Bioreactive separation technology: A retrospective and perspective

Thomas Waluga; Daniel Ohde; Marion Ansorge-Schumacher; Regina Benfer; Wilfried Bluemke; Heiko Briesen; Jakob Burger; Anja Drews; Johannes Gescher; Christiane Glasmacher-Remberg; Marcus Grünewald; Niels Hansen; Christoph Held; Dirk Holtmann; Selin Kara; Jan von Langermann; Andreas Liese; Jørgen Magnus; Alexander Pelzer; Jürgen Pleiss; Tina Radespiel; Jens Uwe Repke; Katrin Rosenthal; Anett Schallmey; Irina Smirnova; John M. Woodley; Thomas Wucherpfennig; Michael Zavrel; Tim Zeiner; Mirko Skiborowski

doi:10.1016/j.cep.2026.110787

Bioreactive separation technology: A retrospective and perspective

Thomas Waluga, Daniel Ohde, Marion Ansorge-Schumacher, Regina Benfer, Wilfried Bluemke, Heiko Briesen, Jakob Burger, Anja Drews, Johannes Gescher, Christiane Glasmacher-Remberg, Marcus Grünewald, Niels Hansen, Christoph Held, Dirk Holtmann, Selin Kara, Jan von Langermann, Andreas Liese, Jørgen Magnus, Alexander Pelzer, Jürgen PleissTina Radespiel, Jens Uwe Repke, Katrin Rosenthal, Anett Schallmey, Irina Smirnova, John M. Woodley, Thomas Wucherpfennig, Michael Zavrel, Tim Zeiner, Mirko Skiborowski^*

^*Corresponding author for this work

Institute of Technical Chemistry

Research output: Contribution to journal › Review article › Research › peer review

Abstract

Biocatalysis, using enzymes or whole cells, offers high selectivity under mild conditions, but its broader application is often hindered by slow kinetics, equilibrium limitations, product inhibition and the processing of dilute streams in the presence of enzymes and cells. Bioreactive separation, defined as the simultaneous process of biocatalysis and separation, provides a powerful concept to overcome these barriers and therefore offers the potential of superiority over conventional processes. The current retro- and perspective paper, which is the result of an interdisciplinary workshop with academic and industry experts from the areas of biotechnology, fluid separations and process systems engineering, provides a focussed review, paired with a distinct novel definition of bioreactive separations that links to multifunctional reactors in chemical engineering and in situ product removal in biocatalysis. By establishing a common framework, this definition connects different research areas and enables systematic development. The current status of bioreactive separation processes is evaluated using SWOT analyses to identify key potentials and challenges. Based on this, a vision for 2040 is outlined, highlighting the need for advances in integration strategies, biocatalyst design, modelling and simulation, and applied research. Overall, a coordinated progress in these areas can significantly enhance the scalability and sustainability of bioprocessing.

Original language	English
Article number	110787
Journal	Chemical Engineering and Processing - Process Intensification
Volume	224
E-pub ahead of print	28 Mar 2026
DOIs	https://doi.org/10.1016/j.cep.2026.110787
Publication status	E-pub ahead of print - 28 Mar 2026

Keywords

Biocatalysis
In situ product removal
Process intensification
Reactive separation

ASJC Scopus subject areas

General Chemistry
General Chemical Engineering
Energy Engineering and Power Technology
Industrial and Manufacturing Engineering

Access to Document

10.1016/j.cep.2026.110787Licence: CC BY 4.0

Cite this

Waluga, T., Ohde, D., Ansorge-Schumacher, M., Benfer, R., Bluemke, W., Briesen, H., Burger, J., Drews, A., Gescher, J., Glasmacher-Remberg, C., Grünewald, M., Hansen, N., Held, C., Holtmann, D., Kara, S., von Langermann, J., Liese, A., Magnus, J., Pelzer, A., ... Skiborowski, M. (2026). Bioreactive separation technology: A retrospective and perspective. Chemical Engineering and Processing - Process Intensification, 224, Article 110787. Advance online publication. https://doi.org/10.1016/j.cep.2026.110787

@article{496823f538b8468eb6f623d2601e3157,

title = "Bioreactive separation technology: A retrospective and perspective",

abstract = "Biocatalysis, using enzymes or whole cells, offers high selectivity under mild conditions, but its broader application is often hindered by slow kinetics, equilibrium limitations, product inhibition and the processing of dilute streams in the presence of enzymes and cells. Bioreactive separation, defined as the simultaneous process of biocatalysis and separation, provides a powerful concept to overcome these barriers and therefore offers the potential of superiority over conventional processes. The current retro- and perspective paper, which is the result of an interdisciplinary workshop with academic and industry experts from the areas of biotechnology, fluid separations and process systems engineering, provides a focussed review, paired with a distinct novel definition of bioreactive separations that links to multifunctional reactors in chemical engineering and in situ product removal in biocatalysis. By establishing a common framework, this definition connects different research areas and enables systematic development. The current status of bioreactive separation processes is evaluated using SWOT analyses to identify key potentials and challenges. Based on this, a vision for 2040 is outlined, highlighting the need for advances in integration strategies, biocatalyst design, modelling and simulation, and applied research. Overall, a coordinated progress in these areas can significantly enhance the scalability and sustainability of bioprocessing.",

keywords = "Biocatalysis, In situ product removal, Process intensification, Reactive separation",

