Abstract
The objective of present work is to fabricate porous three-dimensional biocomposite scaffolds with interconnected pore networks and mechanical strength for wound healing. Variable concentrations of chitosan and methylcellulose hydrogels were blended in the presence of calcium cations to prepare scaffolds by freeze-drying method. Curcumin-aerosol was deposited over the scaffold surface to improve antimicrobial efficacy. Scaffold stability and curcumin interaction were evaluated by Differential Scanning Calorimeter, Thermal Gravimetric Analyzer and Fourier Transform Infrared Spectrophotometer. Scanning Electron Microscopy indicate multi-layered porosity, mesh-like structure and pore-size ranging from 50 to 500 μm. Erythrocyte interaction with chitosan and methylcellulose using Surface Plasmon Resonance assay in the presence of curcumin depicted high binding affinity of chitosan alone than curcumin. The antibacterial activity of SCF-4C against Escherichia coli and Staphylococcus aureus and the instant haemostasis in erythrocyte-agglutination assay by SCF-7 indicate good material properties for wound treatment. Bleeding time and wound healing efficacy conducted on Sprague Dawley rats depict minimum clotting time of SCF-4 (∼32 ± 2 s) compared to SCF-4C (∼45 ± 2 s), while highest ∼85 ± 5 s was observed in curcumin alone. SCF-4C exhibit complete wound healing on day14 in diabetic animals. In-vivo studies confirmed that high concentration of chitosan in presence of curcumin enhances diabetic wound healing process.