Application of bead-based assays for flow cytometry analysis

Abstract

To date microsphere-based assays in flow cytometry have focused on the detection of antibody or antigen. Most studies have been research based to evaluate the performance of the technique relative to conventional techniques. However, there have not been any carefully controlled studies of the sensitivity and specificity, as well as analytic sensitivity of the FMIA technique. As such, it is difficult to document advantages of this tecnique clearly. The data suggest that FMIA is considerably more sensitive than conventional techniques, and the ability to analyze for multiple analytes in one sample dilution is attractive. This ability to simultaneously analyze for multiple samples is primarily dependent upon the size difference as sensed by FALS of the microspheres. However, it is also possible to use microspheres of the same size but that differ in either fluorescence or RALS signal. If microspheres of the same size are used but one fluoresces red and the signal in the assay uses a green fluorochrome, then the two microspheres can be separated by their red fluorescence. Using this technique, one can increase the number of microspheres that can be used in an assay. It is also possible to use microspheres of the same size but with different abilities to scatter the incident light at right angles. The use of these microspheres is then similar to the nonfluorescent versus red microspheres. By the judicious combination of microsphere size, it is possible to easily differentiate eight different microspheres. With the addition of a fluorescebt dye and/or differences in right-angle light-scatter capabilities, the number of different microspheres that can be used simultaneously becomes quite large. In practice, the number of microspheres that can be differentiated is no doubt greater than the number of analytes that need to be assayed in one assay. Although the apparent increase in sensitivity and the ability to simultaneously detect and quantitate numerous analytes are important attributes of FMIA, there are drawbacks to this method. Although the FMIA lends itself well to one-step no-wash procedures, when wash steps are necessary they are time-consuming and ineffecient. Most wash steps in FMIA use centrifugation of the microspheres to remove them from the reagent. There is a significant loss of microspheres in these wash steps, which are time-consuming. There are studies ussing vacuum filtration of the suspension to separate the microspheres from the reagents. A number of different groups are pursuing an automated or semiautomated method for the efficient washing and reagent delivery system for FMIA. Commercial systems are being developed that may allow for the easier handling of these reagents. Numerous groups are investigating the use of microspheres and flow cytometry primarily in immunoassay development. The procedure has the advantages of the simultaneous yet discrete analysis of multiple analytes and the inherent increase in sensitivity using fluorescence over other signals. There will no doubt be wider applications