Abstract
Despite decades of research, the goal of achieving scarless wound healing remains elusive. One of the approaches, treatment with polymeric microcarriers, was shown to promote tissue regeneration in various in vitro models of wound healing. The in vivo effects of such an approach are attributed to transferred cells with polymeric microparticles functioning merely as inert scaffolds. We aimed to establish a bioactive biopolymer carrier that would promote would healing and inhibit scar formation in the murine model of deep skin wounds. Here we characterize two candidate types of microparticles based on fibroin/gelatin or spidroin and show that both types increase re-epithelialization rate and inhibit scar formation during skin wound healing. Interestingly, the effects of these microparticles on inflammatory gene expression and cytokine production by macrophages, fibroblasts, and keratinocytes are distinct. Both types of microparticles, as well as their soluble derivatives, fibroin and spidroin, significantly reduced the expression of profibrotic factors Fgf2 and Ctgf in mouse embryonic fibroblasts. However, only fibroin/gelatin microparticles induced transient inflammatory gene expression and cytokine production leading to an influx of inflammatory Ly6C+ myeloid cells to the injection site. The ability of microparticle carriers of equal proregenerative potential to induce inflammatory response may allow their subsequent adaptation to treatment of wounds with different bioburden and fibrotic content.
Highlights
Skin wound healing is a complex process that involves initial coagulation and rapid myeloid cells infiltration resulting in inflammatory response followed by proliferative and reepithelialization phases [1]
In accordance with our in vitro data, we observed a significant increase in the percentage of highly inflammatory Ly6Chi myeloid cells following the injection of fibroin/gelatin MPs as compared to spidroin MPs and the control group (Figures 4A,C)
Gelatin modification, used in this work to increase biocompatibility of fibroin scaffolds, could further modulate MPs influence on cultured cells, in previous studies we did not observe any effect of gelatin-modified fibroin scaffolds on gene expression in mouse embryonic fibroblasts (MEF) [45]
Summary
Skin wound healing is a complex process that involves initial coagulation and rapid myeloid cells infiltration resulting in inflammatory response followed by proliferative and reepithelialization phases [1]. The balance between these processes determines the dynamics of regeneration, as well as the outcome of wound healing, in particular, fibrosis, scar formation, and efficient restoration of skin appendages [2]. Since STAT3 activation was shown to be crucial for wound healing [15, 16], a possibility of other IL-6 family cytokines involvement in the skin regeneration process should be considered
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