Immunoassay for the determination of morphine-3-glucuronide using a surface plasmon resonance-based biosensor

Polyclonal antibodies were produced for the development of competitive ELISA's and surface plasmon resonance (SPR)-based BIAcore inhibition assays for the detection of morphine-3-glucuronide (M3G, the main metabolite of heroin and morphine). A conjugate consisting of M3G and ovalbumin was produced and used for the generation of antibodies, for the coating of immunoplates and for immobilisation onto BIAcore chips. Competition ELISA's were developed in PBS and urine to characterise the antibodies ability to recognise free M3G. SPR-based inhibition immunoassays on BIAcore were developed. The regeneration of the surface of a chip immobilised with conjugate following antibody binding, essential for the development of inhibition assays was investigated. Regeneration of the conjugate-coated surface was optimised for both polyclonal antibodies resulting in binding-regeneration capacities of approximately 60 cycles for one antibody and 50 cycles for the second antibody. The inhibition assays developed in urine had ranges of detection of 762-24,400 (antibody 1) and 976-62,500 pg ml(-1) (antibody 2). The inter-day coefficients of variation for the assays ranged from 1.48 to 11.24%.     

Prostate-specific antigen immunosensing based on mixed self-assembled monolayers, camel antibodies and colloidal gold enhanced sandwich assays

Prostate-specific antigen (PSA) is a valuable biomarker for prostate cancer screening. We developed a PSA immunoassay on a commercially available surface plasmon resonance biosensor. Our PSA receptor molecule consists of a single domain antigen-binding fragment, cAbPSA-N7, derived from dromedary heavy-chain antibodies and identified after phage display. It binds PSA with a high k(on) value of 1.9x10(6) M-1 s-1, and was covalently immobilised on a gold substrate via a mixed self-assembled monolayer (SAM) of alkanethiols by using carbodiimide-coupling chemistry in 10mM acetate buffer pH 5.5 to obtain an optimal pre-concentration. The best performing and optimised mixed SAM consisted of (10%) 16-mercapto-1-hexadecanoic acid (16-MHA) for covalent cAbPSA-N7 immobilisation and (90%) 11-mercapto-1-undecanol (11-MUOH) to minimise non-specific adsorption of the analyte. In this way, two advantages are incorporated in a single coupling layer. Up to 28 fmol/mm2 of cAbPSA-N7 could be immobilised and 30% of its binding sites participate actively in PSA interaction. In addition, the optimised layer showed also optimal performance to assess physiological samples. Although PSA concentrations as low as 10 ng/ml could be detected directly, this detection limit could be enhanced to PSA levels in the sub ng/ml range by introducing a sandwich assay involving a biotinylated secondary antibody and streptavidin modified gold nanoparticles. This approach realizes the PSA detection at clinical relevant concentrations.     

Multi-analyte assay for triazines using cross-reactive antibodies and neural networks

A biosensor system based on total internal reflectance fluorescence (TIRF) was used to discriminate a mixture of the triazines atrazine and simazine. Only cross-reactive antibodies were available for these two analytes. The biosensor is fully automated and can be regenerated allowing several hundreds of measurements without any user input. Even a remote control for online monitoring in the field is possible. The multivariate calibration of the sensor signal was performed using artificial neural networks, as the relationship between the sensor signals and the concentration of the analytes is highly non-linear. For the development of a multi-analyte immunoassay consisting of two polyclonal antibodies with cross-reactivity to atrazine and simazine and different derivatives immobilised on the transducer surface, the binding characteristics between these substances like binding capacity and cross-reactivity were characterised. The examination of three different measurement procedures showed that a two-step measurement using only one antibody per step allows a quantification of both analytes in a mixture with limits of detection of 0.2 microg/l for atrazine and 0.3 microg/l for simazine. The biosensor is suitable for online monitoring in the field and remote control is possible.     

