96-well plate, the long DNA conjugate label also produced higher fluorescence than the short one, accompanied by about 15-fold improvement in the detection limit. To demonstrate its advantage in real applications, the DNA/dye conjugate was employed in the competitive immunoassay of 17β-estradiol, a clinically and environmentally important analyte. The biotin-terminated DNA was attached to biotinylated anti-estradiol antibody through the biotin/streptavidin/biotin bridge after the immuno-reaction was completed, followed by conjugation with SYBR Green I. The limit of detection for 17β-estradiol is 1.9 pg mL⁻¹, which is 200-fold lower than the assay using fluorescein-labeled antibodies. The new multiple labeling strategy uses readily available reagents, and is also compatible with current biochip platform. It has great potential in the sensitive detection of protein and antibody microarrays.     

Sensitive electrochemical immunosensor array for the simultaneous detection of multiple tumor markers

A novel electrochemical immunosensor array for the simultaneous detection of multiple tumor markers was developed by incorporating electrochemically addressing immobilization and one signal antibody strategy. As a proof-of-principle, an eight-electrode array including six carbon screen-printed working electrodes was used as a base array for the analysis of two important tumor markers, carcinoembryonic antigen (CEA) and α-fetoprotein (AFP) and a horseradish peroxidase-labeled antibody was employed as a signal antibody. The immunosensor in the array was fabricated in sequence by covalently coupling the capture antibody onto the surface of the desired working electrode, which was firstly electrochemically addressably grafted with an aminophenyl group by reduction of in situ generated aminophenyl diazonium cation generated from p-phenylenediamine, using glutaraldehyde as cross-linker. This allowed the selective immobilization of the capture antibody at the desired position on a single array via an electrochemical operation. The immunoassay in sandwich mode was performed by specifically binding the targets, second antibodies and one signal antibody to the immunosensor array. The result showed that the steady current density was directly proportional to the concentration of target CEA/AFP in the range from 0.10 to 50 ng mL(-1) with a detection limit of 0.03 ng mL(-1) for CEA and 0.05 ng mL(-1) for AFP (S/N = 3), respectively. This work demonstrates that the employment of an electrochemically addressing method for the fabrication of an immunosensor array and one signal antibody is a promising approach for the determination of multiple tumor markers in clinical samples.