An impedimetric immunosensor for the label-free detection of bisphenol A

Label-free detection of bisphenol A based on the impedance measurement was achieved with an impedimetric immunosensor. The immunosensor was fabricated by the covalent bond formation between a polyclonal antibody and a carboxylic acid group functionalized onto a nano-particle comprised conducting polymer. By using a commercial reagent 4,4-bis(4-hydroxyphenyl) valeric acid (BHPVA), which has an analogous structure of BPA, we have prepared the antigen through the conjugation of BHPVA with bovine serum albumin (BSA) and then produced a specific polyclonal antibody. The immobilization of antibody and the interaction between antibody and antigen were studied using quartz crystal microbalance (QCM) and electrochemical impedance spectroscopic (EIS) techniques. The impedance and mass changes due to the specific immuno-interaction at the sensor surface were utilized to detect antigen and bisphenol A (BPA). The immunosensor showed specific recognition of BPA with less interference than 4.5% from other common phenolic compounds. Under an optimized condition, the linear dynamic range of BPA detection was between 1 and 100 ng/ml. The detection limit of bisphenol A was determined to be 0.3+/-0.07 ng/ml. The proposed immunosensor was applied to a human serum sample and the BPA concentration was determined by the standard addition method.     

A sensitive immunoassay based on electropolymerized films by capacitance measurements for direct detection of immunospecies

Fabrication of a capacitive immunosensor based on electropolymerized polytyramine (Pty) film for the direct detection of human serum albumin (HSA) without any labeling is described. The capacitance change of the heterostructures, Pty films/covalently bonded antibodies/buffered medium, is utilized for monitoring the specific antibody-antigen interaction. The Pty films are ultrathin and the HSA assay is nearly specific. Experimental parameters affecting antibody immobilization and the sensing of HSA are investigated in detail and optimized. This capacitive sensor prepared with the present method can provide high sensitivity. Under the optimized experimental conditions, a linear calibration curve in the concentration range 1.84-368.6 ng/ml when plotted vs the logarithm of the antigen concentration is obtained and the detection limit (S/N=3) is 1.60 ng/ml. After an acidic washing the present system can be used again. The applicability and reliability of the sensor are also demonstrated.     

Detection of human chorionic gonadotrophin hormone using a label-free epoxysilane-modified capacitive immunosensor

A new and label-free capacitive immunosensor based on antibody-functionalized epoxysilane on a glassy carbon electrode has been developed for quantitative detection of human chorionic gonadotropin (hCG). Monitoring the changes in the capacitance signals of antibodies before and after the binding of the antigen provides the basis for an immunoassay. The performance and factors influencing the immunosensor were also studied. Under the optimized conditions, the developed immunosensor quantitatively detected serum hCG in the range of 18–450 mIU/ml with a detection limit of 5.0 mIU/ml (at 3δ). Thirty-five patients’ sera were assayed by the proposed immunosensor, and the results agreed with those given by the commercial radioimmunoassay test kit, with correlation coefficient of 0.998. Further research about the intrinsic electroactivity of antibodies and their target molecules would surely provide new and sensitive screening assays as well as extensive data regarding their interaction mechanisms.     

Nanostructures and molecular force bases of a highly sensitive capacitive immunosensor

While biosensors have been constructed using various strategies, there is no report describing nanostructures of antibody-immobilized electrode interface in an immunosensor. Here, atomic force microscopy (AFM) and electrochemistry analyses were employed to construct and characterize the nanostructures and electrochemistry of biosensing surface that was created by a sequential self-assembling of bioactive aminobenzenthiol oligomer (o-ABT), glutareldehyde and anti-transferrin (anti-Tf) antibody on the electrode gold surface. Under AFM, a complete coverage of bioactive o-ABT interface could be achieved by anti-Tf antibody at an optimal concentration. The anti-Tf antibody immobilized on electrode surface of the immunosensor exhibited globular-shape topography with some degree of aggregation. Extensive force-curve analysis allowed mapping the functional spots of the anti-Tf immunosensor. Surprisingly, although immunosensing surface was fully covered by anti-Tf antibodies at the optimal concentration, only about 52% of coated anti-Tf antibody molecules (spots) on the electrode surface were able to specifically capture or bind Tf antigen under AFM. Despite limited functional spots, however, the anti-Tf immunosensor was highly specific and sensitive for sensitizing Tf antigen in solution. The anti-Tf molecules on the immunosensor exhibited a greater molecular force bound to holo-Tf (iron-containing form of Tf) than that to apo-Tf (iron-absent form of Tf). Consistently, the anti-Tf immunosensor had a greater electrochemical capacity to sensitize apo-Tf than holo-Tf, supporting the molecular force-based finding by AFM. Thus, the present study elucidated the nanostructures and molecular force bases for the immunosensing capacity of a highly sensitive capacitive immunosensor.     

