Shaping Synthetic Multicellular and Complex Multimaterial Tissues via Embedded Extrusion-Volumetric Printing of Microgels

Davide Ribezzi; Marième Gueye; Sammy Florczak; Franziska Dusi; Dieuwke de Vos; Francesca Manente; Andreas Hierholzer; Martin Fussenegger; Massimiliano Caiazzo; Torsten Blunk; Jos Malda; Riccardo Levato

doi:10.1002/adma.202301673

Shaping Synthetic Multicellular and Complex Multimaterial Tissues via Embedded Extrusion-Volumetric Printing of Microgels

Davide Ribezzi, Marième Gueye, Sammy Florczak, Franziska Dusi, Dieuwke de Vos, Francesca Manente, Andreas Hierholzer, Martin Fussenegger, Massimiliano Caiazzo, Torsten Blunk, Jos Malda, Riccardo Levato^*

^*Corresponding author for this work

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

Abstract

In living tissues, cells express their functions following complex signals from their surrounding microenvironment. Capturing both hierarchical architectures at the micro- and macroscale, and anisotropic cell patterning remains a major challenge in bioprinting, and a bottleneck toward creating physiologically-relevant models. Addressing this limitation, a novel technique is introduced, termed Embedded Extrusion-Volumetric Printing (EmVP), converging extrusion-bioprinting and layer-less, ultra-fast volumetric bioprinting, allowing spatially pattern multiple inks/cell types. Light-responsive microgels are developed for the first time as bioresins (µResins) for light-based volumetric bioprinting, providing a microporous environment permissive for cell homing and self-organization. Tuning the mechanical and optical properties of gelatin-based microparticles enables their use as support bath for suspended extrusion printing, in which features containing high cell densities can be easily introduced. µResins can be sculpted within seconds with tomographic light projections into centimeter-scale, granular hydrogel-based, convoluted constructs. Interstitial microvoids enhanced differentiation of multiple stem/progenitor cells (vascular, mesenchymal, neural), otherwise not possible with conventional bulk hydrogels. As proof-of-concept, EmVP is applied to create complex synthetic biology-inspired intercellular communication models, where adipocyte differentiation is regulated by optogenetic-engineered pancreatic cells. Overall, EmVP offers new avenues for producing regenerative grafts with biological functionality, and for developing engineered living systems and (metabolic) disease models.

Original language	English
Article number	2301673
Number of pages	18
Journal	Advanced Materials
Volume	35
Issue number	36
DOIs	https://doi.org/10.1002/adma.202301673
Publication status	Published - 7 Sept 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 program (grant agreement no. 949 806, VOLUME‐BIO) and from the European's Union's Horizon 2020 research and innovation programme under grant agreement no 964 497 (ENLIGHT). R.L. and J.M. acknowledge the funding from the ReumaNederland (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 (NWA.1228.192.105). T.B. acknowledges the funding from the Deutsche Forschungsgemeinschaft (DFG, German Research Foundation), Project number 326 998 133, TRR 225 (subproject C02).

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

Keywords

biofabrication
volumetric bioprinting
FRESH printing
synthetic biology
optogenetics

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Advanced Materials - 2023 - RibezziFinal published version, 6.27 MBLicence: CC BY

Cite this

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title = "Shaping Synthetic Multicellular and Complex Multimaterial Tissues via Embedded Extrusion-Volumetric Printing of Microgels",

abstract = "In living tissues, cells express their functions following complex signals from their surrounding microenvironment. Capturing both hierarchical architectures at the micro- and macroscale, and anisotropic cell patterning remains a major challenge in bioprinting, and a bottleneck toward creating physiologically-relevant models. Addressing this limitation, a novel technique is introduced, termed Embedded Extrusion-Volumetric Printing (EmVP), converging extrusion-bioprinting and layer-less, ultra-fast volumetric bioprinting, allowing spatially pattern multiple inks/cell types. Light-responsive microgels are developed for the first time as bioresins (µResins) for light-based volumetric bioprinting, providing a microporous environment permissive for cell homing and self-organization. Tuning the mechanical and optical properties of gelatin-based microparticles enables their use as support bath for suspended extrusion printing, in which features containing high cell densities can be easily introduced. µResins can be sculpted within seconds with tomographic light projections into centimeter-scale, granular hydrogel-based, convoluted constructs. Interstitial microvoids enhanced differentiation of multiple stem/progenitor cells (vascular, mesenchymal, neural), otherwise not possible with conventional bulk hydrogels. As proof-of-concept, EmVP is applied to create complex synthetic biology-inspired intercellular communication models, where adipocyte differentiation is regulated by optogenetic-engineered pancreatic cells. Overall, EmVP offers new avenues for producing regenerative grafts with biological functionality, and for developing engineered living systems and (metabolic) disease models.",