author = "Thomas Waluga and Daniel Ohde and Marion Ansorge-Schumacher and Regina Benfer and Wilfried Bluemke and Heiko Briesen and Jakob Burger and Anja Drews and Johannes Gescher and Christiane Glasmacher-Remberg and Marcus Gr{\"u}newald and Niels Hansen and Christoph Held and Dirk Holtmann and Selin Kara and {von Langermann}, Jan and Andreas Liese and J{\o}rgen Magnus and Alexander Pelzer and J{\"u}rgen Pleiss and Tina Radespiel and Repke, {Jens Uwe} and Katrin Rosenthal and Anett Schallmey and Irina Smirnova and Woodley, {John M.} and Thomas Wucherpfennig and Michael Zavrel and Tim Zeiner and Mirko Skiborowski",

note = "Publisher Copyright: {\textcopyright} 2026 The Authors. Published by Elsevier B.V. This is an open access article under the CC BY license. http://creativecommons.org/licenses/by/4.0/",

year = "2026",

month = mar,

day = "28",

doi = "10.1016/j.cep.2026.110787",

language = "English",

volume = "224",

journal = "Chemical Engineering and Processing - Process Intensification",

issn = "0255-2701",

publisher = "Elsevier BV",

}

Waluga, T, Ohde, D, Ansorge-Schumacher, M, Benfer, R, Bluemke, W, Briesen, H, Burger, J, Drews, A, Gescher, J, Glasmacher-Remberg, C, Grünewald, M, Hansen, N, Held, C, Holtmann, D, Kara, S, von Langermann, J, Liese, A, Magnus, J, Pelzer, A, Pleiss, J, Radespiel, T, Repke, JU, Rosenthal, K, Schallmey, A, Smirnova, I, Woodley, JM, Wucherpfennig, T, Zavrel, M, Zeiner, T & Skiborowski, M 2026, 'Bioreactive separation technology: A retrospective and perspective', Chemical Engineering and Processing - Process Intensification, vol. 224, 110787. https://doi.org/10.1016/j.cep.2026.110787

TY - JOUR

T1 - Bioreactive separation technology

T2 - A retrospective and perspective

AU - Waluga, Thomas

AU - Ohde, Daniel

AU - Ansorge-Schumacher, Marion

AU - Benfer, Regina

AU - Bluemke, Wilfried

AU - Briesen, Heiko

AU - Burger, Jakob

AU - Drews, Anja

AU - Gescher, Johannes

AU - Glasmacher-Remberg, Christiane

AU - Grünewald, Marcus

AU - Hansen, Niels

AU - Held, Christoph

AU - Holtmann, Dirk

AU - Kara, Selin

AU - von Langermann, Jan

AU - Liese, Andreas

AU - Magnus, Jørgen

AU - Pelzer, Alexander

AU - Pleiss, Jürgen

AU - Radespiel, Tina

AU - Repke, Jens Uwe

AU - Rosenthal, Katrin

AU - Schallmey, Anett

AU - Smirnova, Irina

AU - Woodley, John M.

AU - Wucherpfennig, Thomas

AU - Zavrel, Michael

AU - Zeiner, Tim

AU - Skiborowski, Mirko

PY - 2026/3/28

Y1 - 2026/3/28

N2 - Biocatalysis, using enzymes or whole cells, offers high selectivity under mild conditions, but its broader application is often hindered by slow kinetics, equilibrium limitations, product inhibition and the processing of dilute streams in the presence of enzymes and cells. Bioreactive separation, defined as the simultaneous process of biocatalysis and separation, provides a powerful concept to overcome these barriers and therefore offers the potential of superiority over conventional processes. The current retro- and perspective paper, which is the result of an interdisciplinary workshop with academic and industry experts from the areas of biotechnology, fluid separations and process systems engineering, provides a focussed review, paired with a distinct novel definition of bioreactive separations that links to multifunctional reactors in chemical engineering and in situ product removal in biocatalysis. By establishing a common framework, this definition connects different research areas and enables systematic development. The current status of bioreactive separation processes is evaluated using SWOT analyses to identify key potentials and challenges. Based on this, a vision for 2040 is outlined, highlighting the need for advances in integration strategies, biocatalyst design, modelling and simulation, and applied research. Overall, a coordinated progress in these areas can significantly enhance the scalability and sustainability of bioprocessing.

AB - Biocatalysis, using enzymes or whole cells, offers high selectivity under mild conditions, but its broader application is often hindered by slow kinetics, equilibrium limitations, product inhibition and the processing of dilute streams in the presence of enzymes and cells. Bioreactive separation, defined as the simultaneous process of biocatalysis and separation, provides a powerful concept to overcome these barriers and therefore offers the potential of superiority over conventional processes. The current retro- and perspective paper, which is the result of an interdisciplinary workshop with academic and industry experts from the areas of biotechnology, fluid separations and process systems engineering, provides a focussed review, paired with a distinct novel definition of bioreactive separations that links to multifunctional reactors in chemical engineering and in situ product removal in biocatalysis. By establishing a common framework, this definition connects different research areas and enables systematic development. The current status of bioreactive separation processes is evaluated using SWOT analyses to identify key potentials and challenges. Based on this, a vision for 2040 is outlined, highlighting the need for advances in integration strategies, biocatalyst design, modelling and simulation, and applied research. Overall, a coordinated progress in these areas can significantly enhance the scalability and sustainability of bioprocessing.

KW - Biocatalysis

KW - In situ product removal

KW - Process intensification

KW - Reactive separation

UR - http://www.scopus.com/inward/record.url?scp=105034843698&partnerID=8YFLogxK

U2 - 10.1016/j.cep.2026.110787

DO - 10.1016/j.cep.2026.110787

M3 - Review article

AN - SCOPUS:105034843698

SN - 0255-2701

VL - 224

JO - Chemical Engineering and Processing - Process Intensification

JF - Chemical Engineering and Processing - Process Intensification

M1 - 110787

ER -

Bioreactive separation technology: A retrospective and perspective

Abstract

Keywords

ASJC Scopus subject areas

Access to Document

Other files and links

Cite this