Hybrid additive manufacturing system for zonal plasma-treated scaffolds
Hybrid additive manufacturing system for zonal plasma-treated scaffolds
Producing synthetic scaffolds with adequate physical, chemical, and biological properties remains a challenge for tissue engineering. Internal architecture, surface chemistry, and material properties have strong impact on the cell biological behavior. This requires sophisticated systems not only able to process multiple materials with different characteristics, creating fully interconnected 3D porous structures with high reproducibility and accuracy, but also able to modify their properties during the fabrication process. This study introduces a novel additive manufacturing system comprising a multiprinting unit (screw-assisted and pressure-assisted printing heads) together with a plasma unit that enables the surface modification of printed scaffolds. Poly(ɛ-caprolactone) scaffolds with a lay-down pattern of 0/90° were fabricated using the screw-assisted printing head and a plasma jet unit used to uniformly modify each layer, a specific region of each layer during the printing process or the external surface of the printed scaffolds. Scaffolds were produced using different plasma exposure times and different distance between the plasma head and the printed layer, and fixed printing conditions. Produced scaffolds were morphologically, mechanically, chemically, and biologically characterized. Results show that the distance between the plasma head and the printed material has no significant effect on the mechanical properties, whereas the increase of the plasma deposition velocity increases the mechanical properties. As expected, plasma treatment increases hydrophilicity and consequently the biological performance of the scaffolds. Results also show the potential of the proposed fabrication system to create functional gradient or scaffolds with tailored properties.
Additive manufacturing, plasma surface modification, plasma-assisted bioextrusion system, scaffold, tissue engineering
205-213
Liu, Fengyuan
34504cf0-2b1a-4b0b-afe3-6e6e7f86a193
Wang, Weiguang
0cc699c0-e7b3-49d0-8c84-1e9d63f747d8
Hinduja, Srichand
4458d7aa-31a5-4670-ba45-c81e68d80669
Da Silva Bartolo, Paulo Jorge
2c085472-871d-4ac1-8767-23e5fe9703cf
13 September 2018
Liu, Fengyuan
34504cf0-2b1a-4b0b-afe3-6e6e7f86a193
Wang, Weiguang
0cc699c0-e7b3-49d0-8c84-1e9d63f747d8
Hinduja, Srichand
4458d7aa-31a5-4670-ba45-c81e68d80669
Da Silva Bartolo, Paulo Jorge
2c085472-871d-4ac1-8767-23e5fe9703cf
Liu, Fengyuan, Wang, Weiguang, Hinduja, Srichand and Da Silva Bartolo, Paulo Jorge
(2018)
Hybrid additive manufacturing system for zonal plasma-treated scaffolds.
3D Printing and Additive Manufacturing, 5 (3), .
(doi:10.1089/3dp.2018.0056).
Abstract
Producing synthetic scaffolds with adequate physical, chemical, and biological properties remains a challenge for tissue engineering. Internal architecture, surface chemistry, and material properties have strong impact on the cell biological behavior. This requires sophisticated systems not only able to process multiple materials with different characteristics, creating fully interconnected 3D porous structures with high reproducibility and accuracy, but also able to modify their properties during the fabrication process. This study introduces a novel additive manufacturing system comprising a multiprinting unit (screw-assisted and pressure-assisted printing heads) together with a plasma unit that enables the surface modification of printed scaffolds. Poly(ɛ-caprolactone) scaffolds with a lay-down pattern of 0/90° were fabricated using the screw-assisted printing head and a plasma jet unit used to uniformly modify each layer, a specific region of each layer during the printing process or the external surface of the printed scaffolds. Scaffolds were produced using different plasma exposure times and different distance between the plasma head and the printed layer, and fixed printing conditions. Produced scaffolds were morphologically, mechanically, chemically, and biologically characterized. Results show that the distance between the plasma head and the printed material has no significant effect on the mechanical properties, whereas the increase of the plasma deposition velocity increases the mechanical properties. As expected, plasma treatment increases hydrophilicity and consequently the biological performance of the scaffolds. Results also show the potential of the proposed fabrication system to create functional gradient or scaffolds with tailored properties.
This record has no associated files available for download.
More information
Published date: 13 September 2018
Keywords:
Additive manufacturing, plasma surface modification, plasma-assisted bioextrusion system, scaffold, tissue engineering
Identifiers
Local EPrints ID: 497816
URI: http://eprints.soton.ac.uk/id/eprint/497816
ISSN: 2329-7662
PURE UUID: 0ffbff30-1b09-459c-850e-3622ed9fabba
Catalogue record
Date deposited: 31 Jan 2025 18:10
Last modified: 01 Feb 2025 03:20
Export record
Altmetrics
Contributors
Author:
Fengyuan Liu
Author:
Weiguang Wang
Author:
Srichand Hinduja
Author:
Paulo Jorge Da Silva Bartolo
Download statistics
Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.
View more statistics