Glyptal as a support for enzyme immobilisation

Glyptal, a polyester obtained from phthalic anhydride and glycerol, was used as a support for protein immobilisation. Hydrazide groups were introduced in the polymer and then converted to azide groups, through which protein was covalently immobilised. Amyloglucosidase was used as a model and an insoluble water derivative was synthesised retaining 24 % of the specific activity of the native enzyme. Some properties of this immobilised enzyme were studied: Km (4.54 g.l^–1 using starch as substrate), optimal temperature (55°C) and half life (8 days). Furthermore, ferromagnetic-azide-glyptal derivative showed to be useful for the amyloglucosidase immobilisation.     

The development of a 'labeless' immunosensor for the detection of Listeria monocytogenes cell surface protein, Internalin B

Electrochemical impedance spectroscopy (EIS) is a widely used technique for probing bioaffinity interactions at the surfaces of electrically conducting polymers. EIS methods can be employed to investigate 'labeless' detection of analytes via impedimetric transduction. This paper describes the development of a direct immunosensor for the detection of a cell-surface protein on Listeria monocytogenes, an extremely important food-borne pathogen. L. monocytogenes are facultative anaerobic, non-sporing, Gram-positive, motile rods that employ the surface bound protein, Internalin B (InlB), to promote invasion into host cells. A recombinant form of InlB was previously cloned and expressed in Escherichia coli and a panel of antibodies and antibody fragments directed against the protein were also produced. Here, we describe how a portion of the recombinant InlB protein, the F3 fragment, and an anti-InlB polyclonal antibody, were used to develop a platform for the labeless immunosensing of InlB. Sensors were fabricated by electropolymerisation of planar screen-printed carbon electrodes with polyaniline (PANI), to produce a conductive substrate. Polyclonal anti-InlB antibody was subsequently incorporated onto the PANI layer using a biotin-avidin system for site-specific immobilisation. The sensors were then probed with varying concentrations of InlB antigen and the impedimetric response at each concentration was recorded. An anti-IgG antibody was immobilised at the electrode surface, as a control and subsequently exposed to the same concentrations of InlB. Impedimetric data for the control sensors were also recorded. Upon exposure to a range of concentrations of antigen, complex plane impedance analyses were used to relate the differing redox states of the polymer layer, to the possible charge transfer at the surface, with respect to the related mechanisms between the antibody and the polymer. These effects were subsequently monitored to assess the impedance of the polymer thereby determining the amount of bound antigen at the sensor surface. Calibration profiles for both sample (InlB) and control (IgG) sensors were constructed. A limit of detection of 4.1 pg/ml was achieved for Internalin B.     

Simultaneous electrochemical immunoassay using CdS/DNA and PbS/DNA nanochains as labels

An electrochemical method for the simultaneous detection of two different tumor markers, carcinoembryonic antigen (CEA) and α-fetoprotein (AFP), in one-pot, using CdS/DNA and PbS/DNA nanochains as labels was developed. Herein, magnetic beads (MBs) as bimolecule immobilizing carriers, were used for co-immobilization of primary anti-CEA and anti-AFP antibodies. The distinguishable signal labels were synthesized by in situ growth of CdS and PbS nanoparticles on DNA chains, respectively, which were further employed to label the corresponding secondary antibodies. A sandwich-type immunoassay format was formed by the biorecognition of the antigens and corresponding antibodies. The assay was based on the peak currents of Cd(2+) and Pb(2+) dissolved from CdS and PbS nanoparticles by HNO(3) using square wave stripping voltammetry. Experimental results show that the multiplexed electrochemical immunoassay has enabled the simultaneous monitoring of CEA and AFP in a single run with wide working ranges of 0.1-100ngmL(-1) for CEA and 0.5-200ngmL(-1) for AFP. The detection limits reach to 3.3pgmL(-1) for CEA and 7.8pgmL(-1) for AFP.     

Electrochemical genosensor design: immobilisation of oligonucleotides onto transducer surfaces and detection methods

The present report reviews immobilisation techniques of purified oligonucleotides on electrochemical transducers and their corresponding detection techniques. Most of the literature reviewed was published in the 1990s. The immobilisation techniques of a DNA probe to the surface of an electrochemical transducer made from carbon, gold, platinum or polypyrrole, ranged from simple adsorption to covalent bonding. Recent efforts to couple the recognition layer containing the immobilised nucleic acid recognition layer with the electrochemical signal transducer are discussed. Special attention is given to hybridisation biosensing based on electroactive indicators.     

