The multidrug-resistant Pseudomonas aeruginosa is considered a public threat, with antibiotics increasing its resistance. Essential oils (EOs) have demonstrated significant effects against several microorganisms. However, due to their volatile nature they cannot be delivered to the bacteria infected site in their free-state. Therefore, biodegradable polymeric delivery platforms are being engineered. Here, hydrogel-like films were produced from a combination of sodium alginate (SA) and gelatin (GN) to serve as delivery platforms for the controlled release of cinnamon leaf oil (CLO) entrapped within chitosan microcapsules. The minimum inhibitory concentration (MIC) of CLO was established at 39.3 mg/mL against P. aeruginosa. Chitosan microcapsules were prepared via ionotropic gelation with tripolyphosphate, containing at the core the CLO at MIC. Successful production was confirmed by fluorescent microscopy using Nile red as detection agent. The encapsulation efficiency and controlled release of the oil were monitored in basic and physiological pH for 24 h. Microcapsules were then embedded within a biodegradable SA/GN polymeric matrix processed via a solvent casting/phase inversion methodology with SA/GN used at 70/30 polymer ratio and 2 wt% SA concentration in distilled water. The coagulation bath was composed of a 2 wt% CaCl2 aqueous solution. The CLO-containing chitosan microcapsules homogeneous distribution was guaranteed by successive vortex and blending processes applied prior to casting. Flexible, highly hydrated films were obtained, with the presence of loaded chitosan capsules being confirmed by FTIR. Qualitative and quantitative antimicrobial examinations validated the modified film potential to fight infections caused by P. aeruginosa bacteria.
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Irradication of Pseudomans aeruginosa via sodium alginate/gelatin films impregnated with chitosan microcapsules loaded with cinnamon leaf oil
Published:
05 November 2020
by MDPI
in 6th International Electronic Conference on Medicinal Chemistry
session Round Table on Natural Products
Abstract:
Keywords: bactericidal effects. bio-based polymers, drug delivery platform, natural extracts, trigger-based release