Treatment of Malignant Brain Tumor by Tumor‐Triggered Programmed Wormlike Micelles with Precise Targeting and Deep Penetration

The efficient and specific drug delivery to brain tumor is a crucial challenge for successful systemic chemotherapy. To overcome these limitations, here a tumor‐triggered programmed wormlike micelle is reported with precise targeting and deep penetration to treat malignant gliomas, which is composed of pH‐responsive mPEG‐ b ‐PDPA copolymer and bioreducible cyclic RGD peptide targeted cytotoxic emtansine (DM1) conjugates (RGD‐DM1). The RGD‐DM1 loaded nanoscaled wormlike micelles (RNW) exhibit nanometer‐sized wormlike assemblies with the transverse diameter of 21.3±1.8 nm and length within 60–600 nm, and the RGD targeting peptide in RNW is 4.2% in weight. RNW can be dissociated at intracellular acidic environments to release RGD‐DM1, and be further degraded into DM1 by cleavage of disulfide bonds in the reductive milieu. In particular, by exploiting the unique wormlike structure and the RGD targeting peptide modification, RNW can be endowed with obviously enhanced drug delivery to brain, precise targeting to brain tumor, deep penetration into tumor mass, and efficient internalization into glioma cells in a programmed manner, thereby surprisingly leading to an 88.9% inhibition on tumor progression in an orthotopic brain tumor model. Therefore, the properly designed RNW can provide a promising delivery platform for systemic chemotherapy of brain tumor.