Virtual design of 3D-printed bone tissue engineered scaffold shape using mechanobiological modeling: relationship of scaffold pore architecture to bone tissue formation
Virtual design of 3D-printed bone tissue engineered scaffold shape using mechanobiological modeling: relationship of scaffold pore architecture to bone tissue formation
<jats:p>Large bone defects are clinically challenging, with up to 15% of these requiring surgical intervention due to non-union. Bone grafts (autographs or allografts) can be used but they have many limitations, meaning that polymer-based bone tissue engineered scaffolds (tissue engineering) are a more promising solution. Clinical translation of scaffolds is still limited but this could be improved by exploring the whole design space using virtual tools such as mechanobiological modeling. In tissue engineering, a significant research effort has been expended on materials and manufacturing but relatively little has been focused on shape. Most scaffolds use regular pore architecture throughout, leaving custom or irregular pore architecture designs unexplored. The aim of this paper is to introduce a virtual design environment for scaffold development and to illustrate its potential by exploring the relationship of pore architecture to bone tissue formation. A virtual design framework has been created utilizing a mechanical stress finite element (FE) model coupled with a cell behavior agent-based model to investigate the mechanobiological relationships of scaffold shape and bone tissue formation. A case study showed that modifying pore architecture from regular to irregular enabled between 17 and 33% more bone formation within the 4–16-week time periods analyzed. This work shows that shape, specifically pore architecture, is as important as other design parameters such as material and manufacturing for improving the function of bone tissue scaffold implants. It is recommended that future research be conducted to both optimize irregular pore architectures and to explore the potential extension of the concept of shape modification beyond mechanical stress to look at other factors present in the body.
Alshammari, Adel
13ebf75e-79d0-4025-894a-d3db94373536
Alabdah, Fahad
4810a32d-e4cc-4c19-a3ac-2bc10188277e
Wang, Weiguang
0cc699c0-e7b3-49d0-8c84-1e9d63f747d8
Cooper, Glen
560d7c9e-76fe-4efe-80a9-986d598e06f1
28 September 2023
Alshammari, Adel
13ebf75e-79d0-4025-894a-d3db94373536
Alabdah, Fahad
4810a32d-e4cc-4c19-a3ac-2bc10188277e
Wang, Weiguang
0cc699c0-e7b3-49d0-8c84-1e9d63f747d8
Cooper, Glen
560d7c9e-76fe-4efe-80a9-986d598e06f1
Alshammari, Adel, Alabdah, Fahad, Wang, Weiguang and Cooper, Glen
(2023)
Virtual design of 3D-printed bone tissue engineered scaffold shape using mechanobiological modeling: relationship of scaffold pore architecture to bone tissue formation.
Polymers, 15 (19), [3918].
(doi:10.3390/polym15193918).
Abstract
<jats:p>Large bone defects are clinically challenging, with up to 15% of these requiring surgical intervention due to non-union. Bone grafts (autographs or allografts) can be used but they have many limitations, meaning that polymer-based bone tissue engineered scaffolds (tissue engineering) are a more promising solution. Clinical translation of scaffolds is still limited but this could be improved by exploring the whole design space using virtual tools such as mechanobiological modeling. In tissue engineering, a significant research effort has been expended on materials and manufacturing but relatively little has been focused on shape. Most scaffolds use regular pore architecture throughout, leaving custom or irregular pore architecture designs unexplored. The aim of this paper is to introduce a virtual design environment for scaffold development and to illustrate its potential by exploring the relationship of pore architecture to bone tissue formation. A virtual design framework has been created utilizing a mechanical stress finite element (FE) model coupled with a cell behavior agent-based model to investigate the mechanobiological relationships of scaffold shape and bone tissue formation. A case study showed that modifying pore architecture from regular to irregular enabled between 17 and 33% more bone formation within the 4–16-week time periods analyzed. This work shows that shape, specifically pore architecture, is as important as other design parameters such as material and manufacturing for improving the function of bone tissue scaffold implants. It is recommended that future research be conducted to both optimize irregular pore architectures and to explore the potential extension of the concept of shape modification beyond mechanical stress to look at other factors present in the body.
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Accepted/In Press date: 26 September 2023
Published date: 28 September 2023
Identifiers
Local EPrints ID: 502271
URI: http://eprints.soton.ac.uk/id/eprint/502271
ISSN: 2073-4360
PURE UUID: acf79652-177c-46f8-9453-04261fcbfc3e
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Date deposited: 19 Jun 2025 16:58
Last modified: 20 Jun 2025 02:14
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Author:
Adel Alshammari
Author:
Fahad Alabdah
Author:
Weiguang Wang
Author:
Glen Cooper
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