Data

Dissolvable 3D printed moulds to augment architecture of melt electrowritten tubular scaffolds

Queensland University of Technology
Brooks-Richards, Trent ; Paxton, Naomi ; Allenby, Mark ; Woodruff, Mia
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ctx_ver=Z39.88-2004&rft_val_fmt=info%3Aofi%2Ffmt%3Akev%3Amtx%3Adc&rfr_id=info%3Asid%2FANDS&rft_id=info:doi10.25912/RDF_1650941419744&rft.title= Dissolvable 3D printed moulds to augment architecture of melt electrowritten tubular scaffolds &rft.identifier=10.25912/RDF_1650941419744&rft.publisher=Queensland University of Technology&rft.description=Melt electrowriting (MEW) is an additive manufacturing technique capable of fabricating microfibre thermoplastic scaffolds which is growing in popularity for tissue engineering applications. MEW is able to produce micron-scale biocompatible constructs through electrodynamic jet deposition with a high-level of control over fibre deposition. By depositing MEW fibres on a rotating cylindrical collector (mandrel), tubular constructs can be fabricated to mimic cylindrical anatomical tissues such as blood vessels. This proof-of-concept study leveraged the water solubility of PVA moulds to support tubular MEW scaffold fabrication in complex and patient-specific geometries. The dissolution rate of 3D printed PVA moulds was measured in water under constant stirring for 2 hours. MEW scaffolds were printed on then removed from either PVA or non-dissolvable PLA moulds, and the preservation of the MEW scaffold morphology was assessed. The non-dissolvable PLA moulds significantly damaged the MEW scaffolds while the PVA dissolvable moulds enabled the preservation the of scaffold geometry and could be separated from the mould with ease. This study demonstrated the capability for MEW to be leveraged as a technique for producing anatomically relevant tubular structures. The associated data is the Supplementary Materials for the following journal article: Brooks-Richards, Trent, Paxton, Naomi, Allenby, Mark, & Woodruff, Mia (2022) Dissolvable 3D printed PVA moulds for melt electrowriting tubular scaffolds with patient-specific geometry. Materials and Design, 215, Article number: 110466. &rft.creator=Brooks-Richards, Trent &rft.creator=Paxton, Naomi &rft.creator=Allenby, Mark &rft.creator=Woodruff, Mia &rft.date=2022&rft.edition=1&rft.relation=https://eprints.qut.edu.au/228424/&rft.coverage=153.015265,-27.452709&rft_rights=© Queensland University of Technology, 2022.&rft_rights=Creative Commons Attribution 3.0 http://creativecommons.org/licenses/by/4.0/&rft_subject=Biochemistry and cell biology&rft_subject=BIOLOGICAL SCIENCES&rft_subject=Engineering design&rft_subject=Engineering practice and education&rft_subject=ENGINEERING&rft_subject=Biomedical engineering&rft_subject=Biofabrication&rft.type=dataset&rft.language=English Access the data

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Creative Commons Attribution 3.0
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© Queensland University of Technology, 2022.

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This data is part of an ongoing study.

Contact Information

Postal Address:
Professor Mia Woodruff
Ph: +61 7 3138 7778

mia.woodruff@qut.edu.au

Full description

Melt electrowriting (MEW) is an additive manufacturing technique capable of fabricating microfibre thermoplastic scaffolds which is growing in popularity for tissue engineering applications. MEW is able to produce micron-scale biocompatible constructs through electrodynamic jet deposition with a high-level of control over fibre deposition. By depositing MEW fibres on a rotating cylindrical collector (mandrel), tubular constructs can be fabricated to mimic cylindrical anatomical tissues such as blood vessels.

This proof-of-concept study leveraged the water solubility of PVA moulds to support tubular MEW scaffold fabrication in complex and patient-specific geometries. The dissolution rate of 3D printed PVA moulds was measured in water under constant stirring for 2 hours. MEW scaffolds were printed on then removed from either PVA or non-dissolvable PLA moulds, and the preservation of the MEW scaffold morphology was assessed. The non-dissolvable PLA moulds significantly damaged the MEW scaffolds while the PVA dissolvable moulds enabled the preservation the of scaffold geometry and could be separated from the mould with ease. This study demonstrated the capability for MEW to be leveraged as a technique for producing anatomically relevant tubular structures.

The associated data is the Supplementary Materials for the following journal article:

Brooks-Richards, Trent, Paxton, Naomi, Allenby, Mark, & Woodruff, Mia (2022) Dissolvable 3D printed PVA moulds for melt electrowriting tubular scaffolds with patient-specific geometry. Materials and Design, 215, Article number: 110466.

Data time period: 17 07 2021 to 30 08 2021

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153.015265,-27.452709

153.015265,-27.452709

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