Magnetic hybrid micelles with controllable structures via interfacial instability-induced confined Co-assembly

Abstract

Co-assembly of amphiphilic block copolymers (BCPs) and nanoparticles (NPs) is an encouraging route to produce shape-tunable functional hybrid micelles, which can integrate the excellent water stability of BCPs and the versatile functionalities of NPs. In this paper, we present an facile method to prepare magnetic hybrid micelles through confined co-assembly of polystyrene grafted Fe3O4@PS NPs and PS-b-poly(ethylene oxide) (PS-b-PEO) induced by interfacial instability of emulsion droplets. The morphology of hybrid micelles can be regulated by varying the surfactant concentration, weight fraction of Fe3O4 NPs, and block ratio of PS-b-PEO. The distribution of NPs inside the micelles is determined by the ratio (d/L) of the NP diameter (d) to the thickness of PS domain of the micelles (L). When 0.49 ≤ d/L < 0.76, the NPs locate within the cylindrical micelles. When d/L ≥ 0.76, the NPs selectively locate in the spherical micelles. More interestingly, the size-selective loading of NPs in the micelles can be achieved, even mixture of NPs different in size is applied. Moreover, these magnetic hybrid micelles show good biocompatibility and morphology-dependent magnetic resonance responsiveness, which may find potential applications in magnetic resonance imaging.