Controlled free radical generation against tumor cells by pH-responsive mesoporous silica nanocomposite.

Free radicals are toxic entities known to cause cellular damage and to mediate cell death. We herein develop a controlled free radical generation strategy for cancer therapy via pH-responsive release of benzoyl peroxide (BPO) in tumor cells and producing free radicals to mediate cell death. BPO as the free radical resource was encapsulated into a chitosan (Cs)-coated mesoporous silica nanocomposite (BPO@HMSNs-Cs). The mesoporous silica carrier improved the BPO solubility by preventing its crystallization and promoted its stability by inclusion. Chitosan imparted the nanocomposite pH-responsive BPO release capacity with enhanced BPO release in simulated acidic tumor media (pH 6.5) and minor release in simulated normal tissue media (pH 7.4). The enhanced free radical generation in tumor media further led to significantly higher cytotoxicity in the tumor at acidic pH 6.5 than at physiological pH 7.4. The free radical-mediated cytotoxicity of BPO@HMSNs-Cs was verified by the observation of free radical-induced green fluorescence in cells. This pH-responsive free radical generation nanocomposite may provide new opportunities for controlled drug delivery and cancer therapy.