High‐Throughput Design of Biocompatible Enzyme‐Based Hydrogel Microparticles with Autonomous Movement

Micro‐ and nanomotors and their use for biomedical applications have recently received increased attention. However, most designs use top‐down methods to construct inorganic motors, which are labour‐intensive and not suitable for biomedical use. Herein, we report a high‐throughput design of an asymm...

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Veröffentlicht in:Angewandte Chemie 2018-07, Vol.130 (31), p.9962-9965
Hauptverfasser: Keller, Shauni, Teora, Serena P., Hu, Guo Xun, Nijemeisland, Marlies, Wilson, Daniela A.
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Sprache:eng
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Zusammenfassung:Micro‐ and nanomotors and their use for biomedical applications have recently received increased attention. However, most designs use top‐down methods to construct inorganic motors, which are labour‐intensive and not suitable for biomedical use. Herein, we report a high‐throughput design of an asymmetric hydrogel microparticle with autonomous movement by using a microfluidic chip to generate asymmetric, aqueous, two‐phase‐separating droplets consisting of poly(ethylene glycol) diacrylate (PEGDA) and dextran, with the biocatalyst placed in the PEGDA phase. The motor is propelled by enzyme‐mediated decomposition of fuel. The speed of the motors is influenced by the roughness of the PEGDA surface after diffusion of dextran and was tuned by using higher molecular weight dextran. This roughness allows for easier pinning of oxygen bubbles and thus higher speeds of the motors. Pinning of bubbles occurs repeatedly at the same location, thereby resulting in constant circular or linear motion. Enzym‐Antrieb: Mithilfe von Mikrofluidik und spontaner Phasentrennung werden Tröpfchen‐in‐Tröpfchen‐Morphologien hergestellt, deren Polymerisation unsymmetrische Mikrogele ergibt. Wird ein Enzym im Hydrogel eingeschlossen, so resultieren aktive Partikel, die sich beim Zusatz eines Treibstoffs (hier Wasserstoffperoxid) selbständig bewegen können.
ISSN:0044-8249
1521-3757
DOI:10.1002/ange.201805661