Selective intracellular free radical generation against cancer cells by bioactivation of low-dose artesunate with a functionalized mesoporous silica nanosystem

Abstract

Excessive free radicals are noxious for living organisms and lead to cell death. Destruction of malignant cells by reactive free radicals has been widely used in cancer treatment. A key consideration is how to allow targeted free radical attack on cancer cells and avoid unwanted side-effects. Herein, we develop an efficient intracellular free radical generation strategy against cancer cells by delivering active ingredients into cancer cells, where free radicals are selectively generated by a lysosomal bioactivation process. Artesunate (ART), which is non-toxic to normal cells, was chosen as the free radical source and transported into cells with a hollow mesoporous silica-based delivery system (ART@HMS). To selectively activate the ART@HMS inside cancer cells, a high-bioactive Fe/O cluster-mesoporous silica nanosystem (Fe/O-MSN) was elaborately prepared. Under the bioactivation of the lysosome, the low-dose ART@HMS together with biocompatible Fe/O-MSN induced significant intracellular generation of toxic free radicals and efficient death of cancer cells. This selective intracellular free radical generation strategy is encouraging for its development into an effective low-cost cancer therapy.