Two enzyme-linked amperometric immunosensors specific for salmonellas were developed as rapid methods for quantifying and detecting these organisms in pure cultures and foods. Both used alkaline phosphatase as the enzyme reporter molecule but one system used phenyl phosphate as the substrate followed by the electrochemical detection of phenol at a polarized platinum electrode. The other system incorporated an enzyme amplification step and relied on the electrochemical detection of a reduced mediator, ferrocyanide. Both assays were rapid (4 h) and specific and generated salmonella-dependent signals above 10(4) cfu/ml (phenyl phosphate system) or 10(5) cfu/ml (enzyme amplified system) in pure cultures and samples of several foods, although the results with beef samples showed considerable variation. Both systems were able to detect low (1-5 cfu/g or /ml) numbers of salmonellas in foods after non-selective (18 h) and selective (22 h) enrichment steps but four samples, out of 147, gave false positive results. False positive results were eliminated by reducing the enrichment steps to 6 h and 18 h respectively (90 samples).
A semi-homogeneous amperometric immunosensor specific to the protein A of Staphylococcus aureus was developed using direct electrochemical detection of phenol produced by alkaline phosphatase from phenyl phosphate. The immunosensor could reliably detect strains of protein A-bearing S. aureus in pure cultures at ca. 10(4) cfu/ml, and at ca. 10(5) cfu/g or ml in various food samples. Due to its semi-homogeneous nature, the system was very simple, easy to operate, and labour-saving. The good correlation between the amperometric current generated by the immunosensor and plate counts illustrated the potential usefulness of this simple system. It proved to be a reliable 24-h detection method for food samples containing very low numbers of protein A-bearing S. aureus after pre-enrichment, as it was able to detect cells that could not directly be enumerated by plate counts.
An amperometric enzyme-linked immunosensor was developed to detect and quantify levels of Staphylococcus aureus electrically in pure cultures and in foods. The assay was a modification of a 'sandwich' ELISA for the protein A of Staph. aureus, employing catalase-labelled anti-protein A antibody. On addition of hydrogen peroxide to the assay system the catalase released O2 which was monitored using an amperometric oxygen electrode. The rate of current increase was proportional to the antigen concentration (protein A or Staph. aureus). Protein A was detected reliably at 0.1 ng/ml representing a 20-fold increase in sensitivity over the conventional ELISA that used horseradish peroxidase. Pure cultures of Staph. aureus were detected at 10(-3)-10(-4) cfu/ml with the amperometric electrode (cf greater than 10(5)/ml for conventional ELISA). The same level of sensitivity was achieved for inoculated food samples. Low levels of contamination (1 cfu/g) of Staph. aureus were detected after incubation at 37 degrees C for 18 h, and the immunosensor could from the basis of a test for screening and identification of protein A-bearing Staph. aureus in 24 h, although natural variations in protein A content between different strains could make the system unreliable in accurate quantification of cell numbers.
An amperometric immunosensor specific to the protein A of Staphylococcus aureus, was developed using the direct electrochemical detection of phenol produced by alkaline phosphatase from phenylphosphate. The immunosensor could detect protein A at 0.01 ng/ml and could reliably detect and quantify pure cultures of protein A-bearing Staph. aureus above 10(3) cfu/ml. A similar sensitivity of detection was obtained with samples of beef and milk.
An amperometric electrochemical immunoassay specific for protein A-bearing Staphylococcus aureus was developed. The method was based on a sandwich immunosorbent assay and incorporated an enzyme amplification step, using a NAD-specific redox cycle generating NADH (C. H. Stanley, A. Johannsson, and C. H. Self, J. Immunol. Methods 83:89-95, 1985). Reduction of the mediator, ferricyanide, was dependent on the initial concentration of antigen. The final potential was measured by using a Pt disk electrode polarized at +0.8 V to the Ag/AgCl reference electrode. The assay was rapid (4 h) and generated protein A-and cell (S. aureus)-dependent signals. The system was highly sensitive and could detect 10 pg of protein A ml-l and <100 CFU of S. aureus ml-'. Similar sensitivities were observed with S. aureus cultures inoculated into beef and milk, but the sensitivity was reduced slightly (ca. 103 g-1) with samples of Cheddar cheese. MATERIALS AND METHODS Reagents. Human immunoglobulin G, protein A (from S. aureus Cowan strain), rabbit anti-protein A antibody, antirabbit immunoglobulin G (whole molecule) alkaline phosphatase (EC 3.1.3.1) conjugate, ,3-NAD 2'3'-cyclic mono-3278
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