Investigation of SPR and electrochemical detection of antigen with polypyrrole functionalized by biotinylated single-chain antibody: a review.

An electrochemical label-free immunosensor based on a biotinylated single-chain variable fragment (Sc-Fv) antibody immobilized on copolypyrrole film is described. An efficient immunosensor device formed by immobilization of a biotinylated single-chain antibody on an electropolymerized copolymer film of polypyrrole using biotin/streptavidin system has been demonstrated for the first time. The response of the biosensor toward antigen detection was monitored by surface plasmon resonance (SPR) and electrochemical analysis of the polypyrrole response by differential pulse voltammetry (DPV). The composition of the copolymer formed from a mixture of pyrrole (py) as spacer and a pyrrole bearing a N-hydroxyphthalimidyl ester group on its 3-position (pyNHP), acting as agent linker for biomolecule immobilization, was optimized for an efficient immunosensor device. The ratio of py:pyNHP for copolymer formation was studied with respect to the antibody immobilization and antigen detection. SPR was employed to monitor in real time the electropolymerization process as well as the step-by-step construction of the biosensor. FT-IR demonstrates the chemical copolymer composition and the efficiency of the covalent attachment of biomolecules. The film morphology was analyzed by electron scanning microscopy (SEM). Results show that a well organized layer is obtained after Sc-Fv antibody immobilization thanks to the copolymer composition defined with optimized pyrrole and functionalized pyrrole leading to high and intense redox signal of the polypyrrole layer obtained by the DPV method. Detection of specific antigen was demonstrated by both SPR and DPV, and a low concentration of 1 pg mL(-1) was detected by measuring the variation of the redox signal of polypyrrole.

Effect of the size of electrode on electrochemical properties of ferrocene-functionalized polypyrrole towards DNA sensing.

A simple and highly sensitive electrochemical DNA sensor based on a ferrocene-functionalized polypyrrole has been prepared on a microelectrode array substrate for a multi-DNA detection chip format. A copolymer formed with 1-(phthalimidylbutanoate)-1'-(N-(3-butylpyrrole)butanamide)ferrocene (Py-Fe-NHP) and pyrrole was electrocopolymerized on the gold surface of both macroelectrode and biochip formats. DNA probes bearing an amino group were covalently grafted by substitution of NHP groups and the hybridization reaction was followed by monitoring the redox signal of the ferrocenyl group acting as the probe. The integration of the polymers into chip format produces high-density arrays of individually addressable oligonucleotide microelectrodes. Results show that reducing the size of the electrodes from a macroelectrode to the chip format allows a variation of the nucleation and the growth process during electropolymerization of modified pyrrole monomers. These modifications enable an increase in the sensitivity and selectivity of DNA hybridization.