Nanocomposite-coated porous templates for engineered bone scaffolds: A parametric study of layer-by-layer assembly conditions
Nanocomposite-coated porous templates for engineered bone scaffolds: A parametric study of layer-by-layer assembly conditions
Using the layer-by-layer (LbL) assembly technique to deposit mechanically reinforcing coatings onto porous templates is a route for fabricating engineered bone scaffold materials with a combination of high porosity, strength, and stiffness. LbL assembly involves the sequential deposition of nano- to micro-scale multilayer coatings from aqueous solutions. Here, a design of experiments (DOE) approach was used to evaluate LbL assembly of polyethyleneimine (PEI), polyacrylic acid (PAA), and nanoclay coatings onto open-cell polyurethane foam templates. The thickness of the coatings, and the porosity, elastic modulus and collapse stress of coated foam templates were most strongly affected by the pH of PAA solutions, salt concentration, and interactions between these factors. The mechanical properties of coated foams correlated with the thickness of the coatings, but were also ascribed to changes in the coating properties due to the different assembly conditions. A DOE optimization aimed to balance the trade-off between higher mechanical properties but lower porosity of foam templates with increasing coating thickness. Micromechanical modelling predicted that deposition of 116 QLs would achieve mechanical properties of cancellous bone (~0.05 GPa stiffness and ~2 MPa strength) at a suitable porosity of ~70%. When capped with a final layer of PAA and cross-linked via thermal treatment, the PEI/PAA/PEI/nanoclay coatings exhibited good indirect cytotoxicity with mesenchymal stem cells. The ability of LbL assembly to deposit a wide range of functional constituents within multilayer-structured coatings makes the general strategy of templated LbL assembly a powerful route for fabricating engineered tissue scaffolds that can be applied onto various porous template materials to achieve a wide range of properties, pore structures, and multifunctionality.
Ziminska, Monika
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Chalanqui, Marine J.
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Chambers, Philip
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Acheson, Jonathan
b4781eeb-9e88-4337-99af-74a2083d58ad
McCarthy, Helen
26fef320-0597-4a97-b054-f2ae8e8a50d7
Dunne, Nicholas
d807aea4-6553-47da-a06d-dfb0d4bbe690
Hamilton, Andrew
9088cf01-8d7f-45f0-af56-b4784227447c
20 September 2019
Ziminska, Monika
a53248bb-9825-4aa4-a9ea-2701a7f618f1
Chalanqui, Marine J.
6a9b74dd-e213-4e18-b099-b65fad0a60c5
Chambers, Philip
b6723bb5-b6f1-4dbb-a4aa-b0d2093007c9
Acheson, Jonathan
b4781eeb-9e88-4337-99af-74a2083d58ad
McCarthy, Helen
26fef320-0597-4a97-b054-f2ae8e8a50d7
Dunne, Nicholas
d807aea4-6553-47da-a06d-dfb0d4bbe690
Hamilton, Andrew
9088cf01-8d7f-45f0-af56-b4784227447c
Ziminska, Monika, Chalanqui, Marine J., Chambers, Philip, Acheson, Jonathan, McCarthy, Helen, Dunne, Nicholas and Hamilton, Andrew
(2019)
Nanocomposite-coated porous templates for engineered bone scaffolds: A parametric study of layer-by-layer assembly conditions.
Biomedical Materials, 14 (6), [065008].
(doi:10.1088/1748-605X/ab3b7b).
Abstract
Using the layer-by-layer (LbL) assembly technique to deposit mechanically reinforcing coatings onto porous templates is a route for fabricating engineered bone scaffold materials with a combination of high porosity, strength, and stiffness. LbL assembly involves the sequential deposition of nano- to micro-scale multilayer coatings from aqueous solutions. Here, a design of experiments (DOE) approach was used to evaluate LbL assembly of polyethyleneimine (PEI), polyacrylic acid (PAA), and nanoclay coatings onto open-cell polyurethane foam templates. The thickness of the coatings, and the porosity, elastic modulus and collapse stress of coated foam templates were most strongly affected by the pH of PAA solutions, salt concentration, and interactions between these factors. The mechanical properties of coated foams correlated with the thickness of the coatings, but were also ascribed to changes in the coating properties due to the different assembly conditions. A DOE optimization aimed to balance the trade-off between higher mechanical properties but lower porosity of foam templates with increasing coating thickness. Micromechanical modelling predicted that deposition of 116 QLs would achieve mechanical properties of cancellous bone (~0.05 GPa stiffness and ~2 MPa strength) at a suitable porosity of ~70%. When capped with a final layer of PAA and cross-linked via thermal treatment, the PEI/PAA/PEI/nanoclay coatings exhibited good indirect cytotoxicity with mesenchymal stem cells. The ability of LbL assembly to deposit a wide range of functional constituents within multilayer-structured coatings makes the general strategy of templated LbL assembly a powerful route for fabricating engineered tissue scaffolds that can be applied onto various porous template materials to achieve a wide range of properties, pore structures, and multifunctionality.
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Accepted/In Press date: 15 August 2019
e-pub ahead of print date: 15 August 2019
Published date: 20 September 2019
Identifiers
Local EPrints ID: 433483
URI: http://eprints.soton.ac.uk/id/eprint/433483
ISSN: 1748-6041
PURE UUID: e216e536-6677-4c6d-9b12-a94c99f02e5c
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Date deposited: 23 Aug 2019 16:30
Last modified: 16 Mar 2024 08:07
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Contributors
Author:
Monika Ziminska
Author:
Marine J. Chalanqui
Author:
Philip Chambers
Author:
Jonathan Acheson
Author:
Helen McCarthy
Author:
Nicholas Dunne
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