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Design of a nanostructured mucoadhesive system containing curcumin for buccal application: from physicochemical to biological aspects.

Sabrina Barbosa de Souza FerreiraGustavo BragaÉvelin Lemos OliveiraJéssica Bassi da SilvaHélen Cássia RossetoLidiane Vizioli de Castro-HoshinoMauro Luciano BaessoWilker CaetanoCraig MurdochHelen Elizabeth ColleyMarcos Luciano Bruschi
Published in: Beilstein journal of nanotechnology (2019)
Mucoadhesive nanostructured systems comprising poloxamer 407 and Carbopol 974P® have already demonstrated good mucoadhesion, as well as improved mechanical and rheological properties. Curcumin displays excellent biological activity, mainly in oral squamous cancer; however, its physicochemical characteristics hinder its application. Therefore, the aim of this study was to develop nanostructured formulations containing curcumin for oral cancer therapy. The photophysical interactions between curcumin and the formulations were elucidated by incorporation kinetics and location studies. They revealed that the drug was quickly incorporated and located in the hydrophobic portion of nanometer-sized polymeric micelles. Moreover, the systems displayed plastic behavior with rheopexy characteristics at 37 °C, viscoelastic properties and a gelation temperature of 36 °C, which ensures increased retention after application in the oral cavity. The mucoadhesion results confirmed the previous findings with the nanostructured systems showing a residence time of 20 min in porcine oral mucosa under flow system conditions. Curcumin was released after 8 h and could permeate through the porcine oral mucosa. Cytotoxicity testing revealed that the formulations were selective to cancer cells over healthy cells. Therefore, these systems could improve the physicochemical characteristics of curcumin by providing improved release and permeation, while selectivity targeting cancer cells.
Keyphrases
  • cancer therapy
  • drug delivery
  • induced apoptosis
  • single cell
  • oxidative stress
  • squamous cell carcinoma
  • young adults
  • endoplasmic reticulum stress
  • low grade
  • cell cycle arrest