[Effect of conditions of monoclonal antibody adsorption on antigen-binding activity].

The dependence of the antigen-binding activity of immobilized antibodies on pH of a saturating buffer has been investigated. We analyzed 28 monoclonal antibodies (MCAs) produced by various hybridomas to three virus antigens, i.e., the nuclear p23 protein of hepatitis C virus (C core protein p23), p24 protein of HIV 1, and the surface antigen of hepatitis B virus (HBsAg). Antibodies were adsorbed on the surfaces of immune plates in acidic (pH 2.8), neutral (pH 7.5), and alkaline (pH 9.5) buffers. The binding of labeled antigens, i.e., biotinylated or conjugated with horseradish peroxidase, with immobilized antigens was tested. It was shown that 10 out of 28 analyzed MCAs (36%) considerably better preserved their antigen-binding activity if their passive adsorption was carried out on the surface of polystyrene plates in an acidic buffer (pH 2.8). This approach allowed constructing a highly sensitive sandwich method for HBsAg assay with a minimal reliably determined antigen concentration of 0.013-0.017 ng/ml. The described approach may be recommended for the optimization of sandwich methods and solid-phase competitive methods.

[Use of pH-sensitive immobilized monoclonal antibodies for optimization of immunoenzyme sandwich technique of detection of HBsAg of hepatitis B virus].

AIM: To develop highly sensitive sandwich technique for identification of surface hepatitis B virus antigen (HBsAg) in serum and analyse of possible improvement of solid phase for immunoenzyme sandwich technique of HBsAg identification through variation of pH-dependent sorption of monoclonal antibodies on the surface of immune plates. MATERIALS AND METHODS: Calibration curves for identification of HBsAg in sandwich techniques using 36 possible binary combinations of monoclonal antibodies of our panel (including high affinity antibodies to HBsAg produced by 6 hybridomas) were compared. Immobilization of antibodies on solid phase (by passive sorption) was performed at different pH values (2.8, 7.5, and 9.5). RESULTS: Analysis of panel of antibodies to HBsAg produced by 6 hybridomas revealed pH-dependent monoclonal antibodies (18C8), which immobilization at low pH values together with detecting antibodies F4F3 allowed to greatly improve sensitivity of the sandwich technique. Minimal credibly detectable concentration of HBsAg in sera of persons infected with hepatitis B virus was 0.013 - 0.017 ng/ml. Validation of sandwich technique was performed on certified panel of serum samples with various concentrations of HBsAg (different serotypes). CONCLUSION: Highly sensitive sandwich technique for detection of HBsAg was developed. It was shown that analysis of panel of monoclonal antibodies on pH-dependence could be used as simple methodical approach for optimization of immunoenzyme sandwich techniques for detection of different antigens.