Synergizing Algorithmic Design, Photoclick Chemistry and Multi‐Material Volumetric Printing for Accelerating Complex Shape Engineering

Parth Chansoria; Dominic Rütsche; Anny Wang; Hao Liu; Davide D'Angella; Riccardo Rizzo; Amelia Hasenauer; Patrick Weber; Wanwan Qiu; Nafeesah Bte Mohamed Ibrahim; Nina Korshunova; Xiao‐Hua Qin; Marcy Zenobi‐Wong

doi:10.1002/advs.202300912

Advanced Science (Sep 2023)

Synergizing Algorithmic Design, Photoclick Chemistry and Multi‐Material Volumetric Printing for Accelerating Complex Shape Engineering

Parth Chansoria,
Dominic Rütsche,
Anny Wang,
Hao Liu,
Davide D'Angella,
Riccardo Rizzo,
Amelia Hasenauer,
Patrick Weber,
Wanwan Qiu,
Nafeesah Bte Mohamed Ibrahim,
Nina Korshunova,
Xiao‐Hua Qin,
Marcy Zenobi‐Wong

Affiliations

Parth Chansoria: Department of Health Sciences and Technology ETH Zürich University Zürich 8092 Switzerland
Dominic Rütsche: Department of Health Sciences and Technology ETH Zürich University Zürich 8092 Switzerland
Anny Wang: Department of Health Sciences and Technology ETH Zürich University Zürich 8092 Switzerland
Hao Liu: Department of Health Sciences and Technology ETH Zürich University Zürich 8092 Switzerland
Davide D'Angella: Hyperganic Group GmbH 80799 Munich Germany
Riccardo Rizzo: Department of Health Sciences and Technology ETH Zürich University Zürich 8092 Switzerland
Amelia Hasenauer: Department of Health Sciences and Technology ETH Zürich University Zürich 8092 Switzerland
Patrick Weber: Department of Health Sciences and Technology ETH Zürich University Zürich 8092 Switzerland
Wanwan Qiu: Department of Health Sciences and Technology ETH Zürich University Zürich 8092 Switzerland
Nafeesah Bte Mohamed Ibrahim: Department of Health Sciences and Technology ETH Zürich University Zürich 8092 Switzerland
Nina Korshunova: Hyperganic Group GmbH 80799 Munich Germany
Xiao‐Hua Qin: Department of Health Sciences and Technology ETH Zürich University Zürich 8092 Switzerland
Marcy Zenobi‐Wong: Department of Health Sciences and Technology ETH Zürich University Zürich 8092 Switzerland

DOI: https://doi.org/10.1002/advs.202300912
Journal volume & issue: Vol. 10, no. 26
pp. n/a – n/a

Abstract

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Abstract The field of biomedical design and manufacturing has been rapidly evolving, with implants and grafts featuring complex 3D design constraints and materials distributions. By combining a new coding‐based design and modeling approach with high‐throughput volumetric printing, a new approach is demonstrated to transform the way complex shapes are designed and fabricated for biomedical applications. Here, an algorithmic voxel‐based approach is used that can rapidly generate a large design library of porous structures, auxetic meshes and cylinders, or perfusable constructs. By deploying finite cell modeling within the algorithmic design framework, large arrays of selected auxetic designs can be computationally modeled. Finally, the design schemes are used in conjunction with new approaches for multi‐material volumetric printing based on thiol‐ene photoclick chemistry to rapidly fabricate complex heterogeneous shapes. Collectively, the new design, modeling and fabrication techniques can be used toward a wide spectrum of products such as actuators, biomedical implants and grafts, or tissue and disease models.

Published in Advanced Science

ISSN: 2198-3844 (Online)
Publisher: Wiley
Country of publisher: Germany
LCC subjects: Science
Website: https://onlinelibrary.wiley.com/journal/21983844

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