Spatial-Selective Volumetric 4D Printing and Single-Photon Grafting of Biomolecules within Centimeter-Scale Hydrogels via Tomographic Manufacturing

Marc Falandt; Paulina Nuñez Bernal; Oksana Dudaryeva; Sammy Florczak; Gabriel Größbacher; Matthias Schweiger; Alessia Longoni; Coralie Greant; Marisa Assunção; Olaf Nijssen; Sandra van Vlierberghe; Jos Malda; Tina Vermonden; Riccardo Levato

doi:10.1002/admt.202300026

Spatial-Selective Volumetric 4D Printing and Single-Photon Grafting of Biomolecules within Centimeter-Scale Hydrogels via Tomographic Manufacturing

Marc Falandt
, Paulina Nuñez Bernal
, Oksana Dudaryeva
, Sammy Florczak
, Gabriel Größbacher
, Matthias Schweiger
, Alessia Longoni
, Coralie Greant
, Marisa Assunção
, Olaf Nijssen
, Sandra van Vlierberghe
, Jos Malda
, Tina Vermonden
, Riccardo Levato^*

^*Corresponding author for this work

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

Abstract

Conventional additive manufacturing and biofabrication techniques are unable to edit the chemicophysical properties of the printed object postprinting. Herein, a new approach is presented, leveraging light-based volumetric printing as a tool to spatially pattern any biomolecule of interest in custom-designed geometries even across large, centimeter-scale hydrogels. As biomaterial platform, a gelatin norbornene resin is developed with tunable mechanical properties suitable for tissue engineering applications. The resin can be volumetrically printed within seconds at high resolution (23.68 ± 10.75 µm). Thiol–ene click chemistry allows on-demand photografting of thiolated compounds postprinting, from small to large (bio)molecules (e.g., fluorescent dyes or growth factors). These molecules are covalently attached into printed structures using volumetric light projections, forming 3D geometries with high spatiotemporal control and ≈50 µm resolution. As a proof of concept, vascular endothelial growth factor is locally photografted into a bioprinted construct and demonstrated region-dependent enhanced adhesion and network formation of endothelial cells. This technology paves the way toward the precise spatiotemporal biofunctionalization and modification of the chemical composition of (bio)printed constructs to better guide cell behavior, build bioactive cue gradients. Moreover, it opens future possibilities for 4D printing to mimic the dynamic changes in morphogen presentation natively experienced in biological tissues.

Original language	English
Article number	2300026
Number of pages	15
Journal	Advanced Materials Technologies
Volume	8
Issue number	15
Early online date	23 May 2023
DOIs	https://doi.org/10.1002/admt.202300026
Publication status	Published - 11 Aug 2023

Bibliographical note

Funding Information:
This project received funding from the European Research Council (ERC) under the European Union's Horizon 2020 research and innovation programme (Grant Agreement No. 949806, VOLUME‐BIO). J.M. and R.L. acknowledge the funding from the ReumaNederland (Grant Nos. LLP‐12, LLP22 and 19‐1‐207 MINIJOINT) and the Gravitation Program “Materials Driven Regeneration,” funded by the Netherlands Organization for Scientific Research (024.003.013). R.L. also acknowledges funding from the NWA‐Ideeëngenerator programme of the Netherlands Organization for Scientific Research (Grant No. NWA.1228.192.105). C.G. and S.v.V. acknowledge funding from the FWO EOS (Grant Agreement No. 40007548) and the FWO Hercules (Grant Agreement No. I003922N). The authors would like to acknowledge Riccardo Rizzo and Marcy Zenobi‐Wong for their advice with the gelatin characterization. The authors would like to thank Rousselot Biomedical for kindly providing the raw, low‐endotoxin gelatin materials, and Daimon J. Hall from Carbon and Neon for his support with scientific illustrations.

Publisher Copyright:
© 2023 The Authors. Advanced Materials Technologies published by Wiley-VCH GmbH.

Funding

This project received funding from the European Research Council (ERC) under the European Union's Horizon 2020 research and innovation programme (Grant Agreement No. 949806, VOLUME‐BIO). J.M. and R.L. acknowledge the funding from the ReumaNederland (Grant Nos. LLP‐12, LLP22 and 19‐1‐207 MINIJOINT) and the Gravitation Program “Materials Driven Regeneration,” funded by the Netherlands Organization for Scientific Research (024.003.013). R.L. also acknowledges funding from the NWA‐Ideeëngenerator programme of the Netherlands Organization for Scientific Research (Grant No. NWA.1228.192.105). C.G. and S.v.V. acknowledge funding from the FWO EOS (Grant Agreement No. 40007548) and the FWO Hercules (Grant Agreement No. I003922N). The authors would like to acknowledge Riccardo Rizzo and Marcy Zenobi‐Wong for their advice with the gelatin characterization. The authors would like to thank Rousselot Biomedical for kindly providing the raw, low‐endotoxin gelatin materials, and Daimon J. Hall from Carbon and Neon for his support with scientific illustrations.

