Acetate ions enhance load and stability of doxorubicin onto PEGylated nanodiamond for selective tumor intracellular controlled release and therapy

Abstract

A successful drug delivery device for cancer chemotherapy should ideally be able to load drugs highly, bring the drug preferentially into tumor cells and reduce its distribution in normal tissue to enhance therapeutic efficacy. To this purpose, a novel protocol for DOX-loaded PEGylated nanodiamond (ND-PEG–DOX/NaAc, NPDA) was fabricated using sodium acetate medium. The NPDA nanoparticles exhibited a maximum loading efficiency (99 wt%) with ultra-low drug leakage (7 wt%). Examination by confocal microscope and flow cytometer showed that the NPDA uptake by cells was time-dependent, with a slow and sustained drug release from the lysosomes at a low pH. Also, when CHO (a normal cell) and MCF-7 (a cancer cell) were treated with NPDA, the results demonstrated that NPDA preferentially accumulated much more in tumor cells than in normal cells, which implied that NPDA has the ability to selectively kill tumor cells. In addition, NPDA can inhibit the migration and proliferation of tumor cells and change the cell cycle compared to the free drug. Outcomes from this work suggest that NPDA would be a promising drug delivery platform and the preparation of such a drug delivery system will also have implications in improving the biomedical applications of smart nanodiamond carriers.