Development, characterization and antimicrobial activity and wound healing nanocomposite membranes xanthan: silver using porcine model

In recent years, advances in biotechnology has allowed the development of synthetic membranes associated with nanocomposites, which has shown promising results as dermal burns dressings. In this sense, silver nanoparticles (NPAg) has been the focus of interest because of their biological properties such as antimicrobial and antiinflammatory effect. The incorporation of NPAg in biological membranes of different natures, such as chitosan, polyester, polymethacrylate methyl and cellulose, has been successfully tested in several biological models. The association between NPAg and polymers produced by the micro-organism presents important advantages, such as water solubility and lack of toxicity. Recently we developed a technique for producing NPAg associated with xanthan (GX), a biopolymer with potential application in various sectors of the petrochemical industry, food and pharmaceutical, through fermentation by Xanthomonas sp performed in the presence of silver nitrate. Therefore, this study aimed to develop, characterize and evaluate the potential antimicrobial and healing membranes nanocomposite xanthan: silver on second-degree burns in the porcine model. Therefore, xanthan biocomposites: silver were used for fabrication of membranes (for casting process, which were subsequently characterized for thickness, mechanical properties (stress, strain, Young´s modulus) and the thermal profile (DSC, TG and DTG). Activity antimicrobial was tested against strains of Escherichia coli (ATCC 25922) and Staphylococcus aureus (ATCC 25923). analysis for tissue repair were made two dermal burns on the back nine male pigs breed Yorkshire (25 ± 5 kg), treated with Xanthan biosensor membrane: silver (XNPAg) with topical application of silver sulfadiazine 1% (SDZ). After eight, 18 and 30 days the wounds were examined macroscopically determined for each lesion area, and the animals euthanized for Microscopic study of the scar area observed that XNPAg membranes showed a significant increase in the values of thickness (P