The use of alcoholic beverages can cause uncontrolled release of drugs from sustained-release solid oral dosage forms and pose severe risks to patient health. The aim of this work was to design a new polymeric excipient with ethanol resistance inherent to the polymer. Polymers were systematically designed, manufactured via emulsion polymerization, and fully characterized. Glass transition temperatures between 10 and 18 °C and minimum film forming temperatures between 10 and 25 °C were chosen because these parameters are ideal for aqueous film-coating processing. Three model drug formulations were made with the new polymer excipients and tested in the presence and absence of ethanol. The concept of an alcohol resistance factor based on Weibull regression analysis was introduced. In vitro results confirmed the hypothesized structure-function relationship between comonomer composition and ethanol resistance. That is, nonionic hydrophilic functional groups interacted more strongly with the ethanolic solvent, as compared with cationic hydrophilic comonomer that interacted more strongly with the surrounding water molecules. The alcohol resistance factor varied between - 44 ± 2% (slower drug release in presence of ethanol) and + 34 ± 0% (faster drug release in presence of ethanol) depending on the comonomer ratio. The main advantages of these new excipients compared with ethanol-resistant excipient blends include ease of use, plasticizers are not necessary, and shorter coating times.
Keywords: Aqueous film coating; Ethanol resistance; New excipient; Oral dosage form; Polymer design; Sustained release.
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