Abstract

Systemic administration of mesoporous silica nanoparticles (MSNs) in biomedical applications has recently been questioned because of poor degradability, which is necessary for the successful development of new drug-delivery systems. Herein, we report the development of colloidal-state-degradable MSNs functionalized with versatile polymer-gatekeepers with a cancer-cell-targeted moiety. The polymer MSNs (PMSNs) were designed with disulfide cross-linking enabling safe encapsulation until cargos are delivered to target cancer cells. Selective targeting was achieved by decoration of CD44-receptor-targeting ligands, hyaluronic acid (HA), with HA-PMSNs. The selective cellular uptake mechanism of the fabricated targeted nanocarrier into CD44-overexpressed cancer cells was demonstrated through the clathrin- and macropinocytosis-mediated pathways. Upon internalization into cancer cells, doxorubicin loaded into the HA-PMSNs can be released by degradation of the polymer shells in the reducing intracellular microenvironment that consequentially induces cell death and further degradation of the MSNs. This study offers a simple technique to fabricate a versatile drug carrier with a high drug loading capacity.