A TA/Cu2+ Nanoparticle Enhanced Carboxymethyl Chitosan-Based Hydrogel Dressing with Antioxidant Properties and Promoting Wound Healing.

Background: As the first line of immune defense and the largest organ of body, skin is vulnerable to damage caused by surgery, burns, collisions and other factors. Wound healing in the skin is a long and complex physiological process that is influenced by a number of different factors. Proper wound care can greatly improve the speed of wound healing and reduce the generation of scars. However, traditional wound dressings (bandages, gauze, etc.) often used in clinical practice have a single function, lack of active ingredients and are limited in use. Hydrogels with three-dimensional network structure are a potential biomedical material because of their physical and chemical environment similar to extracellular matrix. In particular, hydrogel dressings with low price, good biocompatibility, degradability, antibacterial and angiogenic activity are favored by the public. Methods: Here, a carboxymethyl chitosan-based hydrogel dressing (CMCS-TA/Cu2+) reinforced by copper ion crosslinked tannic acid (TA/Cu2+) nanoparticles was developed. This study investigated the physical and chemical characteristics, cytotoxicity, and angiogenesis of TA/Cu2+ nanoparticles and CMCS-TA/Cu2+ hydrogels. Furthermore, a full-thickness skin defect wound model was employed to assess the in vivo wound healing capacity of hydrogel dressings. Results: The introduction of TA/Cu2+ nanoparticles not only could increase the mechanical properties of the hydrogel but also continuously releases copper ions to promote cell migration (the cell migration could reach 92% at 48 h) and tubule formation, remove free radicals and promote wound healing (repair rate could reach 90% at 9 days). Conclusion: Experiments have proved that CMCS-TA/Cu2+ hydrogel has good cytocompatibility, antioxidant and wound healing ability, providing an advantageous solution for skin repair.

FBP1 is highly expressed in human hypertrophic scars and increases fibroblast proliferation, apoptosis, and collagen expression.

PURPOSE: FBP1, one of the far-upstream element binding proteins(FBPs), is a distal upstream binding protein of c-myc, which is highly expressed in tumor tissues. This study aimed to investigate FBP1 expression in human hypertrophic scars and to determine the effects of FBP1 on fibroblasts. MATERIALS AND METHODS: Human normal skin and scar specimens were collected during clinical surgery. One portion of each tissue specimen was embedded in paraffin and sliced to observe differences in histological features and FBP1 expression by immunohistochemistry and western blotting. The other portion of each tissue specimen was cultured to obtain fibroblasts. Fibroblasts from the second to the sixth passage were used for the experiments, which were divided into the following two groups: an experimental group, whose cells were transfected with an siRNA targeting FBP1, and a control group, whose cells where not transfected. MTT and TUNEL assays were performed, respectively, to assess fibroblast proliferation and apoptosis, and western blotting was performed to assess protein expression. RESULTS: We obtained fibroblasts by primary tissue culture and found that FBP1 was highly expressed in hypertrophic scars. MTT assay showed that an siRNA targeting FBP1 significantly reduced fibroblast proliferation in siRNA-treated cells compared to control cells. TUNEL assay showed that there was no difference in apoptosis between the two groups; however, western blotting showed that collagen I, collagen III, c-myc, caspase-3, and caspase-9 expression levels were all decreased in the experimental group. CONCLUSION: FBP1 is highly expressed in human hypertrophic scars and increases fibroblast proliferation, apoptosis and collagen expression.