3D-printed graphene and graphene quantum dot-reinforced polycaprolactone scaffolds for bone-tissue engineering
3D-printed graphene and graphene quantum dot-reinforced polycaprolactone scaffolds for bone-tissue engineering
The regeneration of large-scale bone loss due to accidents, trauma, diseases, or tumor resection is still a critical clinical challenge. With the development of additive manufacturing technology and advanced biomaterials, 3D-printed biocompatible synthetic polymer scaffolds have been widely studied for their key roles in supporting bone tissue regeneration. Scaffold aims to provide mechanical properties that match the host bone as well as biological activities that can effectively promote cell proliferation and differentiation, ultimately facilitating bone tissue regeneration. Due to its unique biocompatibility and biodegradability, polycaprolactone (PCL) becomes one of the dominant synthetic polymeric materials considered for scaffold fabrication. However, using PCL alone presents insufficient mechanical properties; thus, different functional fillers have been added to modulate both the mechanical and biological performance of fabricated scaffolds. Among all functional fillers, carbon nanomaterials, particularly graphene (G), have shown an emerging trend. Graphene quantum dots (GQD), a member of the graphene family, are regarded as an ideal next-generation functional filler for scaffold fabrication. It presents high solubility in water, controllable dose-dependent cytotoxicity similar to that of G, and unique biological properties benefiting from smaller sizes. Current research using GQD for tissue engineering applications is limited, and the systemic comparison between G and GQD at different concentrations is also missing. This study, for the first time, evaluates and compares the impact of incorporating G and GQD into PCL bone tissue engineering scaffolds from surface, thermal, mechanical, and biological perspectives. Results suggested that the addition of both materials under 5 wt % significantly improved both the mechanical and biological performance of PCL scaffolds. Under 3 wt %, PCL/GQD scaffolds presented better compressive strength while maintaining the same level of biological performance compared with PCL/G scaffolds, revealing the strong potential for future in vivo studies and bone tissue regeneration applications.
1245-1256
Meng, Duo
6753f37f-a536-41f3-bc0f-878c8be30439
Hou, Yanhao
fb285a4f-8235-429a-9095-31468811802a
Kurniawan, Darwin
b4a2a388-19fd-4342-bea3-b1b68e6d21e3
Weng, Ren-Jie
ff20d9fb-ba90-4df0-9f1c-136c49485695
Chiang, Wei-Hung
db6b2d14-a342-41ad-83d0-d2f73ce8554d
Wang, Weiguang
0cc699c0-e7b3-49d0-8c84-1e9d63f747d8
12 January 2024
Meng, Duo
6753f37f-a536-41f3-bc0f-878c8be30439
Hou, Yanhao
fb285a4f-8235-429a-9095-31468811802a
Kurniawan, Darwin
b4a2a388-19fd-4342-bea3-b1b68e6d21e3
Weng, Ren-Jie
ff20d9fb-ba90-4df0-9f1c-136c49485695
Chiang, Wei-Hung
db6b2d14-a342-41ad-83d0-d2f73ce8554d
Wang, Weiguang
0cc699c0-e7b3-49d0-8c84-1e9d63f747d8
Meng, Duo, Hou, Yanhao, Kurniawan, Darwin, Weng, Ren-Jie, Chiang, Wei-Hung and Wang, Weiguang
(2024)
3D-printed graphene and graphene quantum dot-reinforced polycaprolactone scaffolds for bone-tissue engineering.
ACS Applied Nano Materials, 7 (1), .
(doi:10.1021/acsanm.3c05225).
Abstract
The regeneration of large-scale bone loss due to accidents, trauma, diseases, or tumor resection is still a critical clinical challenge. With the development of additive manufacturing technology and advanced biomaterials, 3D-printed biocompatible synthetic polymer scaffolds have been widely studied for their key roles in supporting bone tissue regeneration. Scaffold aims to provide mechanical properties that match the host bone as well as biological activities that can effectively promote cell proliferation and differentiation, ultimately facilitating bone tissue regeneration. Due to its unique biocompatibility and biodegradability, polycaprolactone (PCL) becomes one of the dominant synthetic polymeric materials considered for scaffold fabrication. However, using PCL alone presents insufficient mechanical properties; thus, different functional fillers have been added to modulate both the mechanical and biological performance of fabricated scaffolds. Among all functional fillers, carbon nanomaterials, particularly graphene (G), have shown an emerging trend. Graphene quantum dots (GQD), a member of the graphene family, are regarded as an ideal next-generation functional filler for scaffold fabrication. It presents high solubility in water, controllable dose-dependent cytotoxicity similar to that of G, and unique biological properties benefiting from smaller sizes. Current research using GQD for tissue engineering applications is limited, and the systemic comparison between G and GQD at different concentrations is also missing. This study, for the first time, evaluates and compares the impact of incorporating G and GQD into PCL bone tissue engineering scaffolds from surface, thermal, mechanical, and biological perspectives. Results suggested that the addition of both materials under 5 wt % significantly improved both the mechanical and biological performance of PCL scaffolds. Under 3 wt %, PCL/GQD scaffolds presented better compressive strength while maintaining the same level of biological performance compared with PCL/G scaffolds, revealing the strong potential for future in vivo studies and bone tissue regeneration applications.
Text
meng-et-al-2024-3d-printed-graphene-and-graphene-quantum-dot-reinforced-polycaprolactone-scaffolds-for-bone-tissue
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Accepted/In Press date: 11 December 2023
e-pub ahead of print date: 3 January 2024
Published date: 12 January 2024
Identifiers
Local EPrints ID: 503445
URI: http://eprints.soton.ac.uk/id/eprint/503445
ISSN: 2574-0970
PURE UUID: 23ce3a6a-b76a-4736-8219-5a9e6d6fea62
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Date deposited: 01 Aug 2025 16:30
Last modified: 22 Aug 2025 02:46
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Author:
Duo Meng
Author:
Yanhao Hou
Author:
Darwin Kurniawan
Author:
Ren-Jie Weng
Author:
Wei-Hung Chiang
Author:
Weiguang Wang
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