Elevated level of hyaluronic acid binding protein in diabetic rats.

Hyaluronic acid binding protein (HABP), an extracellular matrix glycoprotein which interacts specifically with hyaluronic acid (HA) has been purified to homogeneity by HA affinity chromatography. Antibody was raised against it and the specificity of antibody towards HABP was confirmed by western blot analysis. A specific and sensitive assay method has been developed adopting solid phase non-competitive double sandwich method of ELISA. This new assay method enabled us to determine the levels of HABP in different tissue extracts of normal, diabetic and reverse diabetic rats. A significant increase in the levels of HABP was observed in diabetic animals, which however attained normal levels with insulin treatment.     

胶体金修饰纳米免疫传感器的制备与性能测定

基于原子力显微术,利用电化学、胶体金修饰等,进行与生物分子的结构与功能相关的免疫识别研究。利用分子自组装技术,设计出胶体金修饰CD29免疫传感器,并将原子力显微镜(AFM)针尖修饰CD29后,利用力曲线模式,对免疫传感器进行分子识别及活性点分析。CD29免疫传感器的活性点分析表明,只有62.5%的表面区域有明显力的黏附性,即活性部位,其余部分无活性。通过AFM扫描表面,发现抗体在表面聚集成团状,失去蛋白分子的原有结构,且将活性部位隐藏于内部。推断出这可能是导致蛋白失活的主要原因。     

Structural flexibility of multifunctional HABP1 may be important for regulating its binding to different ligands

Hyaluronan-binding protein 1 (HABP1)/p32/gC1qR was characterized as a highly acidic and oligomeric protein, which binds to different ligands like hyaluronan, C1q, and mannosylated albumin. It exists as trimer in high ionic and reducing conditions as shown by crystal structure. In the present study, we have examined the structural changes of HABP1 under a wide range of ionic environments. HABP1 exhibits structural plasticity, which is influenced by the ionic environment under in vitro conditions near physiological pH. At low ionic strength HABP1 exists in a highly expanded and loosely held trimeric structure, similar to that of the molten globule-like state, whereas the presence of salt stabilizes the trimeric structure in a more compact fashion. It is likely that the combination of the high net charge asymmetrically distributed along the faces of the molecule and the relatively low intrinsic hydrophobicity of HABP1 result in its expanded structure at neutral pH. Thus, the addition of counter ions in the molecular environment minimizes the intramolecular electrostatic repulsion in HABP1 leading to its stable and compact conformations, which reflect in its differential binding toward different ligands. Whereas the binding of HABP1 toward HA is enhanced on increasing the ionic strength, no significant effect was observed with the two other ligands, C1q and mannosylated albumin. Thus, although HA interacts only with compact HABP1, C1q and mannosylated albumin can bind to loosely held oligomeric HABP1 as well. In other words, structural changes in HABP1 mediated by changes in the ionic environment are responsible for recognizing different ligands.     

Hyaluronan and a cell-associated hyaluronan binding protein regulate the locomotion of ras-transformed cells

Hyaluronan (HA) and one of its cell binding sites, fibroblast hyaluronan binding protein (HABP), is shown to contribute to the regulation of 10T1/2 cell locomotion that contain an EJ-ras-metallothionein (MT-1) hybrid gene. Promotion of the ras-hybrid gene with zinc sulfate acutely stimulates, by 6-10-fold, cell locomotion. After 10 h, locomotion drops to two- to threefold above that of uninduced cells. Several observations indicate increased locomotion is partly regulated by HA. These include the ability of a peptide that specifically binds HA (HABR) to reduce locomotion, the ability of HA (0.001-0.1 micrograms/ml), added at 10-30 h after induction to stimulate locomotion back to the original, acute rate, and the ability of an mAb specific to a 56-kD fibroblast HABP to block locomotion. Further, both HA and HABP products are regulated by induction of the ras gene. The effect of exogenous HA is blocked by HABR, is dose-dependent and specific in that chondroitin sulfate or heparan have no significant effect. Stimulatory activity is retained by purified HA and lost upon digestion with Streptomyces hyaluronidase indicating that the activity of HA resides in its glycosaminoglycan chain. Uninduced cells are not affected by HA, HABR, or mAb and production of HA or HABP is not altered during the experimental period. These results suggest that ras-transformation activates an HA/HABP locomotory mechanism that forms part of an autocrine motility mechanism. Reliance of induced cells on HA/HABP for locomotion is transient and specific to the induced state.     

