3D-printed poly(ϵ-caprolactone)/graphene scaffolds activated with p1-latex protein for bone regeneration
3D-printed poly(ϵ-caprolactone)/graphene scaffolds activated with p1-latex protein for bone regeneration
Biomanufacturing is a relatively new research domain focusing on the use of additive manufacturing technologies, biomaterials, cells, and biomolecular signals to produce tissue constructs for tissue engineering. For bone regeneration, researchers are focusing on the use of polymeric and polymer/ceramic scaffolds seeded with osteoblasts or mesenchymal stem cells. However, high-performance scaffolds in terms of mechanical, cell stimulation, and biological performance are still required. This article investigates the use of an extrusion additive manufacturing system to produce poly(ϵ-caprolactone) (PCL) and PCL/graphene nanosheet scaffolds for bone applications. Scaffolds with regular and reproducible architecture and uniform dispersion of graphene were produced and coated with P1-latex protein extracted from the Hevea brasiliensis rubber tree. Results show that the obtained scaffolds cultivated with human adipose-derived stem cells present no toxicity effects. The presence of graphene nanosheet and P1-latex protein in the scaffolds increased cell proliferation compared with PCL scaffolds. Moreover, the presence of P1-latex protein promotes earlier osteogenic differentiation, suggesting that PCL/graphene/P1-latex protein scaffolds are suitable for bone regeneration applications.
P1-latex protein, biofabrication, graphene, scaffold, tissue engineering
127-137
C., Guilherme
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Wang, Weiguang
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W.h., Chiang
3340e35b-371c-472c-b6eb-32c20c2da126
Cooper, Glen
560d7c9e-76fe-4efe-80a9-986d598e06f1
Diver, Carl
29b1f17d-dd3b-4d44-be6d-dba1d76c1e26
Blaker, Jonny
335d1dd7-e240-4e23-b026-d9c99d159876
Frade, MARCO ANDREY CIPRIANI
37a4d8ed-a744-4c1f-9344-75683a6c8663
Da Silva Bartolo, Paulo Jorge
2c085472-871d-4ac1-8767-23e5fe9703cf
C., Guilherme
02b13ded-4d21-4c46-bbc9-c5c55c285deb
Wang, Weiguang
0cc699c0-e7b3-49d0-8c84-1e9d63f747d8
W.h., Chiang
3340e35b-371c-472c-b6eb-32c20c2da126
Cooper, Glen
560d7c9e-76fe-4efe-80a9-986d598e06f1
Diver, Carl
29b1f17d-dd3b-4d44-be6d-dba1d76c1e26
Blaker, Jonny
335d1dd7-e240-4e23-b026-d9c99d159876
Frade, MARCO ANDREY CIPRIANI
37a4d8ed-a744-4c1f-9344-75683a6c8663
Da Silva Bartolo, Paulo Jorge
2c085472-871d-4ac1-8767-23e5fe9703cf
C., Guilherme, Wang, Weiguang, W.h., Chiang, Cooper, Glen, Diver, Carl, Blaker, Jonny, Frade, MARCO ANDREY CIPRIANI and Da Silva Bartolo, Paulo Jorge
(2018)
3D-printed poly(ϵ-caprolactone)/graphene scaffolds activated with p1-latex protein for bone regeneration.
3D Printing and Additive Manufacturing, 5 (2), .
(doi:10.1089/3dp.2018.0012).
Abstract
Biomanufacturing is a relatively new research domain focusing on the use of additive manufacturing technologies, biomaterials, cells, and biomolecular signals to produce tissue constructs for tissue engineering. For bone regeneration, researchers are focusing on the use of polymeric and polymer/ceramic scaffolds seeded with osteoblasts or mesenchymal stem cells. However, high-performance scaffolds in terms of mechanical, cell stimulation, and biological performance are still required. This article investigates the use of an extrusion additive manufacturing system to produce poly(ϵ-caprolactone) (PCL) and PCL/graphene nanosheet scaffolds for bone applications. Scaffolds with regular and reproducible architecture and uniform dispersion of graphene were produced and coated with P1-latex protein extracted from the Hevea brasiliensis rubber tree. Results show that the obtained scaffolds cultivated with human adipose-derived stem cells present no toxicity effects. The presence of graphene nanosheet and P1-latex protein in the scaffolds increased cell proliferation compared with PCL scaffolds. Moreover, the presence of P1-latex protein promotes earlier osteogenic differentiation, suggesting that PCL/graphene/P1-latex protein scaffolds are suitable for bone regeneration applications.
Text
bártolo-et-al-2018-3d-printed-poly(ɛ-caprolactone)-graphene-scaffolds-activated-with-p1-latex-protein-for-bone
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e-pub ahead of print date: 1 June 2018
Keywords:
P1-latex protein, biofabrication, graphene, scaffold, tissue engineering
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Local EPrints ID: 498078
URI: http://eprints.soton.ac.uk/id/eprint/498078
ISSN: 2329-7670
PURE UUID: 39f2f75d-c8df-4ca9-88f3-2ca3f5beb340
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Date deposited: 07 Feb 2025 17:34
Last modified: 22 Aug 2025 02:46
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Contributors
Author:
Guilherme C.
Author:
Weiguang Wang
Author:
Chiang W.h.
Author:
Glen Cooper
Author:
Carl Diver
Author:
Jonny Blaker
Author:
MARCO ANDREY CIPRIANI Frade
Author:
Paulo Jorge Da Silva Bartolo
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