Design and construction of novel molecular conjugates for signal amplification (I): conjugation of multiple horseradish peroxidase molecules to immunoglobulin via primary amines on lysine peptide chains

Immunoconjugates are widely used for indirect detection of analytes (such as antibodies or antigens) in a variety of immunoassays. However, the availability of functional groups such as primary amines or free sulfhydryls in an immunoglobulin molecule is the limiting factor for optimal conjugation and, therefore, determines the sensitivity of an assay. In the present study, an N-terminal bromoacetylated 20 amino acid peptide containing 20 lysine residues was conjugated to N-succinimidyl-S-acetylthioacetate (SATA)-modified IgG or free sulfhydryl groups on 2-mercaptoethylamine (2-MEA)-reduced IgG molecules via a thioether (S---CH₂CONH) linkage to introduce multiple reactive primary amines per IgG. These primary amines were then covalently coupled with maleimide-activated horseradish peroxidase (HRP). The poly-HRP–antibody conjugates thus generated demonstrated greater than 15-fold signal amplification upon reaction with orthophenyldiamine substrate. The poly-HRP–antibody conjugates efficiently detected human immunodeficiency virus (HIV)-1 antibodies in plasma specimens with significantly higher sensitivity than conventionally prepared HRP–antibody conjugates in an HIV-1 solid-phase enzyme immunoassay and Western blot analysis. The signal amplification techniques reported here could have the potential for development of highly sensitive immunodiagnostic assay systems.     

Characterisation of an antibody coated microcantilever as a potential immuno-based biosensor

In this study, we investigated the activity, stability, lifetime and re-usability of monoclonal antibodies to myoglobin covalently immobilised onto microfabricated cantilever surfaces. These sensing surfaces are of interest to us in the development of novel cantilever-based immunosensors. For such sensors the antibody layer represents the sensing element while the microcantilever acts as a mechanical transducer. A procedure for producing re-usable biological coatings has been tested with different independent techniques. An Enzyme Linked Immunosorbent Assay (ELISA) was used to determine the presence of an active antibody coating, and to monitor the lifetime and stability of the immobilised antibody. Through this analysis, the activity of the immobilised antibody layer was found to be more stable with the introduction of sucrose, as a stabilising agent. Sucrose was applied to the immobilised antibody layer after each regeneration step. The immobilised antibody was found to have a stable active lifetime for up to 7 weeks. Fluorescence microscopy was used to give information on the distribution of the coating on the gold and silicon nitride sides of the cantilever. Atomic Force Microscopy was used to determine the presence of the biological coating on the cantilever and to obtain information on the surface morphology of the biological element of the sensor. The combined results provide valuable information on the development of an optimised sensing element and demonstrate a set of methods to use for future sensor-to-sensor characterisation. Preliminary experimental results showing the antibody activity against myoglobin, detected with a microcantilever based sensor prototype confirmed the motivations and potentialities of the proposed immunosensing technique.     

Amperometric enzyme biosensors based on optimised electron-transfer pathways and non-manual immobilisation procedures

Development of reagentless biosensors implies the tight and functional immobilisation of biological recognition elements on transducer surfaces. Specifically, in the case of amperometric enzyme electrodes, electron-transfer pathways between the immobilised redox protein and the electrode surface have to be established allowing a fast electron transfer concomitantly avoiding free-diffusing redox species. Based on the specific nature of different redox proteins and non-manual immobilisation procedures possible biosensor designs are discussed, namely biosensors based on (i) direct electron transfer between redox proteins and electrodes modified with self-assembled monolayers; (ii) anisotropic orientation of redox proteins at monolayer-modified electrodes; (iii) electron-transfer cascades via redox hydrogels; and (iv) electron-transfer via conducting polymers.     

