Design of new generation femoral prostheses using functionally graded materials: A finite element analysis

Design of new generation femoral prostheses using functionally graded materials: A finite element analysis

This study aimed to develop a three-dimensional finite element model of a functionally graded femoral prosthesis. The model consisted of a femoral prosthesis created from functionally graded materials (FGMs), cement, and femur. The hip prosthesis was composed of FGMs made of titanium alloy, chrome-c...

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Main Authors: Oshkour A.A., Osman N.A.A., Yau Y.H., Tarlochan F., Abas W.A.B.W.
Other Authors: 35727035100
Format: Article
Published: 2023
Subjects:
Femoral prosthesis
Finite element analysis
Functionally graded material
Gait
Biocompatible Materials
Computer Simulation
Computer-Aided Design
Elastic Modulus
Equipment Failure Analysis
Femur
Finite Element Analysis
Hip Prosthesis
Humans
Models, Biological
Prosthesis Design
Tensile Strength
Weight-Bearing
Beams and girders
Cements
Finite element method
Hip prostheses
Hydroxyapatite
Prosthetics
Stress concentration
Titanium alloys
Volume fraction
biomaterial
Constituent materials
Functionally graded
Functionally graded material (FGMs)
Gradient exponents
Prosthetic devices
Three dimensional finite element model
High surface area
MLCS
MLOWN
article
biological model
chemistry
computer aided design
computer simulation
equipment failure analysis
femur
finite element analysis
hip prosthesis
human
physiology
prosthesis
tensile strength
weight bearing
Young modulus
Functionally graded materials
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Institution: Universiti Tenaga Nasional
id my.uniten.dspace-30165
record_format dspace
spelling my.uniten.dspace-301652023-12-29T15:45:09Z Design of new generation femoral prostheses using functionally graded materials: A finite element analysis Oshkour A.A. Osman N.A.A. Yau Y.H. Tarlochan F. Abas W.A.B.W. 35727035100 8511221500 16246742500 9045273600 36558784200 Femoral prosthesis Finite element analysis Functionally graded material Gait Biocompatible Materials Computer Simulation Computer-Aided Design Elastic Modulus Equipment Failure Analysis Femur Finite Element Analysis Hip Prosthesis Humans Models, Biological Prosthesis Design Tensile Strength Weight-Bearing Beams and girders Cements Finite element method Hip prostheses Hydroxyapatite Prosthetics Stress concentration Beams and girders Cements Finite element method Hip prostheses Prosthetics Titanium alloys Volume fraction biomaterial Constituent materials Femoral prosthesis Functionally graded Functionally graded material (FGMs) Gait Gradient exponents Prosthetic devices Three dimensional finite element model Constituent materials Femoral prosthesis Functionally graded Gait Gradient exponents High surface area Prosthetic devices Three dimensional finite element model MLCS MLOWN article biological model chemistry computer aided design computer simulation equipment failure analysis femur finite element analysis hip prosthesis human physiology prosthesis tensile strength weight bearing Young modulus Functionally graded materials Functionally graded materials This study aimed to develop a three-dimensional finite element model of a functionally graded femoral prosthesis. The model consisted of a femoral prosthesis created from functionally graded materials (FGMs), cement, and femur. The hip prosthesis was composed of FGMs made of titanium alloy, chrome-cobalt, and hydroxyapatite at volume fraction gradient exponents of 0, 1, and 5, respectively. The stress was measured on the femoral prosthesis, cement, and femur. Stress on the neck of the femoral prosthesis was not sensitive to the properties of the constituent material. However, stress on the stem and cement decreased proportionally as the volume fraction gradient exponent of the FGM increased. Meanwhile, stress became uniform on the cement mantle layer. In addition, stress on the femur in the proximal part increased and a high surface area of the femoral part was involved in absorbing the stress. As such, the stress-shielding area decreased. The results obtained in this study are significant in the design and longevity of new prosthetic devices because FGMs offer the potential to achieve stress distribution that more closely resembles that of the natural bone in the femur. � IMechE 2012. Final 2023-12-29T07:45:09Z 2023-12-29T07:45:09Z 2013 Article 10.1177/0954411912459421 2-s2.0-84874538726 https://www.scopus.com/inward/record.uri?eid=2-s2.0-84874538726&doi=10.1177%2f0954411912459421&partnerID=40&md5=c213b8b14ac8cd1ced0f63f32a25ba19 https://irepository.uniten.edu.my/handle/123456789/30165 227 1 3 17 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 Femoral prosthesis
