Detection of biological threat agents by immunomagnetic microsphere-based solid phase fluorogenic- and electro-chemiluminescence.

This article reviews the recent development of two solid-phase chemiluminescence-based techniques, fluorogenic-chemiluminescence (FCL) and electro-chemiluminescence (ECL) for detection of biological threat agents. Both techniques entail a labeled sandwich immunoassay. The objectives of this work are to develop advanced techniques for sensitive and effective detection of a target analyte, particularly in cases where the analysis includes complex samples containing multiple contaminating factors. Other important considerations in developing such detection techniques include the ease of use, the rapid determination of the results, and system automation for field applications. In FCL, alkaline phosphatase is used as a label and this technique utilizes the dual features of fluorescence and visual color generated upon the presence of the fluorogenic compound, AttoPhos. The assay reaction is determined by measuring the fluorescence. In ECL, the label is a ruthenium-trisbipyridal, which is excited to a higher energy state by an electric current-driven redox reaction, and the extent of the reaction is assessed via photon emission. Both techniques depend upon the magnetic separation technique as a means to isolate the target immunological agents from the sample for analysis. This magnetic capture system allows for a reaction to occur on the electron effective-transfer zone in the ECL and also provides the reaction site for the labeled sandwich in the FCL. Comparative studies of these two techniques for detection of biological threat agents have been performed and the advantages of using magnetic microspheres versus conventional solid-phase matrices are discussed.