Nonspecific particle-based method with two-photon excitation detection for sensitive protein quantification and cell counting.

A novel easy-to-use homogeneous method utilizing two-photon excitation (TPX) for quantification of proteins or counting of eukaryotic cells in solution has been developed. This highly sensitive technique is based on the adsorption competition between the sample and fluorescently labeled protein to micrometer-sized carboxylate modified polystyrene particles and detection of two-photon excited fluorescence. The adsorption of the labeled protein to the particles was detected as a distinct fluorescence on individual microparticles.

Modelling of multi-component immunoassay kinetics - A new node-based method for simulation of complex assays.

The behaviour of binding reactions in immunoassays can be predicted and studied by modelling methods. Simple antibody-analyte binding reaction kinetics can be simulated by e.g.

Theoretical assessments of errors in rapid immunoassays-how critical is the exact timing and reagent concentrations?

The reliability of rapid immunoassay is a concern due to an incomplete incubation to a non-equilibrium state and is susceptible to different error factors causing variance. The most critical point in the process should be found in order to improve the accuracy, and reproducibility of immunoassays, and enhance the system robustness. In this paper, the behavior of rapid assays is predicted by simulations using mechanistic assay model, based on antibody-analyte binding reaction kinetics.

Calibration of bioaffinity assays using kinetic data.

Bioaffinity assays are usually calibrated by using a set of standard measurements fitted to a simple empirical model. In this paper, a new calibration approach based on mechanistic model of reaction kinetics is presented. When the calibration assay is known in terms of reaction mechanism, incubation time, initial concentration, and rate constants, one can back-calculate concentrations of unknown samples measured in a nonequilibrium time point.