Acne is an inflammatory disease of the sebaceous glands. Melittin (Mel) is one of the principal toxic components of bee venom that can cause antibacterial and anti-inflammatory effects. Chitosan is a biodegradable polysaccharide has anti-inflammatory, antimicrobial, and regenerative properties. In this study, chitosan (Ch)/Mel 0.001 and 0.003% nanofibers were fabricated for topical treatment of acne vulgaris. Physicochemical properties of Ch/Mel were evaluated using FTIR and FESEM. Furthermore, encapsulation efficiency, tensile strength, water absorption capacity, enzymatic activity, drug release, antimicrobial, and cell cytotoxicity were assayed. Animal models were exerted to study the impact of Ch/Mel nanofibers on the treatment of Propionibacterium acnes. The FESEM results showed that nanofibers were successfully prepared in nano-scale fiber diameter. The FTIR confirmed the presence of Mel in structures. The addition of melittin to the polymer solution reduced electrical conductivity, induced viscosity and tensile strength of the fibers, and decreased the percentage of the swelling. The Mel loading into Ch/Mel 0.003% was reported at 86.74±1%. This Mel releasing process (89.65%) of Ch/Mel 0.003% was slowly completed during 72 h. The Mel retained its hemolytic activity after being loaded into the polymer structure. The drug toxicity study displayed the lack of any significant toxicity from Ch/Mel nanofibers on normal Human Dermal Fibroblasts (HDF). The Ch/Mel 0.003% achieved the highest growth inhibition in P. acnes in vitro and animal studies, this group showed the greatest reduction in inflammation and redness. The Ch/Mel 0.003% structure is proposed as a suitable topical drug delivery system for treating acne vulgaris.
Microbial biofilms are a main cause of many chronic infections and mortalities, such as dental caries, cystic fibrosis, osteoradionecrosis, urinary tract infections and native valve endocarditis. These polymeric matrices are sessile communities with different rules from those forms via known planktonic bacteria. One of the important biofilm-producing human pathogens is <em>Pseudomonas aeruginosa</em>, which causes death in the majority of people who suffer from cystic fibrosis, AIDS, burns and neutropenic cancer. To find a method for controlling the growth and resistance of <em>P. aeruginosa</em> biofilm, this study investigated the dispersion induction of this microorganism with a diffusible signal factor (DSF), <em>cis</em>-2-decenoic acid (CDA), in combination with Tobramycin as a useful antibiotic. Our findings confirmed that although CDA did not act as a dispersion inducer in this experiment, it did show an antimicrobial effect and decreased the MIC of Tobramycin. These results suggested that research on the probable new effects of DSF molecules will result in advances in the control of biofilm infections.
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