A nanobeads amplified QCM immunosensor for the detection of avian influenza virus H5N1

As a potential pandemic threat to human health, there has been an urgent need for rapid detection of the highly pathogenic avian influenza (AI) H5N1 virus. In this study, magnetic nanobeads amplification based quartz crystal microbalance (QCM) immunosensor was developed as a new method and application for AI H5N1 virus detection. Polyclonal antibodies against AI H5N1 virus surface antigen HA (Hemagglutinin) were immobilized on the gold surface of the QCM crystal through self-assembled monolayer (SAM) of 16-mercaptohexadecanoic acid (MHDA). Target H5N1 viruses were then captured by the immobilized antibodies, resulting in a change in the frequency. Magnetic nanobeads (diameter, 30nm) coated with anti-H5 antibodies were used for further amplification of the binding reaction between antibody and antigen (virus). Both bindings of target H5N1 viruses and magnetic nanobeads onto the crystal surface were further confirmed by environmental scanning electron microscopy (ESEM). The QCM immunosensor could detect the H5N1 virus at a titer higher than 0.0128 HA unit within 2h. The nanobeads amplification resulted in much better detection signal for target virus with lower titers. The response of the antibody-antigen (virus) interaction was shown to be virus titer-dependent, and a linear correlation between the logarithmic number of H5N1 virus titers and frequency shift was found from 0.128 to 12.8 HA unit. No significant interference was observed from non-target subtypes such as AI subtypes H3N2, H2N2, and H4N8. The immunosensor was evaluated using chicken tracheal swab samples. This research demonstrated that the magnetic nanobeads amplification based QCM immunosensor has a great potential to be an alternative method for rapid, sensitive, and specific detection of AI virus H5N1 in agricultural, food, environmental and clinical samples.     

Immunosensors for pesticide analysis: antibody production and sensor development

Immunosensors, a type of affinity biosensor, are based on the binding interactions between an immobilized biomolecule (antibody/antigen) on the electronic transducer surface with the analyte of interest (antigen/antibody), resulting in a detectable signal. The sensor system takes advantage of the high selectivity provided by the molecular recognition characteristic of an antibody, which binds reversibly with a specific antigen. This review article presents the current status of immunosensors, highlighting their potential benefits and limitations for pesticide analysis. The basic criteria for generating specific antibodies against low-molecular-mass pesticides, which are usually nonimmunogenic in nature, are briefly discussed. The article also describes the fundamentals of important transducer technologies and their use in immunosensor development.     

Highly stable electrochemical immunosensor for carcinoembryonic antigen

The long-term stability of sensing interfaces is an important issue in biosensor fabrication. A novel stable gold nanoparticle (AuNP)-modified glassy carbon (GC) electrode interface (GC-Ph-AuNP)-based biosensor for detecting carcinoembryonic antigen (CEA) was developed. GC electrodes were modified with 1,4-phenylenediamine to form a stable layer, and then AuNPs were bound onto the GC electrodes through CAu bonds. Anti-CEA was directly adsorbed on AuNPs fixed on the GC electrode. The linear range of the immunosensor was from 10 fg to 100 ng mL(-1) with a detection limit of 3 fg mL(-1) (S/N=3). The current of the immunosensor was increased by 4% after one month. The GC-Ph-AuNP immunosensor showed high sensitivity, a wide linear range, low detection limit, and good selectivity and stability. The immobilization method of the immunosensor could be widely applied to construct other immunosensors.     

