Microrobots in Brewery: Dual Magnetic/Light-Powered Hybrid Microrobots for Preventing Microbial Contamination in Beer

Katherine Villa; Jan Vyskočil; Yulong Ying; Jaroslav Zelenka; Martin Pumera

doi:10.1002/chem.202000162

Microrobots in Brewery: Dual Magnetic/Light-Powered Hybrid Microrobots for Preventing Microbial Contamination in Beer

Katherine Villa, Jan Vyskočil, Yulong Ying, Jaroslav Zelenka, Martin Pumera

Department of Chemical and Biomolecular Engineering

Research output: Contribution to journal › Article › peer-review

16 Citations (Scopus)

Abstract

Yeasts play a key role in the production of alcoholic beverages by fermentation processes. However, because of their continuous growth, they commonly cause spoilage of the final product. Herein, we introduce dual magnetic/light-responsive self-propelled microrobots that can actively move in a beer sample and capture yeast cells. The presence of magnetic nanoparticles on the surface of the microrobots enables their magnetic actuation under fuel-free conditions. In addition, their photoactivity under visible-light irradiation leads to an overall enhancement of their swimming and yeast removal capabilities. It was found that after the application of the microrobots into a real unfiltered beer sample, these micromachines were able to remove almost 100 % of residual yeasts. In addition, these microrobots could also be added at the initial step of the fermentation process without altering the final beer properties, such as alcohol level, color, and pH. This work demonstrates the potential of using externally actuated microrobots as an innovative and low-cost solution for avoiding yeast spoilage in complex liquid environments, such as alcoholic beverages. Therefore, these autonomous self-propelled microrobots open new avenues for future applications in the food industry.

Original language	English
Pages (from-to)	3039-3043
Number of pages	5
Journal	Chemistry - A European Journal
Volume	26
Issue number	14
DOIs	https://doi.org/10.1002/chem.202000162
Publication status	Published - 2020 Mar 9

Bibliographical note

Funding Information:
M.P. acknowledges the financial support of Grant Agency of the Czech Republic (EXPRO: 19-26896X). The authors thank F. Novotny for the MSD calculations, T. Kincl from the Biotechnology department at UCT for the beer samples and discussions, Dominika Fečková for the CFU measurements and Petr Šálek for the ICP-OES measurements.

Funding Information:
M.P. acknowledges the financial support of Grant Agency of the Czech Republic (EXPRO: 19‐26896X). The authors thank F. Novotny for the MSD calculations, T. Kincl from the Biotechnology department at UCT for the beer samples and discussions, Dominika Fečková for the CFU measurements and Petr Šálek for the ICP‐OES measurements.

Publisher Copyright:
© 2020 Wiley-VCH Verlag GmbH & Co. KGaA, Weinheim

All Science Journal Classification (ASJC) codes

Catalysis
Organic Chemistry

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10.1002/chem.202000162

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title = "Microrobots in Brewery: Dual Magnetic/Light-Powered Hybrid Microrobots for Preventing Microbial Contamination in Beer",

abstract = "Yeasts play a key role in the production of alcoholic beverages by fermentation processes. However, because of their continuous growth, they commonly cause spoilage of the final product. Herein, we introduce dual magnetic/light-responsive self-propelled microrobots that can actively move in a beer sample and capture yeast cells. The presence of magnetic nanoparticles on the surface of the microrobots enables their magnetic actuation under fuel-free conditions. In addition, their photoactivity under visible-light irradiation leads to an overall enhancement of their swimming and yeast removal capabilities. It was found that after the application of the microrobots into a real unfiltered beer sample, these micromachines were able to remove almost 100 % of residual yeasts. In addition, these microrobots could also be added at the initial step of the fermentation process without altering the final beer properties, such as alcohol level, color, and pH. This work demonstrates the potential of using externally actuated microrobots as an innovative and low-cost solution for avoiding yeast spoilage in complex liquid environments, such as alcoholic beverages. Therefore, these autonomous self-propelled microrobots open new avenues for future applications in the food industry.",

author = "Katherine Villa and Jan Vysko{\v c}il and Yulong Ying and Jaroslav Zelenka and Martin Pumera",

note = "Funding Information: M.P. acknowledges the financial support of Grant Agency of the Czech Republic (EXPRO: 19-26896X). The authors thank F. Novotny for the MSD calculations, T. Kincl from the Biotechnology department at UCT for the beer samples and discussions, Dominika Fe{\v c}kov{\'a} for the CFU measurements and Petr {\v S}{\'a}lek for the ICP-OES measurements. Funding Information: M.P. acknowledges the financial support of Grant Agency of the Czech Republic (EXPRO: 19‐26896X). The authors thank F. Novotny for the MSD calculations, T. Kincl from the Biotechnology department at UCT for the beer samples and discussions, Dominika Fe{\v c}kov{\'a} for the CFU measurements and Petr {\v S}{\'a}lek for the ICP‐OES measurements. Publisher Copyright: {\textcopyright} 2020 Wiley-VCH Verlag GmbH & Co. KGaA, Weinheim",

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N2 - Yeasts play a key role in the production of alcoholic beverages by fermentation processes. However, because of their continuous growth, they commonly cause spoilage of the final product. Herein, we introduce dual magnetic/light-responsive self-propelled microrobots that can actively move in a beer sample and capture yeast cells. The presence of magnetic nanoparticles on the surface of the microrobots enables their magnetic actuation under fuel-free conditions. In addition, their photoactivity under visible-light irradiation leads to an overall enhancement of their swimming and yeast removal capabilities. It was found that after the application of the microrobots into a real unfiltered beer sample, these micromachines were able to remove almost 100 % of residual yeasts. In addition, these microrobots could also be added at the initial step of the fermentation process without altering the final beer properties, such as alcohol level, color, and pH. This work demonstrates the potential of using externally actuated microrobots as an innovative and low-cost solution for avoiding yeast spoilage in complex liquid environments, such as alcoholic beverages. Therefore, these autonomous self-propelled microrobots open new avenues for future applications in the food industry.

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Microrobots in Brewery: Dual Magnetic/Light-Powered Hybrid Microrobots for Preventing Microbial Contamination in Beer

Abstract

Bibliographical note

All Science Journal Classification (ASJC) codes

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