Reduced tibial strain-shielding with extraosseous total knee arthroplasty revision system
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Published version
Author(s)
Correa, Tomas
Pal, Bidyut
van Arkel, Richard
Vanacore, Felice
Amis, AA
Type
Journal Article
Abstract
Background
Revision total knee arthroplasty (RTKA) has poorer results than primary total knee arthroplasty (TKA), and the prostheses are invasive and cause strain-shielding of the bones near the knee. This paper describes an RTKA system with extracortical fixation. It was hypothesised that this would reduce strain-shielding compared with intramedullary fixation.
Methods
Twelve replica tibiae were prepared for full-field optical surface strain analysis. They were either left intact, implanted with RTKA components with cemented intramedullary fixation stems, or implanted with a novel design with a tibial tray subframe supported by two extracortical fixation plates and screw fixation. They were loaded to simulate peak walking and stair climbing loads and the surface strains were measured using digital image correlation. The measurements were validated with strain gauge rosettes.
Results
Compared to the intact bone model, extracortical fixation reduced surface strain-shielding by half versus intramedullary fixation. For all load cases and bone regions examined, the extracortical implant shielded 8–27% of bone strain, whereas the intramedullary component shielded 37–56%.
Conclusions
The new fixation design, which offers less bone destruction than conventional RTKA, also reduced strain-shielding. Clinically, this design may allow greater rebuilding of bone loss, and should increase long-term fixation.
Revision total knee arthroplasty (RTKA) has poorer results than primary total knee arthroplasty (TKA), and the prostheses are invasive and cause strain-shielding of the bones near the knee. This paper describes an RTKA system with extracortical fixation. It was hypothesised that this would reduce strain-shielding compared with intramedullary fixation.
Methods
Twelve replica tibiae were prepared for full-field optical surface strain analysis. They were either left intact, implanted with RTKA components with cemented intramedullary fixation stems, or implanted with a novel design with a tibial tray subframe supported by two extracortical fixation plates and screw fixation. They were loaded to simulate peak walking and stair climbing loads and the surface strains were measured using digital image correlation. The measurements were validated with strain gauge rosettes.
Results
Compared to the intact bone model, extracortical fixation reduced surface strain-shielding by half versus intramedullary fixation. For all load cases and bone regions examined, the extracortical implant shielded 8–27% of bone strain, whereas the intramedullary component shielded 37–56%.
Conclusions
The new fixation design, which offers less bone destruction than conventional RTKA, also reduced strain-shielding. Clinically, this design may allow greater rebuilding of bone loss, and should increase long-term fixation.
Date Issued
2018-12-01
Date Acceptance
2018-09-30
Citation
Medical Engineering and Physics, 2018, 62, pp.22-28
ISSN
1350-4533
Publisher
Elsevier
Start Page
22
End Page
28
Journal / Book Title
Medical Engineering and Physics
Volume
62
Copyright Statement
© 2018 The Authors. Published by Elsevier Ltd on behalf of IPEM. This is an open access article under the CC BY license.
(http://creativecommons.org/licenses/by/4.0/)
(http://creativecommons.org/licenses/by/4.0/)
License URL
Sponsor
Engineering & Physical Science Research Council (EPSRC)
Wellcome Trust
Grant Number
N/A
088844/Z/09/Z
Subjects
Cortical bone fixation plate
Prosthesis design
Revision total knee arthroplasty
Stress strain shielding
02 Physical Sciences
09 Engineering
11 Medical And Health Sciences
Biomedical Engineering
Publication Status
Published
Date Publish Online
2018-10-10