Funders	Funder number
European Research Council
Fonds Wetenschappelijk Onderzoek	40007548, I003922N
Nederlandse Organisatie voor Wetenschappelijk Onderzoek	024.003.013, NWA.1228.192.105
Horizon 2020	LLP-12, 949806, 19‐1‐207 MINIJOINT

Keywords

4D printing
biofabrication
light-based printing
photopatterning
volumetric additive manufacturing

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Adv Materials Technologies - 2023 - FalandtFinal published version, 4.05 MBLicence: CC BY

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Falandt, M., Bernal, P. N., Dudaryeva, O., Florczak, S., Größbacher, G., Schweiger, M., Longoni, A., Greant, C., Assunção, M., Nijssen, O., van Vlierberghe, S., Malda, J., Vermonden, T., & Levato, R. (2023). Spatial-Selective Volumetric 4D Printing and Single-Photon Grafting of Biomolecules within Centimeter-Scale Hydrogels via Tomographic Manufacturing. Advanced Materials Technologies, 8(15), Article 2300026. https://doi.org/10.1002/admt.202300026

@article{1516c20fa7a246d28da685f303638f7c,

title = "Spatial-Selective Volumetric 4D Printing and Single-Photon Grafting of Biomolecules within Centimeter-Scale Hydrogels via Tomographic Manufacturing",

abstract = "Conventional additive manufacturing and biofabrication techniques are unable to edit the chemicophysical properties of the printed object postprinting. Herein, a new approach is presented, leveraging light-based volumetric printing as a tool to spatially pattern any biomolecule of interest in custom-designed geometries even across large, centimeter-scale hydrogels. As biomaterial platform, a gelatin norbornene resin is developed with tunable mechanical properties suitable for tissue engineering applications. The resin can be volumetrically printed within seconds at high resolution (23.68 ± 10.75 µm). Thiol–ene click chemistry allows on-demand photografting of thiolated compounds postprinting, from small to large (bio)molecules (e.g., fluorescent dyes or growth factors). These molecules are covalently attached into printed structures using volumetric light projections, forming 3D geometries with high spatiotemporal control and ≈50 µm resolution. As a proof of concept, vascular endothelial growth factor is locally photografted into a bioprinted construct and demonstrated region-dependent enhanced adhesion and network formation of endothelial cells. This technology paves the way toward the precise spatiotemporal biofunctionalization and modification of the chemical composition of (bio)printed constructs to better guide cell behavior, build bioactive cue gradients. Moreover, it opens future possibilities for 4D printing to mimic the dynamic changes in morphogen presentation natively experienced in biological tissues.",

keywords = "4D printing, biofabrication, light-based printing, photopatterning, volumetric additive manufacturing",

author = "Marc Falandt and Bernal, \{Paulina Nu{\~n}ez\} and Oksana Dudaryeva and Sammy Florczak and Gabriel Gr{\"o}{\ss}bacher and Matthias Schweiger and Alessia Longoni and Coralie Greant and Marisa Assun{\c c}{\~a}o and Olaf Nijssen and \{van Vlierberghe\}, Sandra and Jos Malda and Tina Vermonden and Riccardo Levato",

note = "Funding Information: This project received funding from the European Research Council (ERC) under the European Union's Horizon 2020 research and innovation programme (Grant Agreement No. 949806, VOLUME‐BIO). J.M. and R.L. acknowledge the funding from the ReumaNederland (Grant Nos. LLP‐12, LLP22 and 19‐1‐207 MINIJOINT) and the Gravitation Program “Materials Driven Regeneration,” funded by the Netherlands Organization for Scientific Research (024.003.013). R.L. also acknowledges funding from the NWA‐Idee{\"e}ngenerator programme of the Netherlands Organization for Scientific Research (Grant No. NWA.1228.192.105). C.G. and S.v.V. acknowledge funding from the FWO EOS (Grant Agreement No. 40007548) and the FWO Hercules (Grant Agreement No. I003922N). The authors would like to acknowledge Riccardo Rizzo and Marcy Zenobi‐Wong for their advice with the gelatin characterization. The authors would like to thank Rousselot Biomedical for kindly providing the raw, low‐endotoxin gelatin materials, and Daimon J. Hall from Carbon and Neon for his support with scientific illustrations. Publisher Copyright: {\textcopyright} 2023 The Authors. Advanced Materials Technologies published by Wiley-VCH GmbH.",

year = "2023",

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doi = "10.1002/admt.202300026",

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Falandt, M, Bernal, PN, Dudaryeva, O, Florczak, S, Größbacher, G, Schweiger, M, Longoni, A, Greant, C, Assunção, M, Nijssen, O, van Vlierberghe, S, Malda, J , Vermonden, T & Levato, R 2023, 'Spatial-Selective Volumetric 4D Printing and Single-Photon Grafting of Biomolecules within Centimeter-Scale Hydrogels via Tomographic Manufacturing', Advanced Materials Technologies, vol. 8, no. 15, 2300026. https://doi.org/10.1002/admt.202300026