Finite element analysis
Functionally graded material
Gait
Biocompatible Materials
Computer Simulation
Computer-Aided Design
Elastic Modulus
Equipment Failure Analysis
Femur
Finite Element Analysis
Hip Prosthesis
Humans
Models, Biological
Prosthesis Design
Tensile Strength
Weight-Bearing
Beams and girders
Cements
Finite element method
Hip prostheses
Hydroxyapatite
Prosthetics
Stress concentration
Beams and girders
Cements
Finite element method
Hip prostheses
Prosthetics
Titanium alloys
Volume fraction
biomaterial
Constituent materials
Femoral prosthesis
Functionally graded
Functionally graded material (FGMs)
Gait
Gradient exponents
Prosthetic devices
Three dimensional finite element model
Constituent materials
Femoral prosthesis
Functionally graded
Gait
Gradient exponents
High surface area
Prosthetic devices
Three dimensional finite element model
MLCS
MLOWN
article
biological model
chemistry
computer aided design
computer simulation
equipment failure analysis
femur
finite element analysis
hip prosthesis
human
physiology
prosthesis
tensile strength
weight bearing
Young modulus
Functionally graded materials
Functionally graded materials
spellingShingle Femoral prosthesis
Finite element analysis
Functionally graded material
Gait
Biocompatible Materials
Computer Simulation
Computer-Aided Design
Elastic Modulus
Equipment Failure Analysis
Femur
Finite Element Analysis
Hip Prosthesis
Humans
Models, Biological
Prosthesis Design
Tensile Strength
Weight-Bearing
Beams and girders
Cements
Finite element method
Hip prostheses
Hydroxyapatite
Prosthetics
Stress concentration
Beams and girders
Cements
Finite element method
Hip prostheses
Prosthetics
Titanium alloys
Volume fraction
biomaterial
Constituent materials
Femoral prosthesis
Functionally graded
Functionally graded material (FGMs)
Gait
Gradient exponents
Prosthetic devices
Three dimensional finite element model
Constituent materials
Femoral prosthesis
Functionally graded
Gait
Gradient exponents
High surface area
Prosthetic devices
Three dimensional finite element model
MLCS
MLOWN
article
biological model
chemistry
computer aided design
computer simulation
equipment failure analysis
femur
finite element analysis
hip prosthesis
human
physiology
prosthesis
tensile strength
weight bearing
Young modulus
Functionally graded materials
Functionally graded materials
Oshkour A.A.
Osman N.A.A.
Yau Y.H.
Tarlochan F.
Abas W.A.B.W.
Design of new generation femoral prostheses using functionally graded materials: A finite element analysis
description This study aimed to develop a three-dimensional finite element model of a functionally graded femoral prosthesis. The model consisted of a femoral prosthesis created from functionally graded materials (FGMs), cement, and femur. The hip prosthesis was composed of FGMs made of titanium alloy, chrome-cobalt, and hydroxyapatite at volume fraction gradient exponents of 0, 1, and 5, respectively. The stress was measured on the femoral prosthesis, cement, and femur. Stress on the neck of the femoral prosthesis was not sensitive to the properties of the constituent material. However, stress on the stem and cement decreased proportionally as the volume fraction gradient exponent of the FGM increased. Meanwhile, stress became uniform on the cement mantle layer. In addition, stress on the femur in the proximal part increased and a high surface area of the femoral part was involved in absorbing the stress. As such, the stress-shielding area decreased. The results obtained in this study are significant in the design and longevity of new prosthetic devices because FGMs offer the potential to achieve stress distribution that more closely resembles that of the natural bone in the femur. � IMechE 2012.
author2 35727035100
author_facet 35727035100
Oshkour A.A.
Osman N.A.A.
Yau Y.H.
Tarlochan F.
Abas W.A.B.W.
format Article
author Oshkour A.A.
Osman N.A.A.
Yau Y.H.
Tarlochan F.
Abas W.A.B.W.
author_sort Oshkour A.A.
title Design of new generation femoral prostheses using functionally graded materials: A finite element analysis
title_short Design of new generation femoral prostheses using functionally graded materials: A finite element analysis
title_full Design of new generation femoral prostheses using functionally graded materials: A finite element analysis
title_fullStr Design of new generation femoral prostheses using functionally graded materials: A finite element analysis
title_full_unstemmed Design of new generation femoral prostheses using functionally graded materials: A finite element analysis
title_sort design of new generation femoral prostheses using functionally graded materials: a finite element analysis
publishDate 2023
_version_ 1806424152976916480

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