Dataset for Damage mechanisms at the cement-implant interface of polished cemented femoral stems
Dataset for Damage mechanisms at the cement-implant interface of polished cemented femoral stems
The occurrence of damage on polished femoral stems has been widely reported in the literature, and bone cement has been implicated in a tribo-corrosive failure process. However, the mechanisms of cement-mediated damage and the impact of cement formulation on this process are not well understood. In this study, thirteen Zimmer CPT polished femoral stems and corresponding cement specimens were retrieved at revision surgery and analysed using high-resolution imaging techniques. Surface damage attributed to tribo-corrosion was observed on all stems. Corrosion product, in the form of black flaky surface debris, was observed on the surface of cement specimens; both energy-dispersive x-ray spectroscopy (EDX)and inductively coupled plasma mass spectrometry(ICP-MS) confirmed the presence of cobalt and chromium, with the ICP-MS showing much higher levels of Cr compared to Co when compared to the original stem material. Agglomerates of ZrO2 radiopacifier were also identified on the cement surface, and in some cases showed evidence of abrasive wear; the size of these particles correlated well with elliptical pitting evident on the surfaces of the corresponding stems. This evidence supports the hypothesis that agglomerates of hard radiopacifier particles within the cement may induce a wear-dominated tribo-corrosive interaction at the stem-cement interface that damages the surface of polished CoCr femoral stems.
University of Southampton
Shearwood-Porter, Natalie
4716bea7-fa95-45a4-931b-3b96508b7389
Browne, Martin
6578cc37-7bd6-43b9-ae5c-77ccb7726397
Milton, James
9e183221-d0d4-4ddb-aeba-0fdde9d31230
Cooper, Matthew
54f7bff0-1f8c-4835-8358-71eef8529e7a
Palmer, Martin
d2e60e81-5d6e-4ddb-a243-602537286080
Latham, Jeremy M.
c63671a2-248f-489f-b620-64ff19bc20f5
Wood, Robert
d9523d31-41a8-459a-8831-70e29ffe8a73
Cook, Richard
06f8322d-81be-4f82-9326-19e55541c78f
Shearwood-Porter, Natalie
4716bea7-fa95-45a4-931b-3b96508b7389
Browne, Martin
6578cc37-7bd6-43b9-ae5c-77ccb7726397
Milton, James
9e183221-d0d4-4ddb-aeba-0fdde9d31230
Cooper, Matthew
54f7bff0-1f8c-4835-8358-71eef8529e7a
Palmer, Martin
d2e60e81-5d6e-4ddb-a243-602537286080
Latham, Jeremy M.
c63671a2-248f-489f-b620-64ff19bc20f5
Wood, Robert
d9523d31-41a8-459a-8831-70e29ffe8a73
Cook, Richard
06f8322d-81be-4f82-9326-19e55541c78f
Shearwood-Porter, Natalie, Browne, Martin, Milton, James, Cooper, Matthew, Palmer, Martin, Latham, Jeremy M., Wood, Robert and Cook, Richard
(2016)
Dataset for Damage mechanisms at the cement-implant interface of polished cemented femoral stems.
University of Southampton
doi:10.5258/SOTON/393917
[Dataset]
Abstract
The occurrence of damage on polished femoral stems has been widely reported in the literature, and bone cement has been implicated in a tribo-corrosive failure process. However, the mechanisms of cement-mediated damage and the impact of cement formulation on this process are not well understood. In this study, thirteen Zimmer CPT polished femoral stems and corresponding cement specimens were retrieved at revision surgery and analysed using high-resolution imaging techniques. Surface damage attributed to tribo-corrosion was observed on all stems. Corrosion product, in the form of black flaky surface debris, was observed on the surface of cement specimens; both energy-dispersive x-ray spectroscopy (EDX)and inductively coupled plasma mass spectrometry(ICP-MS) confirmed the presence of cobalt and chromium, with the ICP-MS showing much higher levels of Cr compared to Co when compared to the original stem material. Agglomerates of ZrO2 radiopacifier were also identified on the cement surface, and in some cases showed evidence of abrasive wear; the size of these particles correlated well with elliptical pitting evident on the surfaces of the corresponding stems. This evidence supports the hypothesis that agglomerates of hard radiopacifier particles within the cement may induce a wear-dominated tribo-corrosive interaction at the stem-cement interface that damages the surface of polished CoCr femoral stems.
More information
Published date: 2016
Organisations:
Engineering Sciences, Faculty of Engineering and the Environment, Bioengineering Group, Geochemistry, nCATS Group
Projects:
Green Tribology
Funded by: UNSPECIFIED (EP/J001023/1)
5 September 2011 to 4 September 2016
Identifiers
Local EPrints ID: 393917
URI: http://eprints.soton.ac.uk/id/eprint/393917
PURE UUID: d4dea098-bd6c-474a-ba5e-75b49ec72d9b
Catalogue record
Date deposited: 22 Jun 2016 08:39
Last modified: 05 Nov 2023 02:44
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Contributors
Creator:
Natalie Shearwood-Porter
Creator:
Jeremy M. Latham
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