Quartz crystal microbalance immunosensors for environmental monitoring

This paper presents discussion of quartz crystal microbalance (QCM) immunosensors for environmental monitoring. Factors limiting the practical application of antibodies to analytical problems are also presented. Among several candidates for the QCM immunosensor device, selected QCM devices and oscillating circuits were tested thoroughly and developed to obtain highly stable and sensitive frequency signals. The biointerface of QCM immunosensor was designed and controlled to immobilize antibody on the QCM surface, to reduce non-specific binding and to suppress denaturation of immobilizing antibody by self-assembled monolayer technique and artificial phospholipid (2-methacryloyloxyethyl phosphorylcholine (MPC)) polymer. MPC polymer as a antibody-stabilizing reagent was added to reduce non-specific binding of the antigen solution and stabilize the immunologic activity of the antibody-immobilized QCM. In addition, it provides examples for detection and quantitation of environmental samples using QCM immunosensors. The analytical results for fly ash extracted samples of dioxins using the QCM immunosensor indicated a good relationship with GC/MS methods. The integrating protocols of the competitive immunoassay and signal-enhancing step are for detecting low molecular analytes with extremely low detection limits using an QCM immunosensor. Furthermore, its detect limitation was extended from 0.1 to 0.01 ng/ml by the signal-enhancing step when the anti-bisphenol-A antibody conjugated MPC polymeric nanoparticles was used. The QCM immunosensor method has demonstrated its effectiveness as an alternative screening method for environmental monitoring because these results were compared with results obtained through environmental monitoring methods such as ELISA and GC/MS.     

食源性致病菌检测免疫传感器研究进展

食源性致病菌是造成食品安全事件的主要原因之一,因此其检测方法已成为人们研究的热点.食源性致病菌的检测方法主要有病原体培养法、免疫学方法、核酸检测和生物传感器等.其中,免疫传感器基于抗原抗体特异性结合,整合光学、电化学等多学科交叉技术,具有特异性强、检测速度快等特点.本文对比食源性致病菌传统检测方法,综述了近年来免疫传感...     

A novel multi-array immunoassay device for tumor markers based on insert-plug model of piezoelectric immunosensor

A novel multi-array immunoassay device based on the insert-plug model of piezoelectric (Pz) immunosensor fabricated with the screw clamp apparatus has been developed for quantitative detection of tumor markers such as alpha-fetoprotein (AFP), carcinoembryonic antigen (CEA), prostate specific antigen (PSA), and carcinoma antigen 125 (CA125) in serum, in which single immunosensor can oscillate independently with the frequency stability of +/-1 Hz (hertz) in air phase and +/-2 Hz in liquid phase. These response characteristics of Pz tumor marker multi-array immunoassay device such as time-cost, reproducibility and specificity, etc. were also investigated, respectively. The detection range for AFP, CEA, PSA and CA125 obtained by multi-array Pz immunosensor were 20-640 ng/ml, 1.5-30 microg/ml, 1.5-40 ng/ml and 5-150 IU/ml, respectively, with the coefficient of variance (CV) less than 5% and no cross-reactivates with other tumor markers in serum were observed. Application of the multi-array immunosensor to clinical samples demonstrated that results were in good agreement with chemiluminescence immunoassay (CLIA). Moreover, the multi-array Pz immunosensor could be regenerated to be reused for three cycles without appreciable loss of response activity. Therefore, the proposed multi-array immunoassay device based on Pz immunosensor provides a rapid, sensitive, specific, reusable, convenient and reliable alternative for the detection of tumor markers in clinical laboratory.     

pH and cation-induced thermodynamic stability of human hyaluronan binding protein 1 regulates its hyaluronan affinity

Hyaluronan-binding protein 1 (HABP1) is a trimeric protein with high negative charges distributed asymmetrically along the faces of the molecule. Recently, we have reported that HABP1 exhibits a high degree of structural flexibility, which can be perturbed by ions under in vitro conditions near physiological pH (Jha, B. K., Salunke, D. M., and Datta, K. (2003) J. Biol. Chem. 278, 27464-27472). Here, we report the effect of ionic strength and pH on thermodynamic stability of HABP1. Trimeric HABP1 was shown to unfold reversibly upon dissociation ruling out the possibility of existence of folded monomer. An increase in ionic concentration (0.05-1 M) or decrease in pH (pH 8.0-pH 5.0) induced an unusually high thermodynamic stability of HABP1 as reflected in the gradual increase in transition midpoint temperature, enthalpy of transition, and conformational entropy. Our studies suggest that the presence of counter ions in the molecular environment of HABP1 leads to dramatic reduction of the intramolecular electrostatic repulsion either by de-ionizing the charged amino acid residues or by direct binding leading to a more stable conformation. A regulation on cellular HA-HABP1 interaction by changes in pH and ionic strength may exist, because the more stable conformation attained at higher ionic strength or at acidic pH showed maximum affinity toward HA as probed either in solid phase binding assay on HA-immobilized plates or an in-solution binding assay using intrinsic fluorescence of HABP1.     

