Screening of modular supramolecular star polymers for 3D printing of biomedical devices

Lewis R. Hart; Adja B.R. Touré; Robert Owen; Nur R.E. Putri; Richard J.M. Hague; Morgan R. Alexander; Felicity R.A.J. Rose; Zuoxin Zhou; Derek J. Irvine; Laura Ruiz-Cantu; Lyudmila Turyanska; Yinfeng He; Wayne Hayes; Ricky D. Wildman

doi:10.1016/j.mtcomm.2025.112206

Screening of modular supramolecular star polymers for 3D printing of biomedical devices

Lewis R. Hart, Adja B.R. Touré, Robert Owen, Nur R.E. Putri, Richard J.M. Hague, Morgan R. Alexander, Felicity R.A.J. Rose, Zuoxin Zhou, Derek J. Irvine, Laura Ruiz-Cantu, Lyudmila Turyanska, Yinfeng He, Wayne Hayes, Ricky D. Wildman

Research output: Journal Publication › Article › peer-review

Abstract

Identifying suitable materials for additive manufacturing and 3D printing is a challenging task and there is a need to streamline the processes to achieve more rapid adoption of new feedstocks. We have developed a process of using modular supramolecular polymers where individual moieties can be modified in order to achieve a variance in properties. We synthesised a library of 64 polymers and performed a systematic sequence of screening steps to identify preferred candidates for an exemplar printing modality and application. The library was screened for materials amenable to inkjet based 3D printing, then refined to those that had mechanical and biological performance suitable for use in articular cartilage repair, and supported chondrocyte growth. The lead candidate was fabricated into macroscopic architectures with intricate designs, including structure of knee cartilage as a demonstrator of potential application. This strategy for screening materials for specific applications could accelerate the translation of new materials for additive manufacture of novel devices.

Original language	English
Article number	112206
Journal	Materials Today Communications
Volume	45
DOIs	https://doi.org/10.1016/j.mtcomm.2025.112206
Publication status	Published - Apr 2025

Keywords

Additive manufacturing
Biomaterial discovery
Cartilage
Material screening
Modular polymers
Regenerative medicine

ASJC Scopus subject areas

General Materials Science
Mechanics of Materials
Materials Chemistry

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10.1016/j.mtcomm.2025.112206

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Hart, L. R., Touré, A. B. R., Owen, R., Putri, N. R. E., Hague, R. J. M., Alexander, M. R., Rose, F. R. A. J., Zhou, Z., Irvine, D. J., Ruiz-Cantu, L., Turyanska, L., He, Y., Hayes, W., & Wildman, R. D. (2025). Screening of modular supramolecular star polymers for 3D printing of biomedical devices. Materials Today Communications, 45, Article 112206. https://doi.org/10.1016/j.mtcomm.2025.112206

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abstract = "Identifying suitable materials for additive manufacturing and 3D printing is a challenging task and there is a need to streamline the processes to achieve more rapid adoption of new feedstocks. We have developed a process of using modular supramolecular polymers where individual moieties can be modified in order to achieve a variance in properties. We synthesised a library of 64 polymers and performed a systematic sequence of screening steps to identify preferred candidates for an exemplar printing modality and application. The library was screened for materials amenable to inkjet based 3D printing, then refined to those that had mechanical and biological performance suitable for use in articular cartilage repair, and supported chondrocyte growth. The lead candidate was fabricated into macroscopic architectures with intricate designs, including structure of knee cartilage as a demonstrator of potential application. This strategy for screening materials for specific applications could accelerate the translation of new materials for additive manufacture of novel devices.",

keywords = "Additive manufacturing, Biomaterial discovery, Cartilage, Material screening, Modular polymers, Regenerative medicine",

author = "Hart, {Lewis R.} and Tour{\'e}, {Adja B.R.} and Robert Owen and Putri, {Nur R.E.} and Hague, {Richard J.M.} and Alexander, {Morgan R.} and Rose, {Felicity R.A.J.} and Zuoxin Zhou and Irvine, {Derek J.} and Laura Ruiz-Cantu and Lyudmila Turyanska and Yinfeng He and Wayne Hayes and Wildman, {Ricky D.}",

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year = "2025",

month = apr,

doi = "10.1016/j.mtcomm.2025.112206",

language = "English",

volume = "45",

journal = "Materials Today Communications",

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AU - Rose, Felicity R.A.J.

AU - Zhou, Zuoxin

AU - Irvine, Derek J.

AU - Ruiz-Cantu, Laura

AU - Turyanska, Lyudmila

AU - He, Yinfeng

AU - Hayes, Wayne

AU - Wildman, Ricky D.

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AB - Identifying suitable materials for additive manufacturing and 3D printing is a challenging task and there is a need to streamline the processes to achieve more rapid adoption of new feedstocks. We have developed a process of using modular supramolecular polymers where individual moieties can be modified in order to achieve a variance in properties. We synthesised a library of 64 polymers and performed a systematic sequence of screening steps to identify preferred candidates for an exemplar printing modality and application. The library was screened for materials amenable to inkjet based 3D printing, then refined to those that had mechanical and biological performance suitable for use in articular cartilage repair, and supported chondrocyte growth. The lead candidate was fabricated into macroscopic architectures with intricate designs, including structure of knee cartilage as a demonstrator of potential application. This strategy for screening materials for specific applications could accelerate the translation of new materials for additive manufacture of novel devices.

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Screening of modular supramolecular star polymers for 3D printing of biomedical devices

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Keywords

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