Fabrication of pH and thermal dual-responsive hyperbranched copolymer grafted magnetic graphene oxide via surface-initiated RAFT-SCVP for controlled release of DOX

Abstract

Herein, a novel stimuli-responsive magnetic graphene oxide/hyperbranched copolymer nanocomposites (GO@Fe3O4 @HBC) was prepared via mixing surface-initiated RAFT and self-condensing vinyl polymerization technique. In the first step, chain transfer monomer (CTM) was synthesized by the esterification reaction between 2-(dodecylthiocarbonothioylthio)− 2-methylpropionic acid (DDMAT) and 2-Hydroxyethyl methacrylate (HEMA). Besides, graphene oxide nanosheets were decorated with Fe3O4 nanoparticles. The surface of magnetic graphene oxide nanosheets was modified with 3-amino propyl (trimethoxysilyl) (APTS) and then the DDMAT was anchored to the surface of their nanosheets via amidification reaction. At last, smart hyperbranched poly (NIPAM-co-AA) was effectively grafted to the surface of magnetic graphene oxide using the SI-RAFT-SCVP technique. The chemical and physical structure of the synthesized GO@Fe3O4 @HBC were investigated by FT-IR, H NMR, GPC, TGA, DLS, CHN, VSM, UV-Vis, SEM, EDAX, and TEM. The synthesized GO@Fe3O4 @HBC was used as a nanocarrier. The drug delivery efficacy of this nanocarrier was investigated in terms of in vitro doxorubicin (DOX) release and MTT assay against HeLa cells, which confirms both acidic pH and thermo-sensitive behavior. The MTT assay also revealed that the nanocarrier without DOX was biocompatible having cell viability greater than 90% for HeLa cells. DOX-loaded nanocarrier showed high cytotoxic effect on HeLa Cells.