Development of an offline noncompetitive flow immunoassay for the determination of interleukin-8 in cell samples.

A noncompetitive flow immunoassay system (FIA) for the analysis of interleukin-8 (IL-8) in cell samples was developed. Affinity interaction assays based on offline incubation of excess labeled antibodies and antigen (IL-8) were carried out. The residual unbound labeled antibody was trapped in an immunoaffinity column with immobilized IL-8 while the immunocomplex, labeled antibody/IL-8, was detected by a fluorescence detector. Two fluorophores, FLUOS and Cy5.5, were conjugated with IL-8 antibody. Optimization and comparison between the two fluorescent labeled antibodies were performed with regard to pH, antibody concentration, flow rate, injection volume, and association time. Additionally, a horseradish peroxidase enzyme label was used for the conjugation to the anti-IL-8. The enzyme substrate reaction was optimized with respect to temperature and length of the substrate reaction coil. The detection limits were found to be 200 amol using the FLUOS-labeled anti-IL-8 and 1 fmol using the Cy5.5 fluorescence label. The developed FIA technique was applied for the analysis of IL-8 in cell samples. Matrix-assisted laser desorption/ionization time-of-flight mass spectrometry was used to identify IL-8 in the cell samples.

An enzyme flow immunoassay that uses beta-galactosidase as the label and a cellobiose dehydrogenase biosensor as the label detector.

The aim was to develop a fast generic enzyme flow immunoassay (EFIA) using a beta-galactosidase (beta-GAL) label in combination with colorimetric detection as well as with a new amperometric biosensor as the label detector. The amperometric biosensor was previously developed within the group for the determination of diphenols in surface water samples. Antigen (Ag, analyte), tracer (Ag*, antigen labeled with beta-GAL), and antibody (Ab) were incubated off-line. After the equilibrium was reached, the sample was introduced into the flow system. The antibody complexes, AgAb and Ag*Ab, were trapped in a protein G column while the free unbound tracer was eluted and detected by an amperometric biosensor downstream after substrate reaction. The enzyme label beta-GAL converted the substrate 4-aminophenyl-beta-D-galactopyranoside (4-APG) into 4-aminophenol (4-AP), which subsequently was detected by a cellobiose dehydrogenase (CDH) modified solid graphite electrode. 4-AP was first oxidized at the electrode surface at +300 mV vs Ag/AgCl, and the formed 4-imino quinone (4-IQ) was reduced back to 4-AP by the CDH in the presence of cellobiose. By combining the EFIA with the CDH biosensor, the overall signal of one tracer molecule is amplified at two occasions, i.e., one enzyme label converts the substrate into many 4-AP molecules, and second these are further amplified by the CDH biosensor. The optimum conditions for the EFIA in terms of the molar ratio between tracer and beta-GAL, temperature, flow rate, etc., was investigated with colorimetric detection, using 2-nitrophenyl-beta-D-galactopyranoside (2-NPG) as the beta-GAL substrate. The performance of both the colorimetric and CDH biosensor detection was investigated and both methods were applied for determination of the model compound atrazine in spiked surface water samples. Detection limits of 0.056 +/- 0.008 and 0.038 +/- 0.007 microg L(-1) and IC50 values of 2.04 +/- 0.294 and 0.42 +/- 0.08 microg L(-1) were obtained for colorimetric and CDH detection, respectively. Matrix effects were less pronounced with the CDH biosensor than with colorimetric detection.

Rate-limiting steps of tyrosinase-modified electrodes for the detection of catechol.

The response currents obtained for tyrosinase-modified Teflon/graphite, carbon paste, and solid graphite electrodes in the presence of catechol are analyzed primarily using rotating disk electrode experiments. The rate-limiting steps, such as the electrochemical reduction of o-quinones and the enzymatic reduction of oxygen as well as the enzymatic oxidation of catechol, are theoretically considered and experimentally demonstrated for the different electrode configurations.

On-line supported liquid membrane-liquid chromatography with a phenol oxidase-based biosensor as a selective detection unit for the determination of phenols in blood plasma.

The potential of on-line combination of supported liquid membrane extraction and column liquid chromatography with a phenol oxidase-based biosensor as a selective detection unit has been investigated for the determination of phenols in human plasma. The phenols are selectively extracted into a porous PTFE (polytetraflouroethene) membrane impregnated with a water-immiscible organic solvent and further into an alkaline acceptor phase. Via an ion-exchange interface, the analytes are transferred to a reversed-phase column where they are separated and detected using the biosensor. No sample pretreatment before the extraction, except centrifugation, is made. Due to the high selectivity both in the extraction and in the detection steps and to the fact that the demands on the chromatographic separation are low, a quick separation using an eluent with a low concentration of organic modifier can be made, without affecting the biosensor response. Detection limits below the 50 microg/l level in blood plasma were obtained for the three model compounds, phenol, p-cresol and 4-chlorophenol.