Organic Ink Multi‐Material 3D Printing of Sustainable Soft Systems

Andreas Heiden; Michael Schardax; Michael Hüttenberger; David Preninger; Guoyong Mao; David Schiller; Martin Kaltenbrunner

doi:10.1002/adma.202409403

Organic Ink Multi‐Material 3D Printing of Sustainable Soft Systems

Andreas Heiden
, Michael Schardax
, Michael Hüttenberger
, David Preninger
, Guoyong Mao
, David Schiller
, Martin Kaltenbrunner

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

Abstract

Drawing inspiration from nature, soft materials are at the core of a transformation toward adaptive and responsive engineered systems, capable of conquering demanding terrain and safe when interacting with biological life. Despite recent advances in 3D printing of soft materials, researchers are still far from being able to print complex soft systems where a multitude of different components need to work together symbiotically. Closing this gap necessitates a platform that unites diverse materials into one synergetic process. Here, a multi‐material printing system is presented, combining gelatin‐based hydrogels with a new biodegradable support material. This organic ink maintains up to 60° overhang and is printable over gaps to structurally support the main biogel body, while triggered dissolution enables its selective removal and the formation of internal cavities. Therefore, the creation of vascular networks, tunable …

Original language	English
Article number	2409403
Pages (from-to)	2409403
Number of pages	1
Journal	Advanced Materials
Volume	37
Issue number	4
DOIs	https://doi.org/10.1002/adma.202409403
Publication status	Published - Nov 2024

Fields of science

103 Physics, Astronomy

JKU Focus areas

Sustainable Development: Responsible Technologies and Management

Access to Document

10.1002/adma.202409403

Cite this

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title = "Organic Ink Multi‐Material 3D Printing of Sustainable Soft Systems",

abstract = "Drawing inspiration from nature, soft materials are at the core of a transformation toward adaptive and responsive engineered systems, capable of conquering demanding terrain and safe when interacting with biological life. Despite recent advances in 3D printing of soft materials, researchers are still far from being able to print complex soft systems where a multitude of different components need to work together symbiotically. Closing this gap necessitates a platform that unites diverse materials into one synergetic process. Here, a multi‐material printing system is presented, combining gelatin‐based hydrogels with a new biodegradable support material. This organic ink maintains up to 60° overhang and is printable over gaps to structurally support the main biogel body, while triggered dissolution enables its selective removal and the formation of internal cavities. Therefore, the creation of vascular networks, tunable …",

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AU - Heiden, Andreas

AU - Schardax, Michael

AU - Hüttenberger, Michael

AU - Preninger, David

AU - Mao, Guoyong

AU - Schiller, David

AU - Kaltenbrunner, Martin

PY - 2024/11

Y1 - 2024/11

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AB - Drawing inspiration from nature, soft materials are at the core of a transformation toward adaptive and responsive engineered systems, capable of conquering demanding terrain and safe when interacting with biological life. Despite recent advances in 3D printing of soft materials, researchers are still far from being able to print complex soft systems where a multitude of different components need to work together symbiotically. Closing this gap necessitates a platform that unites diverse materials into one synergetic process. Here, a multi‐material printing system is presented, combining gelatin‐based hydrogels with a new biodegradable support material. This organic ink maintains up to 60° overhang and is printable over gaps to structurally support the main biogel body, while triggered dissolution enables its selective removal and the formation of internal cavities. Therefore, the creation of vascular networks, tunable …

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Organic Ink Multi‐Material 3D Printing of Sustainable Soft Systems

Abstract

Fields of science

JKU Focus areas

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