Minimizing Stress Shielding and Cement Damage in Cemented Femoral Component of a Hip Prosthesis through Computational Design Optimization

Minimizing Stress Shielding and Cement Damage in Cemented Femoral Component of a Hip Prosthesis through Computational Design Optimization

The average life expectancy of many people undergoing total hip replacement (THR) exceeds twenty-five years and the demand for implants that increase the load-bearing capability of the bone without affecting the short- or long-term stability of the prosthesis is high. Mechanical failure owing to cem...

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Bibliographic Details
Published in:Advances in Orthopedics Vol. 2017; no. 2017; pp. 1 - 12-007
Main Authors: Khandaker, Morshed, Yadav, Rohan, Fischer, Justin, Ait Moussa, Abdellah
Format: Journal Article
Language:English
Published: Cairo, Egypt Hindawi Limiteds 01-01-2017
Hindawi Publishing Corporation
Hindawi
John Wiley & Sons, Inc
Hindawi Limited
Subjects:
Analysis
Bone cements
Care and treatment
Cement
Design optimization
Fractures
Interfaces
Investigations
Load
Patients
Prostheses
Solid modeling
Stress concentration
Titanium alloys
Transplants & implants
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Summary:The average life expectancy of many people undergoing total hip replacement (THR) exceeds twenty-five years and the demand for implants that increase the load-bearing capability of the bone without affecting the short- or long-term stability of the prosthesis is high. Mechanical failure owing to cement damage and stress shielding of the bone are the main factors affecting the long-term survival of cemented hip prostheses and implant design must realistically adjust to balance between these two conflicting effects. In the following analysis we introduce a novel methodology to achieve this objective, the numerical technique combines automatic and realistic modeling of the implant and embedding medium, and finite element analysis to assess the levels of stress shielding and cement damage and, finally, global optimization, using orthogonal arrays and probabilistic restarts, were used. Applications to implants, fabricated using a homogeneous material and a functionally graded material, were presented.
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Academic Editor: Allen L. Carl
ISSN:2090-3464
2090-3472
2090-3472
DOI:10.1155/2017/8437956