Increasing the aqueous solubility of the anesthetic propofol through wormlike micelle formation

Propofol, a phenol derivative, is commonly employed as an intravenous anesthetic during clinical procedures, formulated as an oil/water emulsion due to its poor solubility in water. The stability limitations associated with emulsions have prompted research efforts towards developing aqueous formulat...

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Published in:Colloids and surfaces, B, Biointerfaces B, Biointerfaces, 2023-12, Vol.232, p.113592-113592, Article 113592
Main Authors: Okasaki, Fernando B., Duarte, Luís G.T.A., Sabadini, Edvaldo
Format: Article
Language:English
Subjects:
aggregates of propofol
emulsions
fluorescence
incorporation into the micellar core and palisade
intravenous injection
micelles
oils
phenol
propofol
propofol as fluorescent probe
rheology
solubility
surfactants
viscoelasticity
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Summary:Propofol, a phenol derivative, is commonly employed as an intravenous anesthetic during clinical procedures, formulated as an oil/water emulsion due to its poor solubility in water. The stability limitations associated with emulsions have prompted research efforts towards developing aqueous formulations of propofol. In this work, we investigate the solubility enhancement of propofol in anionic and cationic surfactants. Our findings reveal that the solubility of propofol can increase significantly, up to 100-fold, depending on the nature of the micellar aggregate, as observed for alkylammonium halogenates CnTAB (for n = 12, 14 and 16), contrasting with the lower solubility with SDS. Interestingly, C14TAB and C16TAB demonstrate significantly higher solubility than C12TAB. This was attributed to the formation of wormlike micelles, in which the propofol molecules are positioned between the cationic heads of the surfactant molecules, changing the micellar curvature and the morphology of the aggregate. Therefore, the aromatic molecules in the micellar environment can be partitioned into the micellar cores and their palisades. Regarding C12TAB, the alkyl chain is too short to form wormlike micelles, thus, concentrating propofol molecules mainly into the micellar core, and consequently, leading to their aggregation. Solubility diagrams of propofol were constructed in conjunction with different surfactants. The systems exhibiting viscoelastic behavior, indicative of wormlike micelle formation, were further investigated using rheology. Additionally, the fluorescent properties of propofol enabled the examination of the anesthetic molecule within diverse micellar environments. [Display omitted] •The anesthetic Propofol forms wormlike micelles with cationic surfactants.•Propofol is distinctly partitioned within different micellar morphologies.•WLM formation relates to higher solubilization of the anesthetic.•WLM are thermodynamically stable, allowing a new proposal for aqueous formulations of Propofol.
ISSN:0927-7765
1873-4367
DOI:10.1016/j.colsurfb.2023.113592