TY - JOUR

T1 - Spatial-Selective Volumetric 4D Printing and Single-Photon Grafting of Biomolecules within Centimeter-Scale Hydrogels via Tomographic Manufacturing

AU - Falandt, Marc

AU - Bernal, Paulina Nuñez

AU - Dudaryeva, Oksana

AU - Florczak, Sammy

AU - Größbacher, Gabriel

AU - Schweiger, Matthias

AU - Longoni, Alessia

AU - Greant, Coralie

AU - Assunção, Marisa

AU - Nijssen, Olaf

AU - van Vlierberghe, Sandra

AU - Malda, Jos

AU - Vermonden, Tina

AU - Levato, Riccardo

N1 - Funding Information: This project received funding from the European Research Council (ERC) under the European Union's Horizon 2020 research and innovation programme (Grant Agreement No. 949806, VOLUME‐BIO). J.M. and R.L. acknowledge the funding from the ReumaNederland (Grant Nos. LLP‐12, LLP22 and 19‐1‐207 MINIJOINT) and the Gravitation Program “Materials Driven Regeneration,” funded by the Netherlands Organization for Scientific Research (024.003.013). R.L. also acknowledges funding from the NWA‐Ideeëngenerator programme of the Netherlands Organization for Scientific Research (Grant No. NWA.1228.192.105). C.G. and S.v.V. acknowledge funding from the FWO EOS (Grant Agreement No. 40007548) and the FWO Hercules (Grant Agreement No. I003922N). The authors would like to acknowledge Riccardo Rizzo and Marcy Zenobi‐Wong for their advice with the gelatin characterization. The authors would like to thank Rousselot Biomedical for kindly providing the raw, low‐endotoxin gelatin materials, and Daimon J. Hall from Carbon and Neon for his support with scientific illustrations. Publisher Copyright: © 2023 The Authors. Advanced Materials Technologies published by Wiley-VCH GmbH.

PY - 2023/8/11

Y1 - 2023/8/11

N2 - Conventional additive manufacturing and biofabrication techniques are unable to edit the chemicophysical properties of the printed object postprinting. Herein, a new approach is presented, leveraging light-based volumetric printing as a tool to spatially pattern any biomolecule of interest in custom-designed geometries even across large, centimeter-scale hydrogels. As biomaterial platform, a gelatin norbornene resin is developed with tunable mechanical properties suitable for tissue engineering applications. The resin can be volumetrically printed within seconds at high resolution (23.68 ± 10.75 µm). Thiol–ene click chemistry allows on-demand photografting of thiolated compounds postprinting, from small to large (bio)molecules (e.g., fluorescent dyes or growth factors). These molecules are covalently attached into printed structures using volumetric light projections, forming 3D geometries with high spatiotemporal control and ≈50 µm resolution. As a proof of concept, vascular endothelial growth factor is locally photografted into a bioprinted construct and demonstrated region-dependent enhanced adhesion and network formation of endothelial cells. This technology paves the way toward the precise spatiotemporal biofunctionalization and modification of the chemical composition of (bio)printed constructs to better guide cell behavior, build bioactive cue gradients. Moreover, it opens future possibilities for 4D printing to mimic the dynamic changes in morphogen presentation natively experienced in biological tissues.

AB - Conventional additive manufacturing and biofabrication techniques are unable to edit the chemicophysical properties of the printed object postprinting. Herein, a new approach is presented, leveraging light-based volumetric printing as a tool to spatially pattern any biomolecule of interest in custom-designed geometries even across large, centimeter-scale hydrogels. As biomaterial platform, a gelatin norbornene resin is developed with tunable mechanical properties suitable for tissue engineering applications. The resin can be volumetrically printed within seconds at high resolution (23.68 ± 10.75 µm). Thiol–ene click chemistry allows on-demand photografting of thiolated compounds postprinting, from small to large (bio)molecules (e.g., fluorescent dyes or growth factors). These molecules are covalently attached into printed structures using volumetric light projections, forming 3D geometries with high spatiotemporal control and ≈50 µm resolution. As a proof of concept, vascular endothelial growth factor is locally photografted into a bioprinted construct and demonstrated region-dependent enhanced adhesion and network formation of endothelial cells. This technology paves the way toward the precise spatiotemporal biofunctionalization and modification of the chemical composition of (bio)printed constructs to better guide cell behavior, build bioactive cue gradients. Moreover, it opens future possibilities for 4D printing to mimic the dynamic changes in morphogen presentation natively experienced in biological tissues.

KW - 4D printing

KW - biofabrication

KW - light-based printing

KW - photopatterning

KW - volumetric additive manufacturing

UR - https://www.scopus.com/pages/publications/85159898084

U2 - 10.1002/admt.202300026

DO - 10.1002/admt.202300026

M3 - Article

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VL - 8

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ER -

Spatial-Selective Volumetric 4D Printing and Single-Photon Grafting of Biomolecules within Centimeter-Scale Hydrogels via Tomographic Manufacturing

Abstract

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Keywords

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