Taking the 3Rs to a higher level: replacement and reduction of animal testing in life sciences in space research

Mathieu Vinken; Daniela Grimm; Sarah Baatout; Bjorn Baselet; Afshin Beheshti; Markus Braun; Anna Catharina Carstens; James A. Casaletto; Ben Cools; Sylvain V. Costes; Phoebe De Meulemeester; Bartu Doruk; Sara Eyal; Miguel J.S. Ferreira; Silvana Miranda; Christiane Hahn; Sinem Helvacıoğlu Akyüz; Stefan Herbert; Dmitriy Krepkiy; Yannick Lichterfeld; Christian Liemersdorf; Marcus Krüger; Shannon Marchal; Jette Ritz; Theresa Schmakeit; Hilde Stenuit; Kevin Tabury; Torsten Trittel; Markus Wehland; Yu Shrike Zhang; Karson S. Putt; Zhong Yin Zhang; Danilo A. Tagle

doi:10.1016/j.biotechadv.2025.108574

Taking the 3Rs to a higher level: replacement and reduction of animal testing in life sciences in space research

Mathieu Vinken^*, Daniela Grimm, Sarah Baatout, Bjorn Baselet, Afshin Beheshti, Markus Braun, Anna Catharina Carstens, James A. Casaletto, Ben Cools, Sylvain V. Costes, Phoebe De Meulemeester, Bartu Doruk, Sara Eyal, Miguel J.S. Ferreira, Silvana Miranda, Christiane Hahn, Sinem Helvacıoğlu Akyüz, Stefan Herbert, Dmitriy Krepkiy, Yannick LichterfeldChristian Liemersdorf, Marcus Krüger, Shannon Marchal, Jette Ritz, Theresa Schmakeit, Hilde Stenuit, Kevin Tabury, Torsten Trittel, Markus Wehland, Yu Shrike Zhang, Karson S. Putt, Zhong Yin Zhang, Danilo A. Tagle

^*Corresponding author for this work

School of Pharmacy

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

Abstract

Human settlements on the Moon, crewed missions to Mars and space tourism will become a reality in the next few decades. Human presence in space, especially for extended periods of time, will therefore steeply increase. However, despite more than 60 years of spaceflight, the mechanisms underlying the effects of the space environment on human physiology are still not fully understood. Animals, ranging in complexity from flies to monkeys, have played a pioneering role in understanding the (patho)physiological outcome of critical environmental factors in space, in particular altered gravity and cosmic radiation. The use of animals in biomedical research is increasingly being criticized because of ethical reasons and limited human relevance. Driven by the 3Rs concept, calling for replacement, reduction and refinement of animal experimentation, major efforts have been focused in the past decades on the development of alternative methods that fully bypass animal testing or so-called new approach methodologies. These new approach methodologies range from simple monolayer cultures of individual primary or stem cells all up to bioprinted 3D organoids and microfluidic chips that recapitulate the complex cellular architecture of organs. Other approaches applied in life sciences in space research contribute to the reduction of animal experimentation. These include methods to mimic space conditions on Earth, such as microgravity and radiation simulators, as well as tools to support the processing, analysis or application of testing results obtained in life sciences in space research, including systems biology, live-cell, high-content and real-time analysis, high-throughput analysis, artificial intelligence and digital twins. The present paper provides an in-depth overview of such methods to replace or reduce animal testing in life sciences in space research.

Original language	English
Article number	108574
Journal	Biotechnology Advances
Volume	81
DOIs	https://doi.org/10.1016/j.biotechadv.2025.108574
State	Published - 1 Jul 2025

Bibliographical note

Publisher Copyright:
© 2025 Elsevier Inc.

Keywords

Artificial intelligence
Bioprinting
Digital twins
High-throughput screening
Live-cell, high-content and real-time analysis
Microgravity and radiation simulators
Microphysiological system
Primary cells and stem cells
Spheroids and organoids
Systems biology

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10.1016/j.biotechadv.2025.108574

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Vinken, M., Grimm, D., Baatout, S., Baselet, B., Beheshti, A., Braun, M., Carstens, A. C., Casaletto, J. A., Cools, B., Costes, S. V., De Meulemeester, P., Doruk, B., Eyal, S., Ferreira, M. J. S., Miranda, S., Hahn, C., Helvacıoğlu Akyüz, S., Herbert, S., Krepkiy, D., ... Tagle, D. A. (2025). Taking the 3Rs to a higher level: replacement and reduction of animal testing in life sciences in space research. Biotechnology Advances, 81, Article 108574. https://doi.org/10.1016/j.biotechadv.2025.108574

