RESUMO
Transdermal patches for analgesic purposes are widely used, however, their occlusive characteristics can often cause allergic reactions, irritating contact dermatitis, and allergic contact dermatitis upon extended use. Chitosan is a natural positively charged bioadhesive polysaccharide with several biological properties, being promising templates for sustained and controlled topical or transdermal drug delivery. Methyl salicylate (MS) is a non-steroidal topical anti-inflammatory drug (NSAID). MS is a lipophilic oily drug commonly found in transdermal patches, being difficult to incorporate into hydrophilic formulations such as Chitosan-based films. Thus, MS is a good candidate to be encapsulated into nanoemulsions (NE). This work reports the formulation development, physical-chemical characterization, and in vitro drug release of NE-loaded Chitosan films formulated with MS, as a novel substitute for transdermal analgesic patches. MS was encapsulated into NE, which were prepared by ultrasonication and presented 29.3 nm ± 0.1 and PdI 0.167 ± 0.005. The incorporation of MS into NE prevented phase separation and provided a homogeneous physical blending formulation, as confirmed by FTIR, TGA. NE-loaded films provided high drug incorporation in the films 94.08% ± 6.63%), and a smaller crystallinity degree in comparison with physical mixture films, suggesting a plasticizing effect of nano-sized droplets. Besides, mean weight, thickness, and moisture content were increased in NE-loaded films in comparison with chitosan-based control films. In vitro drug release from NE-loaded films was significantly higher than for physical mixture films, following Weibull and Korsmeyer-Peppas release kinetics models. The results suggest that NE-loaded chitosan film can increase the drug loading capacity of oil drugs and successfully control in vitro release, constituting a novel approach for transdermal drug delivery of NSAIDs.