Artificial microtubules for rapid and collective transport of magnetic microcargoes
Abstract
Directed transport of microcargoes is essential for living organisms as well as for applications in microrobotics, nanotechnology and biomedicine. Existing delivery technologies often suffer from low speeds, limited navigation control and dispersal by cardiovascular flows. In cell biology, these issues are largely overcome by cytoskeletal motors that carry vesicles along microtubule highways. Thus inspired, here we developed an artificial microtubule (AMT), a structured microfibre with embedded micromagnets that serve as stepping stones to guide particles rapidly through flow networks. Compared with established techniques, the microcargo travels an order of magnitude faster using the same driving frequency, and dispersal is mitigated by a strong dynamic anchoring effect. Even against strong fluid flows, the large local magnetic-field gradients enable both anchoring and guided propulsion. Finally, we show that AMTs can facilitate the self-assembly of microparticles into active-matter clusters, which then enhance their walking speed by bridging over stepping stones collectively. Hence, we demonstrate a unique strategy for robust delivery inside microvascular networks and for minimally invasive interventions, with non-equilibrium effects that could be equally relevant for enhancing biological transport processes. Show more
Permanent link
https://doi.org/10.3929/ethz-b-000559356Publication status
publishedExternal links
Journal / series
Nature Machine IntelligenceVolume
Pages / Article No.
Publisher
SpringerOrganisational unit
03627 - Nelson, Bradley J. / Nelson, Bradley J.
Funding
743217 - Soft Micro Robotics (EC)
185039 - Arbeitstitel "Soft Magnetic Robots: Modeling, Design and Control of Magnetically Guided Continuum Manipulators" (SNF)
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