Sol-moiety: Discovery of a water-soluble prodrug technology for enhanced oral bioavailability of insoluble therapeutics
Arvin Karbasi, Jaden D. Barfuss, T Morgan, Daniel Collins, Drew A Costenbader, David G. Dennis, A. Scott Hinman, KyuWeon Ko, Cynthia Messina, Khanh Cong Nguyen, Rebecca C. Schugar, Karin A. Stein, Brianna B. Williams, Haixia Xu, Justin P. Annes, Mark Smith
Abstract
Though conceptually attractive, the use of water-soluble prodrug technology to enhance oral bioavailability of highly insoluble small molecule therapeutics has not been widely adopted. In large part, this is due to the rapid enzymatic or chemical hydrolysis of prodrugs within the gastrointestinal tract, resulting in drug precipitation and no overall improvement in oral bioavailability relative to standard formulation strategies. We reasoned that an optimal water-soluble prodrug could be attained if the rate of prodrug hydrolysis were reduced to favor drug absorption rather than drug precipitation. In doing so, the rate of hydrolysis provides a pharmacokinetic control point for drug delivery. Herein, we report the discovery of a water-soluble promoiety (Sol-moiety) technology to optimize the oral bioavailability of highly insoluble small molecule therapeutics, possessing various functional groups, without the need for sophisticated, often toxic, lipid or organic solvent-based formulations. The power of the technology is demonstrated with marked pharmacokinetic improvement of the commercial drugs enzalutamide, vemurafenib, and paclitaxel. This led to a successful efficacy study of a water-soluble orally administered prodrug of paclitaxel in a mouse pancreatic tumor model. Current water-soluble prodrug technologies typically result in a lack of overall improvement in oral bioavailability relative to standard formulation strategies. Here, the authors report water soluble promoiety (Sol-moiety) technology that shows improved oral bioavailability over existing water-soluble prodrug technologies and the ability to switch from intravenous to oral administration.