ARTICLE ABSTRACT
Small-molecule inhibitors have had a major impact on cancer care. While treatments have demonstrated clinically promising results, they suffer from dose-limiting toxicities and the emergence of refractory disease. Considerable efforts made to address these issues have more recently focused on strategies implementing particle-based probes that improve drug delivery and accumulation at target sites, while reducing off-target effects.
Ultrasmall (<8 nm) core-shell silica nanoparticles, C′ dots, were molecularly engineered to function as multivalent drug delivery vehicles for significantly improving key in vivo biological and therapeutic properties of a prototype epidermal growth factor receptor (EGFR) tyrosine kinase inhibitor, gefitinib. Novel surface chemical components were used to conjugate gefitinib–dipeptide drug-linkers and deferoxamine (DFO) chelators for therapeutic delivery and PET imaging labels, respectively.
Gefitinib-bound C′ dots (DFO-Gef-C′ dots), synthesized using the gefitinib analogue, APdMG, at a range of drug-to-particle ratios (DPR; DPR = 11–56), demonstrated high stability for DPR values≤ 40, bulk renal clearance, and enhanced in vitro cytotoxicity relative to gefitinib (LD50 = 6.21 nmol/L vs. 3 μmol/L, respectively). In human non–small cell lung cancer mice, efficacious Gef-C′ dot doses were at least 200-fold lower than that needed for gefitinib (360 nmoles vs. 78 μmoles, respectively), noting fairly equivalent tumor growth inhibition and prolonged survival. Gef-C′ dot–treated tumors also exhibited low phosphorylated EFGR levels, with no appreciable wild-type EGFR target inhibition, unlike free drug.
Results underscore the clinical potential of DFO-Gef-C′ dots to effectively manage disease and minimize off-target effects at a fraction of the native drug dose.