Hybridisation of surface-immobilised single-stranded oligonucleotides and polymer monitored by surface plasmon resonance

We have investigated the hybridisation of thiol-modified single-stranded DNA embedded in a polyacrylamide layer through the technique of surface plasmon resonance (SPR). Kinetic studies were carried out by two different immobilisation methods: (a) SH-ssDNA was firstly attached on gold and the remaining free space was filled with polymer and (b) SH-ssDNA and the polymer was attached onto the surface from the same solution. The immobilisation methods were compared for various concentrations of SH-ssDNA. Hybridisation was dependent on both the immobilisation method and the concentration of the components. The highest hybridisation was obtained when SH-ssDNA and the polymer was immobilised from the same solution at low SH-ssDNA concentration or when high concentrations of oligos were spread onto the surface and the surface was post-treated with polymer. The target response corresponded to a surface coverage of 100+/-15 ng/cm2. The same surface coverage on hybridisation was also obtained when low concentration of SH-ssDNA and polymer was attached onto the surface from the same solution. The non-specific binding of sample DNA was very low at optimal concentrations due to the polymer and the hybridisation was linearly dependent on target concentration.     

Development of nanomechanical biosensors for detection of the pesticide DDT

We report the use of a novel technique for detection of the organochlorine insecticide compound dichlorodiphenyltrichloroethane (DDT) by measuring the nanometer-scale bending of a microcantilever produced by differential surface stress. A synthetic hapten of the pesticide conjugated with bovine serum albumin (BSA) was covalently immobilised on the gold-coated side of the cantilever by using thiol self assembled monolayers. The immobilisation process is characterised by monitoring the cantilever deflection in real-time. Then specific detection is achieved by exposing the cantilever to a solution of a specific monoclonal antibody to the DDT hapten derivative. The specific binding of the antibodies on the cantilever sensitised side is measured with nanomolar sensitivity. Direct detection is proved by performing competitive assays, in which the cantilever is exposed to a mixed solution of the monoclonal antibody and DDT. The future prospects and limitations to be overcome for the application of nanomechanical sensors for pesticide detection are discussed.     

Development of QCM biosensor to detect a marine derived pathogenic bacteria Edwardsiella tarda using a novel immobilisation method

QCM technology offers a real time output, simplicity of use and cost effectiveness in addition to high sensitivity. Sensitivity of QCM immunosensor can be enhanced by improving the immobilisation procedure on the quartz surface. The immobilisation strategy should be able to control both the amount and the orientation of the antibody (immunoglobulin; IgG) on the transducer for high affinity to antigens. This study introduced a new methodology recruiting oxidised IgG to expose aldehyde group in Fc region to cross-link to hydrazide conformed on self assembled monolayer (SAM) and compared with three conventional methods. Consequently, it was proved that considerable amount of antibody was immobilised and the sensitivity of new methodology was higher than other methods while ability of new methodology to immobilise IgG was lower than the conventional methods. The frequency shifts following bacterial cell injection were positively related to the frequency shifts after the injection of IgG and the amounts of bacterial cells, revealing that the frequency shifts after bacterial cell injection fully represented the weight change by specific attachments of bacterial cells to the IgG cross-linked on the gold surface. Specificity was tested on different bacteria including E. coli, V. vulnificus and A. hydrophila and showed no significant non-specific affinity on the tested bacteria. It was also demonstrated that the prepared sensor chip was stable enough to withstand repeated surface regeneration. Indeed, polyclonal antibody was more effective to detect antigen than monoclonal antibody which binds to only one epitope of antigen. Conclusively, the new methodology is appeared to be more sensitive than conventional methods tested and reusable for 10 times.     

Biomolecule immobilization in biosensor development: tailored strategies based on affinity interactions

The exponential development of biosensors as powerful analytical tools in the last four decades mainly relies on the high sensitivity and selectivity offered when detecting the target analyte. The transducer and the biological receptor are the bases of the biosensor development. Nevertheless, the bioreceptor immobilisation is also important, playing a key role in the retention of the biological activity, and thus affecting the sensitivity. Parameters such as shelf-life and surface regeneration also depend on the biomolecule immobilisation. Researchers are focusing their efforts towards random and oriented immobilisation procedures. Adsorption, entrapment, cross-linking and electrostatic interactions provide randomly immobilised biomolecules, sometimes partially hindering their biological activity. Covalent binding and affinity interactions may enable oriented biomolecule immobilisations, providing controlled, reproducible and highly active modified surfaces. This paper reviews the main immobilisation strategies used in the biosensors development, putting special emphasis on our contribution to mild and oriented immobilisation techniques.     

