Optimization of Media Change Intervals through Hydrogels Using Mathematical Models

F.A.A. Ruiter; J. King; S. Swapnasrita; S. Giselbrecht; R. Truckenmuller; V.L.S. LaPointe; M.B. Baker; A. Carlier

doi:10.1021/acs.biomac.2c00961

Optimization of Media Change Intervals through Hydrogels Using Mathematical Models

F.A.A. Ruiter, J. King, S. Swapnasrita, S. Giselbrecht, R. Truckenmuller, V.L.S. LaPointe, M.B. Baker^*, A. Carlier^*

^*Corresponding author for this work

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

Abstract

Three-dimensional cell culture in engineered hydro gels is increasingly used in tissue engineering and regenerative medicine. The transfer of nutrients, gases, and waste materials through these hydrogels is of utmost importance for cell viability and response, yet the translation of diffusion coefficients into practical guidelines is not well established. Here, we combined mathematical modeling, fluorescent recovery after photobleaching, and hydrogel diffusion experiments on cell culture inserts to provide a multiscale practical approach for diffusion. We observed a dampening effect of the hydrogel that slowed the response to concentration changes and the creation of a diffusion gradient in the hydrogel by media refreshment. Our designed model combined with measurements provides a practical point of reference for diffusion coefficients in real-world culture conditions, enabling more informed choices on hydrogel culture conditions. This model can be improved in the future to simulate more complicated intrinsic hydrogel properties and study the effects of secondary interactions on the diffusion of analytes through the hydrogel.

Original language	English
Pages (from-to)	604-612
Number of pages	9
Journal	Biomacromolecules
Volume	24
Issue number	2
Early online date	1 Feb 2023
DOIs	https://doi.org/10.1021/acs.biomac.2c00961
Publication status	Published - 13 Feb 2023

Keywords

SOLUTE DIFFUSION
TISSUE

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10.1021/acs.biomac.2c00961Licence: CC BY

Cite this

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title = "Optimization of Media Change Intervals through Hydrogels Using Mathematical Models",

abstract = "Three-dimensional cell culture in engineered hydro gels is increasingly used in tissue engineering and regenerative medicine. The transfer of nutrients, gases, and waste materials through these hydrogels is of utmost importance for cell viability and response, yet the translation of diffusion coefficients into practical guidelines is not well established. Here, we combined mathematical modeling, fluorescent recovery after photobleaching, and hydrogel diffusion experiments on cell culture inserts to provide a multiscale practical approach for diffusion. We observed a dampening effect of the hydrogel that slowed the response to concentration changes and the creation of a diffusion gradient in the hydrogel by media refreshment. Our designed model combined with measurements provides a practical point of reference for diffusion coefficients in real-world culture conditions, enabling more informed choices on hydrogel culture conditions. This model can be improved in the future to simulate more complicated intrinsic hydrogel properties and study the effects of secondary interactions on the diffusion of analytes through the hydrogel.",

keywords = "SOLUTE DIFFUSION, TISSUE",

author = "F.A.A. Ruiter and J. King and S. Swapnasrita and S. Giselbrecht and R. Truckenmuller and V.L.S. LaPointe and M.B. Baker and A. Carlier",

note = "Funding Information: This work is supported by the partners of Regenerative Medicine Crossing Borders (RegMed XB), a public-private partnership that uses regenerative medicine strategies to cure common chronic diseases. This collaboration project is financed by the Dutch Ministry of Economic Affairs by means of the PPP Allowance made available by the Top Sector Life Sciences & Health to stimulate public-private partnerships. This study has also received support from the European Union{\textquoteright}s Horizon 2020 research. Virtual Cell is supported by NIH Grant R24 GM137787 from the National Institute for General Medical Sciences. Publisher Copyright: {\textcopyright} 2023 The Authors. Published by American Chemical Society.",

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AU - Ruiter, F.A.A.

AU - King, J.

AU - Swapnasrita, S.

AU - Giselbrecht, S.

AU - Truckenmuller, R.

AU - LaPointe, V.L.S.

AU - Baker, M.B.

AU - Carlier, A.

N1 - Funding Information: This work is supported by the partners of Regenerative Medicine Crossing Borders (RegMed XB), a public-private partnership that uses regenerative medicine strategies to cure common chronic diseases. This collaboration project is financed by the Dutch Ministry of Economic Affairs by means of the PPP Allowance made available by the Top Sector Life Sciences & Health to stimulate public-private partnerships. This study has also received support from the European Union’s Horizon 2020 research. Virtual Cell is supported by NIH Grant R24 GM137787 from the National Institute for General Medical Sciences. Publisher Copyright: © 2023 The Authors. Published by American Chemical Society.

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Y1 - 2023/2/13

N2 - Three-dimensional cell culture in engineered hydro gels is increasingly used in tissue engineering and regenerative medicine. The transfer of nutrients, gases, and waste materials through these hydrogels is of utmost importance for cell viability and response, yet the translation of diffusion coefficients into practical guidelines is not well established. Here, we combined mathematical modeling, fluorescent recovery after photobleaching, and hydrogel diffusion experiments on cell culture inserts to provide a multiscale practical approach for diffusion. We observed a dampening effect of the hydrogel that slowed the response to concentration changes and the creation of a diffusion gradient in the hydrogel by media refreshment. Our designed model combined with measurements provides a practical point of reference for diffusion coefficients in real-world culture conditions, enabling more informed choices on hydrogel culture conditions. This model can be improved in the future to simulate more complicated intrinsic hydrogel properties and study the effects of secondary interactions on the diffusion of analytes through the hydrogel.

AB - Three-dimensional cell culture in engineered hydro gels is increasingly used in tissue engineering and regenerative medicine. The transfer of nutrients, gases, and waste materials through these hydrogels is of utmost importance for cell viability and response, yet the translation of diffusion coefficients into practical guidelines is not well established. Here, we combined mathematical modeling, fluorescent recovery after photobleaching, and hydrogel diffusion experiments on cell culture inserts to provide a multiscale practical approach for diffusion. We observed a dampening effect of the hydrogel that slowed the response to concentration changes and the creation of a diffusion gradient in the hydrogel by media refreshment. Our designed model combined with measurements provides a practical point of reference for diffusion coefficients in real-world culture conditions, enabling more informed choices on hydrogel culture conditions. This model can be improved in the future to simulate more complicated intrinsic hydrogel properties and study the effects of secondary interactions on the diffusion of analytes through the hydrogel.

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