Submitted by AskScienceModerator t3_10px8sa in askscience
intengineering t1_j6oadaj wrote
Reply to comment by yigitjohn48 in AskScience AMA Series: I'm Birgül Akolpoglu, a doctoral researcher at the Max Planck Institute for Intelligent Systems in Germany. I work on microalgae and bacteria-based microrobots that could one day be used to deliver drugs and battle cancer! AMA! by AskScienceModerator
Thank you for your questions. Here in our study, what happens is that we attach nano-sized magnetic particles to bacteria, and therefore, we are able to control those bacteria using external magnetic fields. You can imagine a single bacterium turning into a tiny magnet that can be navigated using a larger magnet, or electromagnetic setup. As for the colonies, with our optimized method, we were able to generate millions of these bacteria (we call them bacterial biohybrids), carrying the magnetic nanoparticles, meaning that we were able to control the swarms of bacterial biohybrids using external magnetic stimuli. Magnetic control mechanisms are quite robust since magnetic fields are safe to use in clinics and it allows for precise control over tiny swimmers. We can technically “steer” them using our electromagnetic coils, they go right when you press right, and go up when you press up on the control panel!
Hope this answers your questions!
All the best,
/birgül
lawless_c t1_j6obb8z wrote
Is this making them swim i directions you choose or is it more like dragging them about?
Does the magnetic tool(s) that control them have to be super close, like contact with the body?
intengineering t1_j6oeuco wrote
It is not dragging but rather aligning them. So what happens is that the nanoparticles on bacteria align with the applied magnetic field. Therefore, bacteria follow that path. We could also create so-called "magnetic gradients", which would cause dragging or pulling. But we want to use their own motility rather than pulling them.
As for the second question: No, they don't. We use electromagnetic coils (see: https://www.sciencedirect.com/topics/engineering/electromagnetic-coil) that generate enough magnetic field in the center of the setup to steer the microswimmers. These setups are designed for microscopic use, i.e., we attach them to a microscope to simultaneously visualize the motion of bacteria under magnetic fields. Of course, you would need much larger setups for use in humans in the future, but even in that case, it wouldn't be in contact with the body.
Thanks for the Qs!
All the best,
/birgül
DeDragoner t1_j6okrhi wrote
How do you envision to implement this in vivo? There will be innumerable additional challenges (navigating 3D space, tissues etc.) How do you plan to reach tissues? A delivery by the bloodstream would cause heavy immun reactions.
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