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Finite element analysis of circumferential crack behavior in cement-femoral prosthesis interface

Investigating the crack behavior in the cement mantle can improve total hip replacement performance by lessening the effects of crack failure and femoral prosthesis loosening. This study analyzed the behavior of the internal circumferential cracks located in the cement layer of the cement-prosthesis...

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Main Authors: Oshkour A.A., Davoodi M.M., Abu Osman N.A., Yau Y.H., Tarlochan F., Abas W.A.B.W.
Other Authors: 35727035100
Format: Article
Published: Elsevier Ltd 2023
Subjects:
Cement mantel
Crack behavior
Extended finite element method
Femoral prosthesis
Stress intensity factor
Total hip replacement
Arthroplasty
Cements
Crack propagation
Finite element method
Hip prostheses
Prosthetics
Stress intensity factors
Cement layers
Cement mantle
Circumferential cracks
Crack failure
Fracture and fatigue
Gait cycles
Maximum stress intensity
Minimum stress
Push offs
Swing phase
Total hip replacement (THR)
Cracks
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spelling my.uniten.dspace-301862023-12-29T15:45:19Z Finite element analysis of circumferential crack behavior in cement-femoral prosthesis interface Oshkour A.A. Davoodi M.M. Abu Osman N.A. Yau Y.H. Tarlochan F. Abas W.A.B.W. 35727035100 23992063700 8511221500 16246742500 9045273600 36558784200 Cement mantel Crack behavior Extended finite element method Femoral prosthesis Stress intensity factor Total hip replacement Arthroplasty Cements Crack propagation Finite element method Hip prostheses Prosthetics Stress intensity factors Cement layers Cement mantle Circumferential cracks Crack behavior Crack failure Extended finite element method Femoral prosthesis Fracture and fatigue Gait cycles Maximum stress intensity Minimum stress Push offs Swing phase Total hip replacement (THR) Cracks Investigating the crack behavior in the cement mantle can improve total hip replacement performance by lessening the effects of crack failure and femoral prosthesis loosening. This study analyzed the behavior of the internal circumferential cracks located in the cement layer of the cement-prosthesis interface during the main phases of the gait cycle. The extended finite element method was used in determining the stress intensity factors to identify the crack behavior. An adverse relationship was found between the stress intensity factors and the distance from the distal end. Consequently, the maximum stress intensity factors were observed at the distal part, specifically at the corner of the cement mantle. Additionally, the highest values of KI, KII, and KIII were presented during the single leg stance and push off phases, whereas the swing phase showed the minimum stress intensity factors. In addition, KI and KIII were identified to be the dominant stress intensity factors and were respectively enhanced along the proximal to the distal end by about 89.5% and 65.9% in the lateral side and 63.7% and 56.5% in the medial side. This finding indicates higher risks of cement mantle fracture and fatigue crack propagation at the distal area. � 2013 Elsevier Ltd. Final 2023-12-29T07:45:19Z 2023-12-29T07:45:19Z 2013 Article 10.1016/j.matdes.2013.01.037 2-s2.0-84874543617 https://www.scopus.com/inward/record.uri?eid=2-s2.0-84874543617&doi=10.1016%2fj.matdes.2013.01.037&partnerID=40&md5=5314474db8d65368fd3485a640680c9c https://irepository.uniten.edu.my/handle/123456789/30186 49 96 102 All Open Access; Green Open Access Elsevier Ltd Scopus
institution Universiti Tenaga Nasional
building UNITEN Library
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Tenaga Nasional
content_source UNITEN Institutional Repository
url_provider http://dspace.uniten.edu.my/
topic Cement mantel
Crack behavior
Extended finite element method
Femoral prosthesis
Stress intensity factor
Total hip replacement
Arthroplasty
Cements
Crack propagation
Finite element method
Hip prostheses
Prosthetics
Stress intensity factors
Cement layers
Cement mantle
Circumferential cracks
Crack behavior
Crack failure
Extended finite element method
Femoral prosthesis
Fracture and fatigue
Gait cycles
Maximum stress intensity
Minimum stress
Push offs
Swing phase
Total hip replacement (THR)
Cracks
spellingShingle Cement mantel
Crack behavior
Extended finite element method
Femoral prosthesis
Stress intensity factor
Total hip replacement
Arthroplasty
Cements
Crack propagation
Finite element method
Hip prostheses
Prosthetics
Stress intensity factors
Cement layers
Cement mantle
Circumferential cracks
Crack behavior
Crack failure
Extended finite element method
Femoral prosthesis
Fracture and fatigue
Gait cycles
Maximum stress intensity
Minimum stress
Push offs
Swing phase
Total hip replacement (THR)
Cracks
Oshkour A.A.
Davoodi M.M.
Abu Osman N.A.
Yau Y.H.
Tarlochan F.
Abas W.A.B.W.
Finite element analysis of circumferential crack behavior in cement-femoral prosthesis interface
description Investigating the crack behavior in the cement mantle can improve total hip replacement performance by lessening the effects of crack failure and femoral prosthesis loosening. This study analyzed the behavior of the internal circumferential cracks located in the cement layer of the cement-prosthesis interface during the main phases of the gait cycle. The extended finite element method was used in determining the stress intensity factors to identify the crack behavior. An adverse relationship was found between the stress intensity factors and the distance from the distal end. Consequently, the maximum stress intensity factors were observed at the distal part, specifically at the corner of the cement mantle. Additionally, the highest values of KI, KII, and KIII were presented during the single leg stance and push off phases, whereas the swing phase showed the minimum stress intensity factors. In addition, KI and KIII were identified to be the dominant stress intensity factors and were respectively enhanced along the proximal to the distal end by about 89.5% and 65.9% in the lateral side and 63.7% and 56.5% in the medial side. This finding indicates higher risks of cement mantle fracture and fatigue crack propagation at the distal area. � 2013 Elsevier Ltd.
author2 35727035100
author_facet 35727035100
Oshkour A.A.
Davoodi M.M.
Abu Osman N.A.
Yau Y.H.
Tarlochan F.
Abas W.A.B.W.
format Article
author Oshkour A.A.
Davoodi M.M.
Abu Osman N.A.
Yau Y.H.
Tarlochan F.
Abas W.A.B.W.
author_sort Oshkour A.A.
title Finite element analysis of circumferential crack behavior in cement-femoral prosthesis interface
title_short Finite element analysis of circumferential crack behavior in cement-femoral prosthesis interface
title_full Finite element analysis of circumferential crack behavior in cement-femoral prosthesis interface
title_fullStr Finite element analysis of circumferential crack behavior in cement-femoral prosthesis interface
title_full_unstemmed Finite element analysis of circumferential crack behavior in cement-femoral prosthesis interface
title_sort finite element analysis of circumferential crack behavior in cement-femoral prosthesis interface
publisher Elsevier Ltd
publishDate 2023
_version_ 1806424398419197952
score 13.239859

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