This study was performed to design a method for the culture of rat middle-ear epithelium and to apply the method to investigate the characteristics of this epithelium. Culture of explants of middle-ear epithelium in the presence of the epidermal growth factor was successful, whereas serial cultivation required 3T3 feeder cells in addition to the epidermal growth factor. Cultured middle-ear epithelium was studied by phase-contrast microscopy, transmission and scanning electron microscopy, and combined light and scanning electron microscopy (LM/SEM). These techniques showed similarity between the cultured and the natural middle-ear epithelium. Explants and outgrowths showed both flat polygonal and ciliated epithelial cells.In serial cultivation, however, only the first of these cell types was observed. Frequently, a single primary cilium was found on the cell surface. Transmission electron microscopy showed cross-linked envelopes whose formation was promoted by ionophore X537A. Cytokeratin was demonstrated by immunoblotting, immunofluorescence, and immunoperoxidase methods, using an anti-cytokeratin monoclonal antibody. The model described here permits study of the differentiation of middle-ear epithelium in vitro and may be of future value for the study of chronic middle-ear diseases.
We present a study on modification of culture conditions in serially cultured human bronchial epithelial cells (HBEC), necessary to achieve bronchial epithelial cells similar to the native epithelium. Cells were obtained from bronchial biopsies and serially cultured using a previously described method (In Vitro Cell. Dev. Biol. 1993; 29A:379-387). At the air-liquid interface, the second and the subsequent passages of HBEC cultures were grown 7 to 31 days, in medium containing fetal calf serum, using de-epidermized dermis or collagen discs as substratum. Scanning and transmission electron microscopy revealed ciliogenesis after 7 days and maturation of the cilia up to 31 days, irrespective of whether de-epidermized dermis or collagen membrane was used. The transmission electron microscopy of the developing cilia showed fibrogranular masses, procentrioles, basal bodies, and in the mature cilia a normal ultrastructure of the axoneme, the nine doublets, the central pair, radial spokes, and dynein arms in the ciliary shaft. In contrast, the submerged cultures showed no signs of ciliogenesis in the same time course. Results of experiments, in which cell seeding density, the substrate used, and the manner of nutrient supplementation were modulated, revealed that the air-exposure of the cultured HBEC is a necessary requirement for the ciliogenesis. The development pathway of ciliated cells in air-exposed HBEC cultures was similar to the differentiation and maturation pattern in human fetal tracheal cells. The in vitro model of human bronchial epithelial cells derived from biopsies obtained by fiberoptic bronchoscopy offers an attractive model for future studies on the function of human bronchial epithelial cells under normal and pathologic conditions.
In this study, the mode of action of moisturizers on the level of water in the stratum corneum was studied using cryo-scanning electron microscopy. As model for dry skin, we used human skin equivalents (HSEs) generated at 93% or 60% relative humidity (RH). During the generation of the HSEs, the moisturizers were applied during a period of maximal 2 weeks. In HSEs generated under normal culture conditions (93% RH), application of 10% glycerol or 5% urea formulations resulted in increased water levels. Whereas the 5% urea formulations resulted mainly in the formation of intercellular water domains, after 10% glycerol both swelling of corneocytes and formation of intercellular water domains were noticed. A reduction in RH to 60% during treatment reduced the stratum corneum water levels drastically. Treatment with the non-occlusive lipophilic moisturizer isopropyl isostearate resulted in increased water level in the central part of the stratum corneum compared with the untreated control. Our results show that HSEs can be used as a model to study the water distribution.
