Abstract
Magnetic micromachines as wireless end-effectors have been widely applied for drug discovery and regenerative medicine. Yet, the magnetic assembly of arbitrarily shaped cellular microstructures with high efficiency and flexibility still remains a big challenge. Here, a novel clamp-shape micromachine using magnetic nanoparticles was developed for the indirect untethered bioassembly. With a multi-layer template, the nickel nanoparticles were mixed with polydimethylsiloxane (PDMS) for mold replication of the micromachine with a high-resolution and permeability. To actuate the micromachine with a high flexibility and large scalable operation range, a multi-pole electromagnetic system was set up to generate a three-dimensional magnetic field in a large workspace. Through designing a series of flexible translations and rotations with a velocity of 15mm/s and 3 Hz, the micromachine realized the propel-and-throw strategy to overcome the inevitable adhesion during bioassembly. The hydrogel microstructures loaded with different types of cells or the bioactive materials were effectively assembled into microtissues with reconfigurable shape and composition. The results indicate that indirect magnetic manipulation can perform an efficient and versatile bioassembly of cellular micromodules, which is promising for drug trials and modular tissue engineering.
Highlights
The fabrication and manipulation of micro/nanostructure play an important role in various applications including microelectronic devices and biomedical research [1,2,3]
For clinical diagnosis and treatment, magnetic micromachine can work in a confined space flexibly and has been applied for capsule endoscope [4,5] and minimally invasive surgery [6,7]
Magnetic nanoparticles (MNPs), as the superparamagnetic nanomaterial with controllable sizes ranging from a cell dimension to a virus dimension, provide the ability to coat or bond with biological entities for wireless transport and immobilization tasks under microscale [11,12]
Summary
The fabrication and manipulation of micro/nanostructure play an important role in various applications including microelectronic devices and biomedical research [1,2,3]. Since magnetic force is primarily exerted on magnetic substances, it is crucial to design and implement complex micromachine with desired shape and composition for specific tasks [8,9,10]. Through compounding MNPs with biocompatible or biodegradable polymers, the magnet-tagged micromachines can be fabricated as microcarrier or end-effector for versatile, dynamic, and accurate biomanipulation [13,14]. The development of MNPs-based micromachine with customized architecture and control scheme is meaningful in pharmacological research and tissue engineering
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