keywords = "biofabrication, volumetric bioprinting, FRESH printing, synthetic biology, optogenetics",

author = "Davide Ribezzi and Mari{\`e}me Gueye and Sammy Florczak and Franziska Dusi and {de Vos}, Dieuwke and Francesca Manente and Andreas Hierholzer and Martin Fussenegger and Massimiliano Caiazzo and Torsten Blunk and Jos Malda 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 program (grant agreement no. 949 806, VOLUME‐BIO) and from the European's Union's Horizon 2020 research and innovation programme under grant agreement no 964 497 (ENLIGHT). R.L. and J.M. acknowledge the funding from the ReumaNederland (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 (NWA.1228.192.105). T.B. acknowledges the funding from the Deutsche Forschungsgemeinschaft (DFG, German Research Foundation), Project number 326 998 133, TRR 225 (subproject C02). Publisher Copyright: {\textcopyright} 2023 The Authors. Advanced Materials published by Wiley-VCH GmbH.",

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doi = "10.1002/adma.202301673",

language = "English",

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AU - Ribezzi, Davide

AU - Gueye, Marième

AU - Florczak, Sammy

AU - Dusi, Franziska

AU - de Vos, Dieuwke

AU - Manente, Francesca

AU - Hierholzer, Andreas

AU - Fussenegger, Martin

AU - Caiazzo, Massimiliano

AU - Blunk, Torsten

AU - Malda, Jos

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 program (grant agreement no. 949 806, VOLUME‐BIO) and from the European's Union's Horizon 2020 research and innovation programme under grant agreement no 964 497 (ENLIGHT). R.L. and J.M. acknowledge the funding from the ReumaNederland (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 (NWA.1228.192.105). T.B. acknowledges the funding from the Deutsche Forschungsgemeinschaft (DFG, German Research Foundation), Project number 326 998 133, TRR 225 (subproject C02). Publisher Copyright: © 2023 The Authors. Advanced Materials published by Wiley-VCH GmbH.

PY - 2023/9/7

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N2 - In living tissues, cells express their functions following complex signals from their surrounding microenvironment. Capturing both hierarchical architectures at the micro- and macroscale, and anisotropic cell patterning remains a major challenge in bioprinting, and a bottleneck toward creating physiologically-relevant models. Addressing this limitation, a novel technique is introduced, termed Embedded Extrusion-Volumetric Printing (EmVP), converging extrusion-bioprinting and layer-less, ultra-fast volumetric bioprinting, allowing spatially pattern multiple inks/cell types. Light-responsive microgels are developed for the first time as bioresins (µResins) for light-based volumetric bioprinting, providing a microporous environment permissive for cell homing and self-organization. Tuning the mechanical and optical properties of gelatin-based microparticles enables their use as support bath for suspended extrusion printing, in which features containing high cell densities can be easily introduced. µResins can be sculpted within seconds with tomographic light projections into centimeter-scale, granular hydrogel-based, convoluted constructs. Interstitial microvoids enhanced differentiation of multiple stem/progenitor cells (vascular, mesenchymal, neural), otherwise not possible with conventional bulk hydrogels. As proof-of-concept, EmVP is applied to create complex synthetic biology-inspired intercellular communication models, where adipocyte differentiation is regulated by optogenetic-engineered pancreatic cells. Overall, EmVP offers new avenues for producing regenerative grafts with biological functionality, and for developing engineered living systems and (metabolic) disease models.

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KW - biofabrication

KW - volumetric bioprinting

KW - FRESH printing

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KW - optogenetics

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ER -

Shaping Synthetic Multicellular and Complex Multimaterial Tissues via Embedded Extrusion-Volumetric Printing of Microgels

Abstract

Bibliographical note

Keywords

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