Investigation of osteoprotegerin interactions with ligands and antibodies using piezoelectric biosensors

Osteoprotegerin (OPG, osteoclastogenesis inhibitory factor) is a secretory glycoprotein involved as a soluble factor in the regulation of bone mass. OPG and its ligand (RANKL) levels in serum indicate the osteoclast formation activity. Alterations of the RANKL/OPG concentration ratio may be the cause of bone loss in many imbalances including osteoporosis, hypercalcaemia, metastatic osteolytic lesions and rheumatic bone degradation. The interactions of OPG with several antibodies were studied using the piezoelectric quartz crystal sensor. Monoclonal anti-OPG antibodies (5H3, 4E6H9 and OPG1.3) were immobilised on the sensing surface modified with covalently attached monolayer of protein A. Binding of both OPG standard and recombinant OPGFc chimeric protein was followed in real time. All antibodies were able to bind OPG and OPGFc, though in the case of MAb 4E6H9 the immunocomplexes dissociated quickly in the absence of OPG. Alternatively, biorecognition layers with RANKL were used. Two versions of the piezoelectric sensor for OPG were developed. The direct immunosensor was based on the antibody 5H3 and the affinity sensor employed the immobilised RANKL. The RANKL sensor exhibited poor reproducibility of results. For the immunosensor, the measuring range was 1.2-35 U/L of OPG. One analysis was completed within 15 min; the sensors were used repeatedly using regeneration with glycine buffer (pH 2.0). The developed immunosensor seems promising for rapid determination of osteoprotegerin in serum.     

Directed immobilization of nucleic acids at ultramicroelectrodes using a novel electro-deposited polymer

A two-step method for the directed immobilization of nucleic acids at ultramicroelectrodes with micron-size dimensions is described. The approach is based on the immobilization of streptavidin at the surface of carbon or noble metal electrodes within a novel electro-deposited polymer, formed by electropolymerization of the natural compound scopoletin (7-hydroxy-6-methoxy-coumarin) at potentials between 0.4 and 0.7 V vs. Ag/AgCl. Biotin-tagged nucleic acids or proteins are immobilized on top of the modified electrodes in a second step. The new method has some advantages compared to classical electropolymerization approaches (e.g. polypyrrole, polyphenol), because the growing polymer is highly hydrophilic, resulting in efficient incorporation of streptavidin and a high biotin binding capacity of 6 pmol cm(-2). The polymer film seems to be non-conductive but shows good swelling properties in aqueous solutions. The feasibility of the method for the electro-directed biochemical modification of individual microelectrodes has been demonstrated by sequential immobilization of two different single strand oligonucleotides onto interdigitated ultramicroelectrodes. The resulting miniature DNA probe was used for single base mutation detection with two synthetic targets (fluorescence-labeled 17-mer oligomers) by evaluating the fluorescence patterns after hybridisation with the immobilised DNA probes. The new method is useful for the production of microelectrode based DNA chips and for the electro-directed immobilisation of biomolecules at microelectrode structures with high spatial resolution and yield.     

