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The matricellular protein decorin delivered intradermally with coacervate improves wound resolution in the CXCR3‐deficient mouse model of hypertrophic scarring.
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- Additional Information
- Abstract:
Cutaneous wound healing is an intricate orchestration of three overlapping phases of repair that encompass numerous cell types, signalling cascades, and microenvironment modifications to reach a successful resolution. Disruption of any of these steps will create an abnormal healing response resulting in either ulceration or excessive scarring. It has become evident that the extracellular matrix and its associated components are key orchestrators during this process. One of these essential matrix proteins is decorin, a small leucine‐rich proteoglycan (SLRP) that acts as a regulator of collagen fibrillogenesis and a non‐competitive inhibitor of multiple growth factors signalling cascades. Decorin is a necessary shut‐off switch for the pro‐reparative mechanism of the tissue replacement phase and limits the occurrence of hypertrophic scarring by preventing excessive repair. We investigated the use of decorin as a therapeutic by administering the matrix protein anchored in a slow‐release coacervate in a hypertrophic scarring mouse model. The results show that early wound healing phase measurements exhibit little difference in performance compared to our coacervate‐only baseline or HB‐EGF‐treated control mice. However, during the resolution phase of wound healing, the decorin‐treatment significantly reduces cutaneous thickness, enhances collagen alignment, and improves overall wound scoring in the mice. Thus, mice treated with decorin display better healing outcomes and could limit the hypertrophic scarring phenotype in the coacervate only, and HB‐EGF controls. These results suggest that decorin may be a promising tool and alternative therapy for patients who suffer from over‐exuberant matrix deposition during wound healing. [ABSTRACT FROM AUTHOR]
- Abstract:
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