Reversible immobilization of an antibody with a thiol-substituted sorbent

In situ regeneration of bioactive coatings enabled by an evolved Staphylococcus aureus sortase A

Surface immobilization of bioactive molecules is a central paradigm in the design of implantable devices and biosensors with improved clinical performance capabilities. However, in vivo degradation or denaturation of surface constituents often limits the long-term performance of bioactive films. Here we demonstrate the capacity to repeatedly regenerate a covalently immobilized monomolecular thin film of bioactive molecules through a two-step stripping and recharging cycle. Reversible transpeptidation by a laboratory evolved Staphylococcus aureus sortase A (eSrtA) enabled the rapid immobilization of an anti-thrombogenic film in the presence of whole blood and permitted multiple cycles of film regeneration in vitro that preserved its biological activity. Moreover, eSrtA transpeptidation facilitated surface re-engineering of medical devices in situ after in vivo implantation through removal and restoration film constituents. These studies establish a rapid, orthogonal and reversible biochemical scheme to regenerate selective molecular constituents with the potential to extend the lifetime of bioactive films.

Bioactive coatings offer a strategy to modulate host response to implants, but their translation to the clinic is hampered by their fast in vivo degradation. Here, the authors use an engineered bacterial protein to regenerate an anti-thrombogenic film in vitro and in situ after device implantation.

Novel potentiometry immunoassay with amplified sensitivity for diphtheria antigen based on Nafion, colloidal Ag and polyvinyl butyral as matrixes

A novel potentiometry immunoassay with amplified sensitivity has been developed for the detection of diphtheria antigen (Diph) via immobilizing diphtheria antibody (anti-Diph) on a platinum electrode based on Nafion, colloidal Ag (Ag), and polyvinyl butyral (PVB) as matrixes in this study. The modified procedure was further characterized by electrochemical impedance spectroscopy (EIS) and cyclic voltammetry (CV). The influence and factors influencing the performance of resulting immunosensor were studied in detail. The resulting immunosensor exhibited sigmoid curve with log Diph concentrations, high sensitivity (51.4 mV/decade), wide linear range from 8 to 800 ng ml(-1) with a detection limit of 1.5 ng ml(-1), rapid potentiometric response (<3 min) and long-term stability (>6 months). Analytical results of clinical samples show that the developed immunoassay is comparable with the enzyme-linked immunosorbent assays (ELISAs) method, implying a promising alternative approach for detecting diphtheria antigen in the clinical diagnosis.

Environmental toxicity monitoring using electrochemical biosensing systems

Environmental monitoring faces the challenge of measuring an increasing number of analytes at ever decreasing concentrations. Since not all species of a given analyte have the same detrimental impact on the environment, new analytical devices and techniques are required to distinguish between the different species of a pollutant or different groups of pollutants. This paper describes analytical techniques based on biomaterials that are toxically sensitive to pollutants. This approach permits the biomonitoring of certain compounds by looking at their toxic properties. Although these techniques are based on a sound analytical strategy, their applications are limited because most of the interactions between the biological material and the analyte are irreversible. Additionally, the immobilised biological material has a limited stability. Several biomonitoring strategies based on electrochemical biosensing are discussed here and how to recover the bioactivity of biosensing system, both in discrete and automated procedures, is also reviewed.

Amperometric immunosensors based on protein A coupled polyaniline-perfluorosulfonated ionomer composite electrodes

A very sensitive immunosensor based on polyaniline/ Nafion/protein A (PA/NF/PrA) composite electrodes has been developed for the amperometric immunoanalysis with urease-labeled immunoreagents. The use of urease conjugated goat anti-RIgG (GaRIgG-Ur) as the labeled antibody and urea as the substrate with an amperometric detection at -200 mV (vs Ag/AgCl) resulted in a dynamic range of 50-2000 ng mL-1 and a low detection limit of 10 ng/mL (64 pM) for the immunoanalysis of rabbit immunoglobulin G (RIgG). Because of the special affinity between protein A and RIgG, the PA/NF/PrA electrode can be regenerated repetitively by changing the pH of the buffer solutions. Characteristics of the PA/NF/PrA/RIgG immunosensor and optimal conditions for the competitive immunoanalysis of RIgG with FIA were studied.

Development of electrochemical immunosensing systems with renewable surfaces

The repeated use of immunochemically modified solid phases in electrochemical immunosensor analysis is the driving interest of this work. Two new strategies have been developed. One of these strategies is aimed at the development of a manual methodology. It comprises the construction of amperometric immunosensors based on rigid biocomposites. These biocomposites are formed by a conducting polymer composite matrix that acts as a reservoir of an immobilized immunologic material. The surface of the biocomposite can be renewed by a simple polishing procedure. The second strategy involves the design of an automatic methodology. It features an immunochemical analytical system using flow injection techniques. The potentiometric detection uses a solid phase formed by immunologic reagents immobilized in magnetic particles. These particles are fixed to the sensor with the use of a magnetic field. The renewal of the reactive surface is achieved by the release and activation of the restraining magnetic field and the manipulation of the flow. The analytical properties of these immunosensors were evaluated measuring RIgG using a competitive technique and measuring GaRIgG with a sandwich methodology. The labelling enzymes of the immunoconjugates were peroxidase in amperometric measurements and urease in potentiometric measurements.