An in situ electrochemical surface plasmon resonance immunosensor with polypyrrole propylic acid film: comparison between SPR and electrochemical responses from polymer formation to protein immunosensing

A novel in situ electrochemical surface plasmon resonance (EC-SPR) immunosensor is presented in this paper. The EC-SPR measurement can be used to in situ monitor the polymer formation, probe immobilization, antigen-antibody interaction and protein immunosensing process. A sandwich immunosensor based on permeable polypyrrole propylic acid (PPA) film is constructed using mouse IgG as a model analyte. The results show that the introduction of capture antibody conjugated enzyme not only enhances the current responses but also increases the SPR angle shift. The calibration curves of electrochemical (EC) and surface plasmon resonance (SPR) measurement exhibit a similar dependence on the bulk concentration of antigen. An approximate linear relationship can be obtained by plotting the data in semi-logarithmic reference frame. Compared with SPR, EC shows higher sensitivity with prolonged time. The in situ EC-SPR immunosensor described herein could have important potentials for diagnostics and medicine applications.     

6746 SERA peptide analogues immunogenicity and protective efficacy against malaria is associated with short alpha helix formation: malaria protection associated with peptides alpha helix shortening

Erythrocyte high activity binding peptides (HABPs) have been identified for the Plasmodium falciparum serine repeat antigen (SERA). HABP 6746, located in this protein's 50 kDa fragment had its critical binding residues replaced by amino acids having similar mass but different charge to change their immunologic properties. This peptide analogues were used to immunize Aotus monkeys that were challenged later on with a virulent P. falciparum strain to determine their protective efficacy. A shortening in alpha helix structure was found in the immunogenic and protective ones when their secondary structure was analyzed by NMR, to correlate their structure with their immunologic properties. These data, together with results from previous studies, suggest that this shortening in HABP helical configuration may lead to better fitting with immune system molecules, rendering them immunogenic and protective and therefore making them excellent candidates for consideration as components of a subunit based multicomponent synthetic vaccine against malaria.     

Immunosensors for Pesticide Analysis: Antibody Production and Sensor Development

ABSTRACT:?

Immunosensors, a type of affinity biosensor, are based on the binding interactions between an immobilized biomolecule (antibody/antigen) on the electronic transducer surface with the analyte of interest (antigen/antibody), resulting in a detectable signal. The sensor system takes advantage of the high selectivity provided by the molecular recognition characteristic of an antibody, which binds reversibly with a specific antigen.

This review article presents the current status of immunosensors, highlighting their potential benefits and limitations for pesticide analysis. The basic criteria for generating specific antibodies against low-molecular-mass pesticides, which are usually nonimmunogenic in nature, are briefly discussed. The article also describes the fundamentals of important transducer technologies and their use in immunosensor development.     

Label-free electrochemical immunosensor based on graphene/methylene blue nanocomposite

For the specificity of prostate cancer markers, prostate specific antigen (PSA) has been widely used in prostate cancer screening, diagnosis, and treatment after monitoring. In normal male serum, PSA can only be detected in traces of 0-4 ng mL(-1). In this paper, we constructed an electrochemical immunosensor for PSA detection using a nanocomposite film of graphene sheets-methylene blue-chitosan (GS-MB-CS) as electrode material. The nanocomposite film showed high binding affinity to the electrode and was used to immobilize the antibody of PSA. The modification procedure was monitored by cyclic voltammetry (CV). An amperometric biosensor was easily developed based on the response of peak current to the capture of PSA induced by specific antigen-antibody reactions. Under optimum conditions, the amperometric signal decreased linearly with PSA concentration (0.05-5.00 ng mL(-1)). A low limit of detection (13 pg mL(-1)) and a high selectivity are obtained. Moreover, the prepared immunosensor was applied for the analysis of PSA in serum samples with satisfactory results. The proposed method may have a promising future in biochemical assays for high selectivity, good reproducibility, and stability.