Natural polymers such as chitosan and Aloe vera are widely used in novel wound dressings due to their biocompatibility and biodegradability. A problem associated with these polymers is their poor mechanical behavior. Efforts have been made to improve the mechanical properties by mixing synthetic polymers such as PVA, but the role of chitosan and Aloe vera in the final dressing is dimmed. The techniques are also time-consuming and costly and there is still a need for an acceptable and affordable wound dressing which can be made through easily accessible techniques. A new but very simple method is introduced in this work for incorporating PVA nanofibers with Aloe vera-containing chitosan films. Using this method the levels of Aloe vera and chitosan in the system can be optimized at higher scales while benefiting from PVA best mechanical properties as a composite layer. Higher amounts of Aloe vera and chitosan in the system lead to lower product costs and more biocompability. The biological properties of films were examined through cell cytotoxicity and antibacterial tests and compared with Atomic force microscopy results. Physical and mechanical properties of films containing PVA nanofibers were characterized by water vapor permeability, swelling ratio, and tensile tests. The morphology of fibers before and after applying on the films was also observed by scanning electron microscopy. According to the results, this combination of natural and synthetic polymers has led to an affordable, biocompatible, and flexible film for wound dressing applications.
Superhydrophobic silica aerogels reinforced with polyacrylonitrile fibers for adsorbing oil from water and oil mixtures
