Abstract
Overcoming severe side effects from anticancer agents without decreasing their effects on tumor growth is a major challenge. We report on a prodrug technology using agents that are spatiotemporally activated primarily in tumors while the extratumoral toxicity to healthy cells is minimized. We developed ROS-activatable prodrugs of a strong anticancer agent, doxazolidine (doxaz). Doxaz is a DNA alkylating agent with a half-life of 3 min and significantly higher cytotoxicity than the clinically used parental compound doxorubicin (dox). Importantly, doxaz is not affected by p-glycoprotein expression since it irreversibly alkylates DNA while dox inhibits the topoisomerase II DNA complex. As drug activator, we use reactive oxygen species (ROS), already produced inside cancer cells in higher abundance than in normal cells but additionally generated by external stimuli such as radionuclides (via radiolysis of water) and/or ROS-inducing drugs. We synthesized the prodrug, Doxaz-BA, and evaluated its efficacy in vitro in cell cultures and in vivo in xenograft mouse models. Doxaz-BA is effective in a broad range of cancer cells since most cancer cells produce higher levels of ROS. Combining with clinically relevant radiotracers such as (18)F-FDG or other tumor-tropic agents / ROS inducing drugs results in a tumor-specific and enhanced localized therapy paradigm.