Electrochemical DNA biosensor for bovine papillomavirus detection using polymeric film on screen-printed electrode

A new electrochemical DNA biosensor for bovine papillomavirus (BPV) detection that was based on screen-printed electrodes was comprehensively studied by electrochemical methods of cyclic voltammetry (CV) and differential pulse voltammetry (DPV). A BPV probe was immobilised on a working electrode (gold) modified with a polymeric film of poly-L-lysine (PLL) and chitosan. The experimental design was carried out to evaluate the influence of polymers, probe concentration (BPV probe) and immobilisation time on the electrochemical reduction of methylene blue (MB). The polymer poly-L-lysine (PLL), a probe concentration of 1μM and an immobilisation time of 60min showed the best result for the BPV probe immobilisation. With the hybridisation of a complementary target sequence (BPV target), the electrochemical signal decreased compared to a BPV probe immobilised on the modified PLL-gold electrode. Viral DNA that was extracted from cattle with papillomatosis also showed a decrease in the MB electrochemical reduction, which suggested that the decreased electrochemical signal corresponded to a bovine papillomavirus infection. The hybridisation specificity experiments further indicated that the biosensor could discriminate the complementary sequence from the non-complementary sequence. Thus, the results showed that the development of analytical devices, such as a biosensor, could assist in the rapid and efficient detection of bovine papillomavirus DNA and help in the prevention and treatment of papillomatosis in cattle.     

Optimisation of glass surfaces for optical immunosensors

The surfaces of glass sensor chips were modified with dextran to generate a layer protecting the sensor surface from unspecific protein binding and also serving as a matrix for covalent protein immobilisation. Dextran was coupled to the glass surface in different concentrations either covalently on amino-functionalised glass chips or via biotin-avidin binding. Unspecific binding of BSA was monitored with the grating coupler system, and was increasingly suppressed with increasing dextran concentrations. Using a solution with 100 mg/ml carboxymethylated dextran decreased the signals to approximately 2% of those obtained at an untreated glass chip. Antibodies were successfully immobilised in the dextran and binding to the corresponding Cy5-labelled antigen was repeatedly monitored using a fluorescence sensor system (total internal reflection fluorescence (TIRF)).     

Anti-rabbit immunoglobulin G detection in complex medium by PM-RAIRS and QCM Influence of the antibody immobilisation method

Two antibody immobilisation procedures were compared to set up an immunosensor for goat anti-rabbit immunoglobulin (anti-rIgG), i.e. rIgG covalently bound or immobilised via affinity to protein A (PrA). In both cases, the first layer of protein was covalently bound to a mixed self-assembled monolayer (SAM) of mercaptoundecanoic acid (MUA) and mercaptohexanol (C6OH) on a gold surface. The elaboration of the sensitive surfaces, as well as their selectivity and sensitivity were studied step by step by polarization modulation-reflection absorption infra-red spectroscopy (PM-RAIRS) and quartz crystal microbalance (QCM) with impedance measurement. QCM measurements showed that the viscoelastic properties of the antibody layer were markedly modified during the antigen recognition when the antibody was bound by affinity to PrA. The specific detection of antigen within a complex medium was assessed by PM-RAIRS thanks to the grafting of cobalt-carbonyl probes. Affinity constants between the immobilised rIgG and the anti-rIgG were determined from PM-RAIRS analysis.     

Use of a novel micro-fluidic device to create arrays for multiplex analysis of large and small molecular weight compounds by surface plasmon resonance

There is an increasing demand to develop biosensor monitoring devices capable of biomarker profiling for predicting animal adulteration and detecting multiple chemical contaminants or toxins in food produce. Surface plasmon resonance (SPR) biosensors are label free detection systems that monitor the binding of specific biomolecular recognition elements with binding partners. Essential to this technology are the production of biochips where a selected binding partner, antibody, biomarker protein or low molecular weight contaminant, is immobilised. A micro-fluidic immobilisation device allowing the covalent attachment of up to 16 binding partners in a linear array on a single surface has been developed for compatibility with a prototype multiplex SPR analyser. The immobilisation unit and multiplex SPR analyser were respectively evaluated in their ability to be fit-for-purpose for binding partner attachment and detection of high and low molecular weight molecules. The multiplexing capability of the dual technology was assessed using phycotoxin concentration analysis as a model system. The parent compounds of four toxin groups were immobilised within a single chip format and calibration curves were achieved. The chip design and SPR technology allowed the compartmentalisation of the binding interactions for each toxin group offering the added benefit of being able to distinguish between toxin families and perform concentration analysis. This model is particularly contemporary with the current drive to replace biological methods for phycotoxin screening.