Array-in-well serodiagnostic assay utilizing upconverting phosphor label technology.

In this study, a multiplex serological array-in-well assay was constructed for simultaneous detection of serum IgG antibodies against parvovirus B19 and human adenovirus. The array was prepared in streptavidin-coated 96-well microtiter plates by spotting biotinylated parvovirus B19 virus-like-particles, adenovirus type 2 and 5 hexon antigens, negative control of human serum albumin and positive controls of human IgG and anti-human IgG antibodies on the bottom of each well in an array format with a printable area of 2 mm × 2 mm. The array-in-well assay was evaluated with serum samples (n=89) of different antibody status as determined by commercial enzyme immunoassay for parvovirus IgG, and by in-house enzyme immunoassay for adenovirus IgG. The bound serum anti-parvovirus IgG, anti-adenovirus IgG, and total IgG antibodies were detected with anti-human IgG antibody coated photon upconverting nanoparticles and the assay was measured with an anti-Stokes photoluminescence imager. Detection of specific antibodies by the multiplex array-in-well assay was in good agreement (100% for parvovirus B19 and 96% for adenovirus) with the reference results. In conclusion, the array-in-well with upconverting phosphor reporter technology was able to detect antiviral antibodies in human sera, and represents an efficient serodiagnostic concept that is a promising new tool for multiplex serology.

Quantitative multianalyte microarray immunoassay utilizing upconverting phosphor technology.

A quantitative multianalyte immunoassay utilizing luminescent upconverting single-crystal nanoparticles as reporters on an antibody array-in-well platform was demonstrated. Upconverting nanoparticles are inorganic rare earth doped materials that have the unique feature of converting low energy infrared radiation into higher energy visible light. Autofluorescence, commonly limiting the sensitivity of fluorescence-based assays, can be completely eliminated with photon upconversion technology because the phenomenon does not occur in biological materials. Biotinylated antibodies for three analytes (prostate specific antigen, thyroid stimulating hormone, and luteinizing hormone) were printed in an array format onto the bottom of streptavidin-coated microtiter wells. Analyte dilutions were added to the wells, and the analytes were detected with antibody-coated upconverting nanoparticles. Binding of the upconverting nanoparticles was imaged with an anti-Stokes photoluminescence microwell imager, and the standard curves for each analyte were quantified from the selected spot areas of the images. Single analyte and reference assays were also carried out to compare with the results of the multianalyte assay. Multiplexing did not have an effect on the assay performance. This study demonstrates the feasibility of upconverting single-crystal nanoparticles for imaging-based detection of quantitative multianalyte assays.

Oligonucleotide array-in-well platform for detection and genotyping human adenoviruses by utilizing upconverting phosphor label technology.

We have developed a robust array-in-well test platform based on an oligonucleotide array, combining advantages of simple instrumentation and new upconverting phosphor reporter technology. Upconverting inorganic lanthanide phosphors have a unique property of photoluminescence emission at visible wavelengths under near-infrared excitation. No autofluorescence is produced from the sample or support material, enabling a highly sensitive assay. In this study, the assay is performed in standard 96-well microtiter plates, making the technique easily adaptable to high-throughput analysis. The oligonucleotide array-in-well assay is employed to detect a selection of ten common adenovirus genotypes causing human infections. The study provides a demonstration of the advantages and potential of the upconverting phosphor-based reporter technology in multianalyte assays and anti-Stokes photoluminescence detection with an anti-Stokes photoluminescence imaging device.

CD4+ T lymphocyte subsets express connexin 43 and establish gap junction channel communication with macrophages in vitro.

Gap junction channels constructed of connexins (Cxs) are expressed by peripheral and secondary lymphoid organ-derived lymphocytes. These channels in the plasma membrane play key roles in a range of lymphocyte functions exemplified by the synthesis and secretion of Igs and cytokines and during transmigration across the endothelium. Most recently, their involvement in antigen cross-presentation has also been established. We report here for the first time the expression of mRNA and protein encoding Cx43 in mouse-derived CD4+ Th0, Th1, and Th2 lymphocyte subpopulations and demonstrate the establishment gap junction channel formation with primary macrophages in vitro. We show that this mode of direct communication is particularly favored in Th1-macrophage interactions and that LPS inhibits lymphocyte-macrophage cross-talk independently of the subset of lymphocyte involved. Our work suggests that gap junction-mediated communication can be modulated in the absence of specific antigenic stimulation. Therefore, a further mechanism featuring gap junction-mediated communication may be implicated in immune regulation.