Quartz crystal microbalance study of DNA immobilization and hybridization for nucleic Acid sensor development.

The immobilization of two 30-mer oligonucleotides, one biotinylated (biotin-DNA) and the other having a mercaptohexyl group at the 5'-phosphate end (BS1-SH), onto modified gold surfaces has been examined using a quartz crystal microbalance (QCM). Both single-layer and multilayer DNA films were prepared. The single-layer films of biotin-DNA were constructed by binding to a precursor layer of avidin, which had been attached to the QCM either covalently using a water-soluble carbodiimide hydrochloride (EDC) and N-hydroxysuccinimide (NHS) or via electrostatic interaction with poly(allylamine hydrochloride) (PAH). Single-layer films of BS1-SH were also formed on PAH via the electrostatic attraction between the amine groups on PAH and the negatively charged phosphate backbone of DNA. Multilayer films of DNA were fabricated by the successive deposition of avidin and poly(styrenesulfonate) (PSS), up to a total of nine avidin/PSS layers, followed by DNA adsorption. DNA immobilization and hybridization of the immobilized DNAs was monitored in situ from QCM frequency changes. Hybridization was induced by exposure of the DNA-containing films to complementary DNA in solution. Equal frequency changes were observed for the DNA immobilization and hybridization steps for the single-layer films, indicating a DNA probe-to-hybridized DNA target ratio of 1:1. The multilayer DNA films also exhibited DNA hybridization, with a greater quantity of DNA hybridized compared with the single-layer films. The multilayer films provide a novel means for the fabrication of DNA-based thin films with increased capacity for nucleic acid detection.

Surface plasmon resonance studies of immunoreactions utilizing disposable diffraction gratings.

The specificity of protein binding between immuno-gamma globulin (IgG) and anti-IgG has been investigated by means of surface plasmon resonance measurements, with a view to determining whether a perspex replica of a holographic diffraction grating can be used efficiently as the momentum-coupling device. The replicas are easy to fabricate, of low cost, and may be useful as disposable sensing heads in a biosensor. The majority of all published work concerning surface-plasmon-based biosensors has detailed the use of prisms as the momentum-coupling devices. Therefore, the relative advantages and disadvantages of both systems are discussed in this paper, including a sensitive optical technique which is beyond the scope of prism geometries.

Immobilisation of IgG onto gold surfaces and its interaction with anti-IgG studied by surface plasmon resonance.

The optical excitation of surface plasmon resonance (SPR) at a metal dielectric interface has been used to study the binding of immunoglobulin G (IgG) to gold and anti-IgG to immobilised IgG layers. In these studies both a monoclonal mouse and polyclonal sheep IgG were used as receptor layers for anti-IgG. The kinetics of binding were investigated by monitoring the reflectivity of light at an angle close to plasmon resonance. Both the initial rate of change and final reflectivity were measured during and after protein binding. The amount of protein bound to the surface was found to be less for the monoclonal mouse IgG compared to the polyclonal sheep IgG, these two IgG nominally being of the same dimensions and molecular weight. Further, anti-IgG binding produced greater changes in reflectivity than the initial IgG layers. By fitting the full angle-dependent reflectivity data to the Fresnel equation the effective protein layer thicknesses of IgG and anti-IgG as a function of concentration were determined. Differences in the effective thickness of the bound layer for the two IgG was observed, the mouse IgG having a thinner effective thickness compared with the sheep IgG. The limitations of direct binding of protein to metal surfaces in SPR biosensor applications are discussed.