Abstract
Advances in microrobotics for biological applications are often limited due to their complex manufacturing processes, which often utilize cytotoxic materials, as well as limitations in the ability to manipulate these small devices wirelessly. In an effort to overcome these challenges, we investigated a facile method for generating biocompatible hydrogel based robots that are capable of being manipulated using an externally generated magnetic field. Here, we experimentally demonstrate the fabrication and autonomous control of loaded-alginate microspheres, which we term artificial cells. In order to generate these microparticles, we employed a centrifuge-based method in which microspheres were rapidly ejected from a nozzle tip. Specifically, we used two mixtures of sodium alginate; one containing iron oxide nanoparticles and the other containing mammalian cells. This mixture was loaded into a needle that was fixed on top of a microtube containing calcium chloride, and then briefly centrifuged to generate hundreds of Janus microspheres. The fabricated microparticles were then magnetically actuated with a rotating magnetic field, generated using electromagnetic coils, prompting the particles to roll across a glass substrate. Also, using vision-based feedback control, a single artificial cell was manipulated to autonomously move in a programmed pattern.
Highlights
Today one of the most exciting frontiers in robotics is the development of untethered microand nanorobotic systems, which hold the potential to revolutionize the fields of bio-manufacturing and medicine
Many groups have termed these loaded-alginate particles as artificial cells,[26,27,28] in that they mimic the basic structure of living cells
These cell-like particles have the potential to be used for on-demand assembly of high resolution biological materials;[29] yet they are limited by the fact that it is difficult to precisely control their movement, assembly times depend on manual skill, and have low throughput.[30]
Summary
Today one of the most exciting frontiers in robotics is the development of untethered microand nanorobotic systems, which hold the potential to revolutionize the fields of bio-manufacturing and medicine. Towards this end we have fabricated alginate Janus microparticles (i.e. artificial cells) that encapsulate both magnetic nanoparticles and living cells and demonstrate the ability to actuate these microparticles autonomously through vision based feedback control utilizing the magnetic field generated by a three-axis electromagnetic coil system.
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