Comparison of two fluorescence immunoassay methods for the detection of endocrine disrupting chemicals in water.

We describe two fluorescence immunoassays capable of detecting endocrine disrupting compounds in waste water. The first fluorescence method is a heterogeneous assay using total internal reflection fluorescence (TIRF) detection. The second method is a homogeneous assay that utilizes energy transfer (ETIA). Both fluorescence immunoassays are compared with respect to detection principle and ability to quantify the model analytes estrone, estradiol, and ethinylestradiol in a complex matrix regarding recovery rates and limits of detection. Calibrations were performed for the three analytes using both fluorescence methods. Limits of detection between 0.01 and 0.85 microg/l are achieved. In addition, measurements in synthetic waste water spiked with the analytes were performed. Both immunoassays allow the detection in waste water with recovery rates in the range of 70-112%.

Miniaturization of a homogeneous fluorescence immunoassay based on energy transfer using nanotiter plates as high-density sample carriers.

The miniaturization of a homogeneous competitive immunoassay to a final assay volume of 70 nL is described. As the sample carrier, disposable plastic nanotiter plates (NTP) with dimensions of 2 x 2 cm2 containing 25 x 25 wells, corresponding to approximately 15,000 wells on a traditional 96-well microtiter plate footprint, were used. Sample handling was accomplished by a piezoelectrically actuated micropipet. To reduce evaporation while pipetting the assays, the NTP was handled in a closed humid chamber and cooled to the point of condensation. To avoid washing steps, a homogeneous assay was developed that was based on energy-transfer (ET). As a model system, an antibody-based assay for the detection of the environmentally relevant compound, simazine, in drinking water was chosen. Antibodies were labeled with the long-wavelength-excitable sulfoindocyanine dye Cy5 (donor), and a tracer was synthesized by labeling BSA with a triazine derivative and the acceptor dye Cy5.5. At low analyte concentrations, the tracer was preferably bound to the antibody binding sites. As a result of the close proximity of Cy5.5 and Cy5, an efficient quenching of the Cy5 fluorescence occurred. Higher analyte concentrations led to a progressive binding of the analyte to the antibody binding sites. The increased Cy5 fluorescence was determined by using a scanning laser-induced fluorescence detector. The limit of detection (LOD), using an antibody concentration of 20 nM, was 0.32 microg/L, or 1.11 x 10(-16) mol of simazine. In comparison, the LOD of the 96-well microtiter-plate-based ET immunoassay (micro-ETIA) was 0.15 microg/L, or 1.87 x 10(-13) mol. The LOD of the optimized micro-ETIA at 1 nM IgG, was 0.01 microg/L.