Bi-layered Nanofibers Membrane Loaded with Titanium Oxide and Tetracycline as Controlled Drug Delivery System for Wound Dressing Applications

In our present investigation, a ternary nano dressing consists of titanium dioxide nano particle loaded chitosan-pectin was prepared to evaluate biocompatibility, antimicrobial and in vivo wound healing properties. The photoactive property of TiO₂ based materials makes it important candidate for numerous medical applications. Chitosan can be easily processed into membranes, gels, nanofibers, beads, nanoparticles, scaffolds, and sponge forms that can be used in wound healing applications. Pectin acts as a natural prophylactic substance against poisoning with toxic cations and its styptic and curing effects are well documented in healing ointments. The characterizations of prepared nano dressing were made by FTIR, TGA, DSC, SEM and TEM. The physicochemical parameters of nano dressing were evaluated by various techniques, namely, the Whole blood clotting test, haemolysis ratio measurement, cytotoxicity test using NIH3T3 and L929 fibroblast cells. The in vivo open excision-type wound healing efficiency of prepared nano dressing and its comparison with conventional gauze were evaluated by measuring wound contraction and histological examinations in adult male albino rats. The synergistic effects of nano dressing such as good antibacterial ability, high swelling properties, high water vapour transmission rate (WVTR), excellent hydrophilic nature, biocompatibility, wound appearance, wound closure rate and histological study through in vivo test makes it a suitable candidate for wound healing applications.

Mimicking porous topography of natural extracellular matrix is advantageous for successful regeneration of damaged tissues or organs. Nanotechnology being one of the most promising and growing technology today shows an extremely huge potential in the field of tissue engineering. Nanofibrous structures that mimic the native extracellular matrix and promote the adhesion of various cells are being developed as tissue-engineered scaffolds for skin, bone, vasculature, heart, cornea, nervous system, and other tissues. A range of novel biocomposite materials has been developed to enhance the bioactive or therapeutic properties of these nanofibrous scaffolds via surface modifications, including the immobilization of functional cell-adhesive ligands and bioactive molecules such as drugs, enzymes, and cytokines. In skin tissue engineering, usage of allogeneic skin is avoided to reestablish physiological continuity and also to address the challenge of curing acute and chronic wounds, which remains as the area of exploration with various biomimetic approaches. Two-dimensional, three-dimensional scaffolds and stem cells are presently used as dermal regeneration templates for the treatment of full-thickness skin defects resulting from injuries and severe burns. The present review elaborates specifically on the fabrication of nanofibrous structured strategies for wound dressings, wound healing, and controlled release of growth factors for skin tissue regeneration. © 2012 by the Wound Healing Society.