AI Article Synopsis
- A new prodrug strategy has been developed for delivering water-insoluble camptothecins using liposomes, which are tiny drug-delivery vehicles.
- The prodrug is formed by modifying a camptothecin analogue into an ester that includes an aminoalkanoanic group, enhancing its solubility and enabling better loading into the liposome at acidic pH levels.
- Once at a tumor site, the prodrug activates and decomposes to release the active drug due to pH changes, making the approach promising for targeting various camptothecin drugs effectively.
Article Abstract
We describe a versatile prodrug strategy for loading the liposomal lumen with water-insoluble camptothecins. The procedure involves conversion of an active camptothecin analogue to a 20-OR omega-aminoalkanoanic ester prodrug in which R = CO[CH(2)](n)()NH(2) and n = 1-3. The basic amino group of the prodrug serves three roles. First, at pH ranges of 3-5, the amine enhances aqueous solubility. Second, it enhances responsiveness to a transmembrane ammonium sulfate gradient across the liposomal bilayer, thereby facilitating active loading of the agent into the liposomal aqueous core. Third, at a physiological pH of 7 or above (the pH to be encountered following drug release at the tumor site), the nucleophilicity of the amine manifests itself and cyclization to the C-21 carbonyl carbon occurs. This cyclization triggers a rapid and convenient nonenzymatic decomposition process that releases active camptothecin. Accordingly, this novel liposomal approach offers a potential system for tumor-targeting prodrugs of many water-insoluble camptothecins, including the highly lipophilic and clinically attractive analogues SN-38, 9-nitrocamptothecin and DB-67. The rate of formation of the active agent at the tumor site can be controlled through the selection of n (the length of the alkyl spacer group).
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| http://dx.doi.org/10.1021/ja0256212 | DOI Listing |
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