The interaction of a model active pharmaceutical with cationic surfactant and the subsequent design of drug based ionic liquid surfactants

[Display omitted] Interactions of active pharmaceutical ingredients (API) with surfactants remain an important research area due to the need to improve drug delivery systems. In this study, UV–Visible spectrophotometry was used to investigate the interactions between a model low molecular weight hyd...

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Bibliographic Details
Published in:Journal of colloid and interface science 2016-11, Vol.481, p.117-124
Main Authors: Qamar, Sara, Brown, Paul, Ferguson, Steven, Khan, Rafaqat Ali, Ismail, Bushra, Khan, Abdur Rahman, Sayed, Murtaza, Khan, Asad Muhammad
Format: Article
Language:English
Subjects:
Cations - chemistry
Cetrimonium Compounds - chemistry
Drug delivery
Drug Design
Encapsulation
Hydrophilic drugs
Ionic liquid
Ionic Liquids - chemistry
Ionic surfactant
Micelles
Models, Chemical
Quantum Theory
Surface-Active Agents - chemistry
UV–Vis spectroscopy
Valproic Acid - chemistry
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Summary:[Display omitted] Interactions of active pharmaceutical ingredients (API) with surfactants remain an important research area due to the need to improve drug delivery systems. In this study, UV–Visible spectrophotometry was used to investigate the interactions between a model low molecular weight hydrophilic drug sodium valproate (SV) and cationic surfactant cetyltrimethylammonium bromide (CTAB). Changes in the spectra of SV were observed in pre- and post-micellar concentrations of CTAB. The binding constant (Kb) values and the number of drug molecules encapsulated per micelle were calculated, which posed the possibility of mixed micelle formation and strong complexation between SV and CTAB. These results were compared to those of a novel room temperature surface active ionic liquid, which was synthesized by the removal of inorganic counterions from a 1:1 mixture of CTAB and SV. In this new compound the drug now constitutes a building block of the carrier and, as such, has considerably different surfactant properties to its building blocks. In addition, enhanced solubility in a range of solvents, including simulated gastric fluid, was observed. The study provides valuable experimental evidence concerning the performance of drug based surfactant ionic liquids and how their chemical manipulation, without altering the architecture of the API, leads to control of surfactant behavior and physicochemical properties. In turn, this should feed through to improved and controlled drug release rates and delivery mechanisms, and the prevention of precipitation or formation of polymorphs typical of crystalline form APIs.
ISSN:0021-9797
1095-7103
DOI:10.1016/j.jcis.2016.07.054