The aim of the present study was to compare the cellular pattern and structural changes in the airway walls of atopic and nonatopic patients with asthma. Bronchial biopsy specimens were obtained from 13 atopic subjects with asthma, nine nonatopic patients with asthma, and seven healthy control subjects and investigated using immunohistochemical methods. The number of eosinophils increased in both asthma groups, but significantly more in the atopic group. The number of mast cells increased similarly in the two asthma groups, whereas the number of neutrophils increased only in the nonatopic asthma group. The number of T-lymphocytes (CD3-, CD4-, CD8-, CD-25-positive cells) was higher in patients with atopic asthma compared with nonatopic asthma. Interleukin-4 (IL-4) and IL-5-positive cells were more frequently found in the atopic asthma group, whereas cells staining for IL-8 were more frequent in the nonatopic group. The degree of epithelial damage was significantly higher in the atopic asthma group compared with the control subjects and the nonatopic asthmatics. The tenascin and laminin layer was significantly thicker in the atopic group compared with the group of nonatopic asthmatics. In the atopic group, there was a significant negative correlation between epithelial integrity (defined as the relative length of intact epithelium) and the eosinophil count and also between the number of CD25-positive cells and epithelial integrity. The number of mast cells correlated positively with the thickness of tenascin- and laminin-positive layers. In conclusion, we provide evidence of different patterns of involvement of inflammatory cells in atopic and nonatopic patients with asthma. There were also structural differences in the bronchial mucous membrane between atopic asthma and nonatopic asthma. This suggests that there are differences in the extent of the immunopathologic response of these clinically distinct forms of asthma.
Fluorescent lanthanide chelates with long decay times allow the suppression of the fast decaying autofluorescence in biological specimens. This property makes lanthanide chelates attractive as labels for fluorescence microscopy. As a consequence of the suppression of the background fluorescence the sensitivity can be increased.We modified a standard epifluorescence microscope for time-resolved fluorescence imaging by adding a pulsed light source and a chopper in the narrow aperture plane. A cooled CCD-camera was used for detection and the images were digitally processed.A fluorescent europium chelate was conjugated to antisera and to streptavidin. These conjugates were used for the localization of tumor associated antigen C242 in the malignant mucosa of human colon, for the localization of type I1 collagen mRNA in developing human cartilaginary growth plates, and for the detection of HPV type specific gene sequences in the squamous epithelium of human cer-
vix.The specific slowly decaying fluorescence of the europium label could be effectively separated from the fast decaying background fluorescence. It was possible to use the europium label at the cell and tissue level and the autofluorescence was effectively suppressed in in situ hybridization and immunohistochemical reactions in both frozen and formaldehydefixed, wax-embedded specimens. 0 1992 Wiley-Liss, Inc.
In this report, we describe luminescence imaging microscopy using five different photoluminescent dyes in a single specimen. We combined the long decay time luminophores, europium(III) chelate, terbium(III) chelate, palladium(II) coproporphyrin, and platinum(II) coproporphyrin, with a green nuclear stain, Syto 25 trade mark, that emits conventional fast decaying fluorescence. The luminescence emissions from the five different luminophores were separated from each other by the differences in spectra and decay times using time-resolved detection. Applicability of this dye-combination for multiparameter analysis of a biological object was verified in a mixed population of peripheral blood leukocytes. Leukocyte cytocentrifugates were incubated in one step with a cocktail of luminophore-conjugated antibodies recognizing neutrophil- and lymphocyte-specific markers, followed by rapid staining with a mixture of nuclear stain and Pt-porphyrin as an eosinophil stain. The results show that multiple luminescent dyes with long decay time can be used together, and in combination with a conventional fluorophore. The separation of the signals of the long decay time labels was distinctive and enabled reliable identification of different leukocyte types, as well as an automated cell count. The long decay time luminophores together with time-resolved luminescence imaging microscopy (TR-LIM) provide a unique tool for studies of simultaneous expression of multiple antigens at the level of a single cell. In comparison with other multiparameter imaging techniques, the described technique offers increased accuracy of results, simplification of preparation procedure, and dramatic shortening of the total processing time. To our knowledge, this is the first time that simultaneous fivefold labeling/staining and analysis in a single specimen has been performed in the field of immunocytochemistry.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.