Exposure of human skin to solar ultraviolet (UV) light induces local and systemic immune suppression. It is known that alterations of immune functions of Langerhans cells (LCs) and dermal dendritic cells (DDCs) mediate this phenomenon. The purpose of this study was to mimic in vitro the early UV-induced skin disruption to better understand the involvement of the skin micro-environment in triggering this immunosuppressive state. We therefore developed skin equivalents (SEs) integrating LCs and DDCs derived from monocytes (mo-LCs and mo-DDCs, respectively). First, we showed that Langerin(+) mo-LC and dendritic cell (DC)-specific ICAM-3 grabbing nonintegrin (SIGN)(+) mo-DDCs were immunolocalized in situ in epidermal and dermal compartments of SEs, respectively. The SE micro-environment without immune cells displayed full cytokine profile that may ensure and maintain differentiation, localization, and immaturity of LCs and DDCs in situ, as shown by secretion of granulocyte-macrophage colony-stimulating factor, transforming growth factor beta (beta)-1, interleukin (IL)-4, IL-13, and IL-15 involved in cell differentiation; presence of complete chemokine network as macrophage inflammatory protein 3 alpha (alpha); low secretion of pro-inflammatory cytokines tumor necrosis factor alpha (TNF-alpha), IL-1 beta, IL-6, and IL-8; and surprising secretion of immunosuppresive cytokine IL-10. Second, we demonstrated that skin micro-environment homeostasis was greatly disrupted under solar UV irradiation of SEs. In fact, we showed a pro-inflammatory state characterized by high secretion of TNF-alpha, IL-1 beta, IL-6, and IL-8 and low secretion of IL-10. This breakdown of immune homeostasis was visualized at the same time as in situ migration of mo-LCs and mo-DDCs into the dermal equivalent of SEs. Moreover, this tissue migration of mo-LCs and mo-DDCs into SEs was in accordance with the chemokine (C-C motif) receptor 7 expression and the DC-lysosome-associated membrane glycoprotein acquisition only on mo-LCs. Our results highlighted major participation of the skin micro-environment in the triggering and modulating of UV-induced skin immune responses. In addition, it could be concluded that these SEs are reliable tools for modeling biological events inaccessible in humans.
The introduction of a synthetic calcium phosphate into a biological environment is likely to result in surface-mediated chemical events. On the basis of such an assessment, we studied the chemical changes occurring in the mineral after exposure of a synthetic hydroxyapatite ceramic to both in vivo (implantation in human) and in vitro (cell culture) conditions. A small amount of the material was phagocytized but the major remaining part behaved as a secondary nucleator as evidenced by the appearance of a newly formed mineral. Morphologically, the newly formed mineral appeared as tiny crystals precipitated and grown from the surface of the initial synthetic crystals. The density of the additional mineral increased from the periphery to the core of each biomaterial aggregate. Chemically, it was identified by IR spectroscopy as a carbonated apatitic mineral. We propose that the adsorption of biomolecules could inhibit precipitation, accounting for the increasing amount of precipitate from the periphery to the core of the aggregates.
An in vitro method is described to assess the influence of synthetic calcium phosphate powders on osteoblast activities. Human osteoblast cell cultures were established from iliac crest. MC3T3-E1, an established osteogenic cell line, was employed as a control. Scanning and transmission electron microscopic observations clearly demonstrated the internalization of particles of calcium phosphate by the two osteoblast cell populations. As a consequence to the phagocytotic process, RNA transcription and protein synthesis were stimulated, as indicated by the measurements of labeled uridine, leucine and proline uptakes. From these data, it is proposed that such an in vitro model, using one of the specific cell types involved in the tissue responses to implants, could be useful to assess the biological response at the cell-biomaterial interaction.
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