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abstract = "Human settlements on the Moon, crewed missions to Mars and space tourism will become a reality in the next few decades. Human presence in space, especially for extended periods of time, will therefore steeply increase. However, despite more than 60 years of spaceflight, the mechanisms underlying the effects of the space environment on human physiology are still not fully understood. Animals, ranging in complexity from flies to monkeys, have played a pioneering role in understanding the (patho)physiological outcome of critical environmental factors in space, in particular altered gravity and cosmic radiation. The use of animals in biomedical research is increasingly being criticized because of ethical reasons and limited human relevance. Driven by the 3Rs concept, calling for replacement, reduction and refinement of animal experimentation, major efforts have been focused in the past decades on the development of alternative methods that fully bypass animal testing or so-called new approach methodologies. These new approach methodologies range from simple monolayer cultures of individual primary or stem cells all up to bioprinted 3D organoids and microfluidic chips that recapitulate the complex cellular architecture of organs. Other approaches applied in life sciences in space research contribute to the reduction of animal experimentation. These include methods to mimic space conditions on Earth, such as microgravity and radiation simulators, as well as tools to support the processing, analysis or application of testing results obtained in life sciences in space research, including systems biology, live-cell, high-content and real-time analysis, high-throughput analysis, artificial intelligence and digital twins. The present paper provides an in-depth overview of such methods to replace or reduce animal testing in life sciences in space research.",

keywords = "Artificial intelligence, Bioprinting, Digital twins, High-throughput screening, Live-cell, high-content and real-time analysis, Microgravity and radiation simulators, Microphysiological system, Primary cells and stem cells, Spheroids and organoids, Systems biology",

author = "Mathieu Vinken and Daniela Grimm and Sarah Baatout and Bjorn Baselet and Afshin Beheshti and Markus Braun and Carstens, {Anna Catharina} and Casaletto, {James A.} and Ben Cools and Costes, {Sylvain V.} and {De Meulemeester}, Phoebe and Bartu Doruk and Sara Eyal and Ferreira, {Miguel J.S.} and Silvana Miranda and Christiane Hahn and {Helvacıoğlu Aky{\"u}z}, Sinem and Stefan Herbert and Dmitriy Krepkiy and Yannick Lichterfeld and Christian Liemersdorf and Marcus Kr{\"u}ger and Shannon Marchal and Jette Ritz and Theresa Schmakeit and Hilde Stenuit and Kevin Tabury and Torsten Trittel and Markus Wehland and Zhang, {Yu Shrike} and Putt, {Karson S.} and Zhang, {Zhong Yin} and Tagle, {Danilo A.}",

note = "Publisher Copyright: {\textcopyright} 2025 Elsevier Inc.",

year = "2025",

month = jul,

day = "1",

doi = "10.1016/j.biotechadv.2025.108574",

language = "אנגלית",

volume = "81",

journal = "Biotechnology Advances",

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Vinken, M, Grimm, D, Baatout, S, Baselet, B, Beheshti, A, Braun, M, Carstens, AC, Casaletto, JA, Cools, B, Costes, SV, De Meulemeester, P, Doruk, B, Eyal, S, Ferreira, MJS, Miranda, S, Hahn, C, Helvacıoğlu Akyüz, S, Herbert, S, Krepkiy, D, Lichterfeld, Y, Liemersdorf, C, Krüger, M, Marchal, S, Ritz, J, Schmakeit, T, Stenuit, H, Tabury, K, Trittel, T, Wehland, M, Zhang, YS, Putt, KS, Zhang, ZY & Tagle, DA 2025, 'Taking the 3Rs to a higher level: replacement and reduction of animal testing in life sciences in space research', Biotechnology Advances, vol. 81, 108574. https://doi.org/10.1016/j.biotechadv.2025.108574

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AU - Grimm, Daniela

AU - Baatout, Sarah

AU - Baselet, Bjorn

AU - Beheshti, Afshin

AU - Braun, Markus

AU - Carstens, Anna Catharina

AU - Casaletto, James A.

AU - Cools, Ben

AU - Costes, Sylvain V.

AU - De Meulemeester, Phoebe

AU - Doruk, Bartu

AU - Eyal, Sara

AU - Ferreira, Miguel J.S.

AU - Miranda, Silvana

AU - Hahn, Christiane

AU - Helvacıoğlu Akyüz, Sinem

AU - Herbert, Stefan

AU - Krepkiy, Dmitriy

AU - Lichterfeld, Yannick

AU - Liemersdorf, Christian

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AU - Schmakeit, Theresa

AU - Stenuit, Hilde

AU - Tabury, Kevin

AU - Trittel, Torsten

AU - Wehland, Markus

AU - Zhang, Yu Shrike

AU - Putt, Karson S.

AU - Zhang, Zhong Yin

AU - Tagle, Danilo A.

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KW - Live-cell, high-content and real-time analysis

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KW - Microphysiological system

KW - Primary cells and stem cells

KW - Spheroids and organoids

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Taking the 3Rs to a higher level: replacement and reduction of animal testing in life sciences in space research

Abstract

Bibliographical note

Keywords

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