Strategy for controlling the properties of bioactive poly-ether-ether-ketone/hydroxyapatite composites for bone tissue engineering scaffolds
Strategy for controlling the properties of bioactive poly-ether-ether-ketone/hydroxyapatite composites for bone tissue engineering scaffolds
A strategy for the preparation of bioactive poly-ether-ether-ketone/hydroxyapatite (PEEK/HA) composites was proposed in this study with the aim of controlling the biological and mechanical properties of different parts of the composites. The strategy integrated solvent-based extrusion freeforming 3D printing technology in order to print high-resolution HA scaffolds and compression molding processes for the production of bioactive PEEK/HA composites. To this end, an optimized model, established using response surface methodology, was employed to optimize the extrusion process parameters on the basis of accurate characterization of the extrusion pressure, and the effects of the filament/pore sizes on the PEEK infiltration depth into the HA scaffold were investigated. The results of scanning electron microscopy and computed tomography analyses revealed that the PEEK/HA composites exhibited a uniform microstructure and a good interface between the HA filaments and the PEEK matrix following the optimization of the process parameters. The HA scaffolds were fully infiltrated by PEEK in both vertical and lateral directions with an infiltration depth of 3 mm while maintaining the HA network structure and uniformity. The biological and mechanical performance test results validated that the PEEK/HA composites possessed excellent biocompatibility as well as yields and compressive strengths within the range of human cortical bone suitable for load-bearing applications.
Zhong, Gaoyan
4122f394-9978-4435-874b-5e8356d19a31
Vaezi, Mohammad
828e14c1-3236-4153-8f69-3837233f48ed
Mei, Xinliang
c722b96e-beab-484f-a41b-a08443b32a6d
Liu, Ping
41ff5c8a-4b8a-4010-b1a9-eb6d03716591
Yang, Shoufeng
e0018adf-8123-4a54-b8dd-306c10ca48f1
Zhong, Gaoyan
4122f394-9978-4435-874b-5e8356d19a31
Vaezi, Mohammad
828e14c1-3236-4153-8f69-3837233f48ed
Mei, Xinliang
c722b96e-beab-484f-a41b-a08443b32a6d
Liu, Ping
41ff5c8a-4b8a-4010-b1a9-eb6d03716591
Yang, Shoufeng
e0018adf-8123-4a54-b8dd-306c10ca48f1
Zhong, Gaoyan, Vaezi, Mohammad, Mei, Xinliang, Liu, Ping and Yang, Shoufeng
(2019)
Strategy for controlling the properties of bioactive poly-ether-ether-ketone/hydroxyapatite composites for bone tissue engineering scaffolds.
ACS Omega.
(doi:10.1021/acsomega.9b02572).
Abstract
A strategy for the preparation of bioactive poly-ether-ether-ketone/hydroxyapatite (PEEK/HA) composites was proposed in this study with the aim of controlling the biological and mechanical properties of different parts of the composites. The strategy integrated solvent-based extrusion freeforming 3D printing technology in order to print high-resolution HA scaffolds and compression molding processes for the production of bioactive PEEK/HA composites. To this end, an optimized model, established using response surface methodology, was employed to optimize the extrusion process parameters on the basis of accurate characterization of the extrusion pressure, and the effects of the filament/pore sizes on the PEEK infiltration depth into the HA scaffold were investigated. The results of scanning electron microscopy and computed tomography analyses revealed that the PEEK/HA composites exhibited a uniform microstructure and a good interface between the HA filaments and the PEEK matrix following the optimization of the process parameters. The HA scaffolds were fully infiltrated by PEEK in both vertical and lateral directions with an infiltration depth of 3 mm while maintaining the HA network structure and uniformity. The biological and mechanical performance test results validated that the PEEK/HA composites possessed excellent biocompatibility as well as yields and compressive strengths within the range of human cortical bone suitable for load-bearing applications.
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acsomega.9b02572
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Accepted/In Press date: 23 October 2019
e-pub ahead of print date: 5 November 2019
Identifiers
Local EPrints ID: 435634
URI: http://eprints.soton.ac.uk/id/eprint/435634
ISSN: 2470-1343
PURE UUID: 847e3d89-3bf5-44f5-9dc8-d291f96a50f5
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Date deposited: 15 Nov 2019 17:30
Last modified: 16 Mar 2024 05:14
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Author:
Gaoyan Zhong
Author:
Mohammad Vaezi
Author:
Xinliang Mei
Author:
Ping Liu
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