The ability of flow cytometry to resolve multiple parameters was used in a microsphere-based flow cytometric assay for the simultaneous determination of several cytokines in a sample. The flow cytometer microspherebased assay (FMBA) for cytokines consists of reagents and dedicated software, specifically designed for the quantitative determination of cytokines. We have made several improvements in the multiplex assay: (i) dedicated software specific for the quantitative multiplex assay that processes data automatically, (ii) a stored master calibration curve with a two-point recalibration to adjust the stored curve periodically, and (iii) an internal standard to normalize the detection step in each sample. Overall analytical performance, including sensitivity, reproducibility, and dynamic range, was investigated for interleukin-4 (IL-4), IL-6, IL-10, IL-12, gamma interferon (IFN-␥), and tumor necrosis factor alpha. These assays were found to be reproducible and accurate, with a sensitivity in the picograms-per-milliliter range. Results obtained with FMBA correlate well with commercial enzyme-linked immunosorbent assay data (r > 0.98) for all cytokines assayed. This multiplex assay was applied to the determination of cytokine profiles in whole blood from atopic and nonatopic patients. Our results show that atopic subjects' blood produces more IL-4 (P ؍ 0.003) and less IFN-␥ (P ؍ 0.04) than the blood of nonatopic subjects. However, atopic asthmatic subjects' blood produces significantly more IFN-␥ than that of atopic nonasthmatic subjects (P ؍ 0.03). The results obtained indicate that the FMBA technology constitutes a powerful system for the quantitative, simultaneous determination of secreted cytokines in immune diseases.It has been known for years that fluorescent flow cytometric detection combined with the use of sized latex microspheres allows one to perform specific and quantitative immunoassays of soluble analytes (9). The ability of the flow cytometer to discriminate between individual microspheres on the basis of size, fluorescent intensity, and/or fluorescent wavelength makes possible multianalytical assays. The use of microspheres of different sizes for multiplex assays has been described for different analytes in numerous publications (1,15,16,18,23,24). However, discrimination of microspheres by fluorescence has been documented only recently (8,14).The routine use of this attractive technology faces three distinct hurdles. First, the software commercialized with cytometers is complex and more appropriate for the qualitative cellular analysis of individual samples than for the batch mode of sampling required for the quantitative assay of several analytes. Second, reagent development faces unique analytical difficulties, such as the calibration of each individual assay in a multiplex assay and the quality of complex reagents with multiple components. Third, the concept of multiplex quantitative assays, albeit very attractive in principle, has yet to demonstrate its usefulness compared with well-acce...
