Depth profiling via nanoindentation for characterisation of the elastic modulus and hydraulic properties of thin hydrogel layers
Depth profiling via nanoindentation for characterisation of the elastic modulus and hydraulic properties of thin hydrogel layers
The accurate determination of the mechanical properties of hydrogels is of fundamental importance for a range of applications, including in assessing the effect of stiffness on cell behaviour. This is a particular issue when using thin hydrogel layers adherent to stiff substrate supports, as the apparent stiffness can be significantly influenced by the constraint of the underlying impermeable substrate, leading to inaccurate measurements of the elastic modulus and permeability of thin hydrogel layers. This study used depth profiling nanoindentation and a poroelastic model for spherical indentation to identify the elastic moduli and hydraulic conductivity of thin polyacrylamide (PAAm) hydrogel layers (∼27 μm–782 μm thick) on impermeable substrates. The apparent stiffness of thin PAAm layers increased with indentation depth and was significantly greater than those of thicker hydrogels, which showed no influence of indentation depth. The hydraulic conductivity decreased as the geometrical confinement of hydrogels increased, indicating that the fluid became more constrained within the confinement areas. The impact of geometrical confinement on the apparent modulus and hydraulic conductivity of thin PAAm hydrogel layers was then established, and their elastic moduli and intrinsic permeability were determined in relation to this effect. This study offers valuable insights into the mechanical characterisation of thin PAAm hydrogel layers used for the fundamental study of cell mechanobiology.
Xu, Dichu
e91ddedf-af9a-4f0c-834b-3e538c2e166b
Hernandez Miranda, Maria Luisa
035474c1-1507-4a2a-9a2d-ae4aafb3efb7
Evans, Nick
06a05c97-bfed-4abb-9244-34ec9f4b4b95
Sengers, Bram
d6b771b1-4ede-48c5-9644-fa86503941aa
Browne, Martin
6578cc37-7bd6-43b9-ae5c-77ccb7726397
Cook, Richard
06f8322d-81be-4f82-9326-19e55541c78f
19 October 2023
Xu, Dichu
e91ddedf-af9a-4f0c-834b-3e538c2e166b
Hernandez Miranda, Maria Luisa
035474c1-1507-4a2a-9a2d-ae4aafb3efb7
Evans, Nick
06a05c97-bfed-4abb-9244-34ec9f4b4b95
Sengers, Bram
d6b771b1-4ede-48c5-9644-fa86503941aa
Browne, Martin
6578cc37-7bd6-43b9-ae5c-77ccb7726397
Cook, Richard
06f8322d-81be-4f82-9326-19e55541c78f
Xu, Dichu, Hernandez Miranda, Maria Luisa, Evans, Nick, Sengers, Bram, Browne, Martin and Cook, Richard
(2023)
Depth profiling via nanoindentation for characterisation of the elastic modulus and hydraulic properties of thin hydrogel layers.
Journal of the Mechanical Behavior of Biomedical Materials, 148.
(doi:10.1016/j.jmbbm.2023.106195).
Abstract
The accurate determination of the mechanical properties of hydrogels is of fundamental importance for a range of applications, including in assessing the effect of stiffness on cell behaviour. This is a particular issue when using thin hydrogel layers adherent to stiff substrate supports, as the apparent stiffness can be significantly influenced by the constraint of the underlying impermeable substrate, leading to inaccurate measurements of the elastic modulus and permeability of thin hydrogel layers. This study used depth profiling nanoindentation and a poroelastic model for spherical indentation to identify the elastic moduli and hydraulic conductivity of thin polyacrylamide (PAAm) hydrogel layers (∼27 μm–782 μm thick) on impermeable substrates. The apparent stiffness of thin PAAm layers increased with indentation depth and was significantly greater than those of thicker hydrogels, which showed no influence of indentation depth. The hydraulic conductivity decreased as the geometrical confinement of hydrogels increased, indicating that the fluid became more constrained within the confinement areas. The impact of geometrical confinement on the apparent modulus and hydraulic conductivity of thin PAAm hydrogel layers was then established, and their elastic moduli and intrinsic permeability were determined in relation to this effect. This study offers valuable insights into the mechanical characterisation of thin PAAm hydrogel layers used for the fundamental study of cell mechanobiology.
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e-pub ahead of print date: 14 October 2023
Published date: 19 October 2023
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Local EPrints ID: 492702
URI: http://eprints.soton.ac.uk/id/eprint/492702
ISSN: 1751-6161
PURE UUID: 89cdec78-0bbc-4e77-a80b-c7f6fecc7706
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Date deposited: 12 Aug 2024 16:41
Last modified: 13 Aug 2024 01:42
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Author:
Maria Luisa Hernandez Miranda
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