Docetaxel (DTX) remains the first-line chemotherapeutic for advanced prostate cancer, however, its therapeutic efficacy remains limited by poor aqueous solubility, rapid systemic clearance, and severe dose-dependent toxicity. To overcome these constraints, we developed a PEGylated, disulfide-bridged hierarchical mesoporous silica nanocarrier (PEG-HMS) as a redox-sensitive delivery system for DTX (PEG-HMS-DTX). The nanostructure was fabricated by integrating disulfide-containing organosilanes into the silica framework and conjugating thiol-reactive PEG chains, thereby combining long circulation stability with tumor-selective release. Comprehensive physicochemical characterization confirmed uniform spherical morphology, an optimal hydrodynamic size (∼40-50 nm), attenuated surface charge following PEGylation, and high colloidal stability in physiological media, while disulfide linkages enabled responsive structural changes under reductive conditions. Drug release was minimal under physiological conditions (70%), minimal systemic toxicity, and elevated apoptosis characterized by increased cleaved caspase-3 and reduced PCNA/Bcl-2 expression. Collectively, this "stable-in-circulation, trigger-in-tumor" platform substantially improves intratumoral DTX delivery and apoptosis-driven antitumor efficacy, while maintaining systemic safety. These findings highlight PEG-HMS-DTX as a promising and generalizable strategy for prostate cancer chemotherapy, warranting further pharmacokinetic, immunogenicity, and GLP toxicology studies to support translational advancement.
Song et al. (Tue,) studied this question.