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Issue 4, 2010
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Modeling magnetic microcapsules that crawl in microchannels

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Abstract

Using computational modeling, we probe how to design microfluidic systems in which magnetic microcapsules could autonomously crawl along channel walls. The polymeric microcapsules are fluid-filled elastic shells with embedded superparamagnetic nanoparticles and, thereby, can be controlled by external magnetic fields. We show that when a magnetic force circulates normal to a sticky microchannel wall, capsules can propel in a steady, autonomous manner. The unidirectional capsule propulsion is facilitated by hydrodynamic interactions between the capsules and channel walls, and is most effective when the magnitudes of magnetic and adhesive forces are equal to each other. Furthermore, the propulsion efficiency is greater for compliant capsules. Our findings could be useful for designing novel microfluidic devices where mobile magnetic microcapsules could be harnessed as microscale transport vehicles.

Graphical abstract: Modeling magnetic microcapsules that crawl in microchannels

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Publication details

The article was received on 14 Aug 2009, accepted on 19 Oct 2009 and first published on 01 Dec 2009


Article type: Paper
DOI: 10.1039/B916835D
Citation: Soft Matter, 2010,6, 794-799
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    Modeling magnetic microcapsules that crawl in microchannels

    H. Masoud and A. Alexeev, Soft Matter, 2010, 6, 794
    DOI: 10.1039/B916835D

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