Magnetic Helical Hydrogel Motor for Directing T Cell Chemotaxis

Micro/nanomotors are attracting booming research enthusiasm with their revolutionary potential in biomedicine, sensing, and nanoengineering. Among the motors proposed, magnetic micro/nanomotors are of great interest with their high controllability and field biocompatibility. Yet the fabrication of magnetic actuated especially helical motors requires expensive and complicated instruments, 3D printing or glancing angle deposition, etc. Here, a soft and biocompatible helical poly(vinyl alcohol) (PVA) hydrogel motor via a versatile set‐up is engineered. The obtained helical hydrogel motor offers high capacity for chemokine CXCL12 and superparamagnetic iron oxide (Fe3O4) nanoparticles, which can then allow magnetic manipulation. With a low strength rotating magnetic field, the system is able to perform 3D precision navigation, necessary to steer the robotic system to a model diseased area. The chemokine cues from the hydrogel motor, acting as the synthetic leader cell, then directs immune T cell chemotactic migration. In a previously reported cell manipulating motor system, towing or pushing a single/two cell was demonstrated, with limited efficiency. This motor platform represents a novel approach for directing endogenous cell chemotaxis and organizing immune response. A soft poly(vinyl alcohol) hydrogel motor with chemokine integrated is engineered via a versatile set‐up. This magnetic helical motor performs precision navigation and location to the target site in biorelevant media. Such a hydrogel motor can direct immune T cell chemotactic migration to a predetermined model disease site, representing a novel motor based approach for manipulating cell swarms.