Imination of Microporous Chitosan Fibers-A Route to Biomaterials with On Demand Antimicrobial Activity and Biodegradation for Wound Dressings

Microporous chitosan nanofibers functionalized with different amounts of an antimicrobial agent via imine linkage were prepared by a three-step procedure including the electrospinning of a chitosan/PEO blend, PEO removal and acid condensation reaction in a heterogeneous system with 2-formylphenylboronic acid. The fibers' characterization was undertaken keeping in mind their application to wound healing. Thus, by FTIR and H-1-NMR spectroscopy, it was confirmed the successful imination of the fibers and the conversion degree of the amine groups of chitosan into imine units. The fiber morphology in terms of fiber diameter, crystallinity, inter- and intra-fiber porosity and strength of intermolecular forces was investigated using scanning electron microscopy, polarized light microscopy, water vapor sorption and thermogravimetric analysis. The swelling ability was estimated in water and phosphate buffer by calculating the mass equilibrium swelling. The fiber biodegradation was explored in five media of different pH, corresponding to different stages of wound healing and the antimicrobial activity against the opportunistic pathogens inflicting wound infection was investigated according to standard tests. The biocompatibility and bioadhesivity were studied on normal human dermal fibroblast cells by direct contact procedure. The dynamic character of the imine linkage of the functionalized fibers was monitored by UV-vis spectroscopy. The results showed that the functionalization of the chitosan microporous nanofibers with antimicrobial agents via imine linkage is a great route towards bio-absorbable wound dressings with on demand antimicrobial properties and biodegradation rate matching the healing stages.

Automated summary

Microporous chitosan nanofibers functionalized with different amounts of antimicrobial agents via imine linkage were prepared and characterized for their application in wound healing. The study investigated the fiber morphology, swelling ability, biodegradation, antimicrobial activity, biocompatibility and bioadhesivity. The results showed that the functionalized nanofibers could potentially be used as bio-absorbable wound dressings with antimicrobial properties.