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Pluronic ® F127 Hydrogel Containing Silver Nanoparticles in Skin Burn Regeneration: An Experimental Approach from Fundamental to Translational Research.

Pedro FranciscoMariana Neves AmaralAfonso NevesTânia Ferreira-GonçalvesAna Silveira VianaJosé CatarinoPedro FaíscaSandra SimõesJoão PerdigãoAdília J CharmierMaria Manuela GasparCatarina Pinto Reis
Published in: Gels (Basel, Switzerland) (2023)
Presently, skin burns are considered one of the main public health problems and lack therapeutic options. In recent years, silver nanoparticles (AgNPs) have been widely studied, playing an increasingly important role in wound healing due to their antibacterial activity. This work is focused on the production and characterization of AgNPs loaded in a Pluronic ® F127 hydrogel, as well as assessing its antimicrobial and wound-healing potential. Pluronic ® F127 has been extensively explored for therapeutic applications mainly due to its appealing properties. The developed AgNPs had an average size of 48.04 ± 14.87 nm (when prepared by method C) and a negative surface charge. Macroscopically, the AgNPs solution presented a translucent yellow coloration with a characteristic absorption peak at 407 nm. Microscopically, the AgNPs presented a multiform morphology with small sizes (~50 nm). Skin permeation studies revealed that no AgNPs permeated the skin after 24 h. AgNPs further demonstrated antimicrobial activity against different bacterial species predominant in burns. A chemical burn model was developed to perform preliminary in vivo assays and the results showed that the performance of the developed AgNPs loaded in hydrogel, with smaller silver dose, was comparable with a commercial silver cream using higher doses. In conclusion, hydrogel-loaded AgNPs is potentially an important resource in the treatment of skin burns due to their proven efficacy by topical administration.
Keyphrases
  • silver nanoparticles
  • wound healing
  • public health
  • photodynamic therapy
  • drug delivery
  • multidrug resistant
  • stem cells
  • staphylococcus aureus
  • high throughput
  • human health
  • climate change
  • tissue engineering