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Abstract
Aims
Loosening is a well-known complication in the fixation of fractures using devices such as locking plates or unilateral fixators. It is believed that high strains in the bone at the bone-screw interface can initiate loosening, which can result in infection, and further loosening. Here, we present a new theory of loosening of implants. The time-dependent response of bone subjected to loads results in interfacial deformations in the bone which accumulate with cyclical loading and thus accentuates loosening.
Methods
We used an ‘ideal’ bone-screw system, in which the screw is subjected to cyclical lateral loads and trabecular bone is modelled as non-linear viscoelastic and non-linear viscoelastic-viscoplastic material, based on recent experiments, which we conducted.
Results
We found that the interfacial deformation in the bone increases with the number of cycles, and the use of a non-linear viscoelastic-viscoplastic model results in larger deformations, some of which are irrecoverable. There is an apparent trend in which interfacial deformations increase with increasing porosity of bone.
Conclusion
The developed time-dependent model of the mechanical behaviour of bone permits prediction of loosening due to cyclical loads, which has not been possible previously. Application of this model shows that implant loosening will be accentuated by cyclical loading due to physiological activities, and the risks of loosening are greater in osteoporotic patients.
Loosening is a well-known complication in the fixation of fractures using devices such as locking plates or unilateral fixators. It is believed that high strains in the bone at the bone-screw interface can initiate loosening, which can result in infection, and further loosening. Here, we present a new theory of loosening of implants. The time-dependent response of bone subjected to loads results in interfacial deformations in the bone which accumulate with cyclical loading and thus accentuates loosening.
Methods
We used an ‘ideal’ bone-screw system, in which the screw is subjected to cyclical lateral loads and trabecular bone is modelled as non-linear viscoelastic and non-linear viscoelastic-viscoplastic material, based on recent experiments, which we conducted.
Results
We found that the interfacial deformation in the bone increases with the number of cycles, and the use of a non-linear viscoelastic-viscoplastic model results in larger deformations, some of which are irrecoverable. There is an apparent trend in which interfacial deformations increase with increasing porosity of bone.
Conclusion
The developed time-dependent model of the mechanical behaviour of bone permits prediction of loosening due to cyclical loads, which has not been possible previously. Application of this model shows that implant loosening will be accentuated by cyclical loading due to physiological activities, and the risks of loosening are greater in osteoporotic patients.
| Original language | English |
|---|---|
| Pages (from-to) | 580-586 |
| Journal | Bone & Joint Research |
| Volume | 7 |
| Issue number | 10 |
| DOIs | |
| Publication status | Published - 25 Oct 2018 |
Keywords / Materials (for Non-textual outputs)
- cyclic loading
- viscoelastic-viscoplastic
- bone volume ratio
- irrecoverable strain
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Dive into the research topics of 'Time-dependent behaviour of bone accentuates loosening in the fixation of fractures using bone-screw systems'. Together they form a unique fingerprint.Projects
- 1 Finished
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A novel diagnostic tool: from structural health monitoring to tissue quality prediction
Pankaj, P. (Principal Investigator)
1/10/13 → 31/03/17
Project: Research
Profiles
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Pankaj Pankaj
- School of Engineering - Personal Chair of Computational Biomechanics
Person: Academic: Research Active