Unspecific peroxygenase immobilization in 3D-printed microfluidics: towards tailor-made screening platforms

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Autoren

  • Elena Gkantzou
  • Theofilia Koulopoulou
  • Hannah Brass
  • David Schönauer
  • Anton Glieder
  • Selin Kara

Organisationseinheiten

Externe Organisationen

  • Bisy GmbH
  • Aarhus University
Forschungs-netzwerk anzeigen

Details

OriginalspracheEnglisch
Seiten (von - bis)6496-6502
Seitenumfang7
FachzeitschriftCatalysis science & technology
Jahrgang14
Ausgabenummer22
Frühes Online-Datum14 Okt. 2024
PublikationsstatusVeröffentlicht - 2024

Abstract

In the context of empowering biocatalysis, an easy-to-develop, reproducible, and easy-to-scale biocatalytic system under continuous flow is demonstrated. 3D printing technology is used as the reactor manufacturing method, yielding identical and low-cost microfluidic chips that can be further modified to serve as a biocatalytic platform for simultaneous parameter screening. The model enzyme studied here is unspecific peroxygenase (UPO). UPOs are currently under intensive study, due to their distinct promiscuity in oxyfunctionalization chemistry. This is the first study demonstrating UPO's immobilization in a microfluidic concept. The developed method for surface functionalization of microfluidic reactors is based on polydopamine modification and was proven highly reproducible. UPO showed a TTN of 19 249 and a STY of 2.1 g L -1 h -1, under the specified conditions. The kinetic behavior of the system under flow conditions is reported. The system was also regenerated with a 51.4% recovered activity. Further utilization of microfluidic concepts is expected to unravel the full potential of UPOs for oxyfunctionalization reactions of particular interest. The proposed system is foreseen as a screening platform for different reaction conditions, reaction substrates, or enzyme mutants.

Zitieren

Unspecific peroxygenase immobilization in 3D-printed microfluidics: towards tailor-made screening platforms. / Gkantzou, Elena; Koulopoulou, Theofilia; Brass, Hannah et al.
in: Catalysis science & technology, Jahrgang 14, Nr. 22, 2024, S. 6496-6502.

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Gkantzou E, Koulopoulou T, Brass H, Schönauer D, Glieder A, Kara S. Unspecific peroxygenase immobilization in 3D-printed microfluidics: towards tailor-made screening platforms. Catalysis science & technology. 2024;14(22):6496-6502. Epub 2024 Okt 14. doi: 10.1039/d4cy00869c
Gkantzou, Elena ; Koulopoulou, Theofilia ; Brass, Hannah et al. / Unspecific peroxygenase immobilization in 3D-printed microfluidics : towards tailor-made screening platforms. in: Catalysis science & technology. 2024 ; Jahrgang 14, Nr. 22. S. 6496-6502.
Download
@article{bf247c240eb34ae4b2be505c5dc2c484,
title = "Unspecific peroxygenase immobilization in 3D-printed microfluidics: towards tailor-made screening platforms",
abstract = "In the context of empowering biocatalysis, an easy-to-develop, reproducible, and easy-to-scale biocatalytic system under continuous flow is demonstrated. 3D printing technology is used as the reactor manufacturing method, yielding identical and low-cost microfluidic chips that can be further modified to serve as a biocatalytic platform for simultaneous parameter screening. The model enzyme studied here is unspecific peroxygenase (UPO). UPOs are currently under intensive study, due to their distinct promiscuity in oxyfunctionalization chemistry. This is the first study demonstrating UPO's immobilization in a microfluidic concept. The developed method for surface functionalization of microfluidic reactors is based on polydopamine modification and was proven highly reproducible. UPO showed a TTN of 19 249 and a STY of 2.1 g L -1 h -1, under the specified conditions. The kinetic behavior of the system under flow conditions is reported. The system was also regenerated with a 51.4% recovered activity. Further utilization of microfluidic concepts is expected to unravel the full potential of UPOs for oxyfunctionalization reactions of particular interest. The proposed system is foreseen as a screening platform for different reaction conditions, reaction substrates, or enzyme mutants.",
author = "Elena Gkantzou and Theofilia Koulopoulou and Hannah Brass and David Sch{\"o}nauer and Anton Glieder and Selin Kara",
note = "Publisher Copyright: {\textcopyright} 2024 The Royal Society of Chemistry.",
year = "2024",
doi = "10.1039/d4cy00869c",
language = "English",
volume = "14",
pages = "6496--6502",
journal = "Catalysis science & technology",
issn = "2044-4753",
publisher = "Royal Society of Chemistry",
number = "22",

}

Download

TY - JOUR

T1 - Unspecific peroxygenase immobilization in 3D-printed microfluidics

T2 - towards tailor-made screening platforms

AU - Gkantzou, Elena

AU - Koulopoulou, Theofilia

AU - Brass, Hannah

AU - Schönauer, David

AU - Glieder, Anton

AU - Kara, Selin

N1 - Publisher Copyright: © 2024 The Royal Society of Chemistry.

PY - 2024

Y1 - 2024

N2 - In the context of empowering biocatalysis, an easy-to-develop, reproducible, and easy-to-scale biocatalytic system under continuous flow is demonstrated. 3D printing technology is used as the reactor manufacturing method, yielding identical and low-cost microfluidic chips that can be further modified to serve as a biocatalytic platform for simultaneous parameter screening. The model enzyme studied here is unspecific peroxygenase (UPO). UPOs are currently under intensive study, due to their distinct promiscuity in oxyfunctionalization chemistry. This is the first study demonstrating UPO's immobilization in a microfluidic concept. The developed method for surface functionalization of microfluidic reactors is based on polydopamine modification and was proven highly reproducible. UPO showed a TTN of 19 249 and a STY of 2.1 g L -1 h -1, under the specified conditions. The kinetic behavior of the system under flow conditions is reported. The system was also regenerated with a 51.4% recovered activity. Further utilization of microfluidic concepts is expected to unravel the full potential of UPOs for oxyfunctionalization reactions of particular interest. The proposed system is foreseen as a screening platform for different reaction conditions, reaction substrates, or enzyme mutants.

AB - In the context of empowering biocatalysis, an easy-to-develop, reproducible, and easy-to-scale biocatalytic system under continuous flow is demonstrated. 3D printing technology is used as the reactor manufacturing method, yielding identical and low-cost microfluidic chips that can be further modified to serve as a biocatalytic platform for simultaneous parameter screening. The model enzyme studied here is unspecific peroxygenase (UPO). UPOs are currently under intensive study, due to their distinct promiscuity in oxyfunctionalization chemistry. This is the first study demonstrating UPO's immobilization in a microfluidic concept. The developed method for surface functionalization of microfluidic reactors is based on polydopamine modification and was proven highly reproducible. UPO showed a TTN of 19 249 and a STY of 2.1 g L -1 h -1, under the specified conditions. The kinetic behavior of the system under flow conditions is reported. The system was also regenerated with a 51.4% recovered activity. Further utilization of microfluidic concepts is expected to unravel the full potential of UPOs for oxyfunctionalization reactions of particular interest. The proposed system is foreseen as a screening platform for different reaction conditions, reaction substrates, or enzyme mutants.

UR - http://www.scopus.com/inward/record.url?scp=85207467282&partnerID=8YFLogxK

U2 - 10.1039/d4cy00869c

DO - 10.1039/d4cy00869c

M3 - Article

VL - 14

SP - 6496

EP - 6502

JO - Catalysis science & technology

JF - Catalysis science & technology

SN - 2044-4753

IS - 22

ER -

Von denselben Autoren