Finite element analysis on longitudinal and radial functionally graded femoral prosthesis
This study focused on developing a 3D finite element model of functionally graded femoral prostheses to decrease stress shielding and to improve total hip replacement performance. The mechanical properties of the modeled functionally graded femoral prostheses were adjusted in the sagittal and transv...
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my.uniten.dspace-299802023-12-29T15:43:50Z Finite element analysis on longitudinal and radial functionally graded femoral prosthesis Oshkour A.A. A Abu Osman N. Davoodi M.M. Yau Y.H. Tarlochan F. B Wan Abas W.A. Bayat M. 35727035100 55810871000 23992063700 16246742500 9045273600 55946515000 55989556600 Femoral prosthesis Finite element analysis Strain energy Stress shielding Total hip replacement Finite Element Analysis Hip Prosthesis Materials Testing Prosthesis Design Stress, Mechanical Arthroplasty Bone cement Finite element method Functionally graded materials Hip prostheses Mechanical properties Shielding Strain energy Volume fraction femoral prosthesis finite element analysis strain energy stress shielding total hip replacement 3D finite element model Conventional materials Femoral prosthesis Functionally graded Gradient exponents Stress shielding Total hip replacement (THR) Transverse planes article femoral prosthesis finite element analysis hip prosthesis materials testing mechanical stress prosthesis strain energy Stress shielding total hip prosthesis Prosthetics This study focused on developing a 3D finite element model of functionally graded femoral prostheses to decrease stress shielding and to improve total hip replacement performance. The mechanical properties of the modeled functionally graded femoral prostheses were adjusted in the sagittal and transverse planes by changing the volume fraction gradient exponent. Prostheses with material changes in the sagittal and transverse planes were considered longitudinal and radial prostheses, respectively. The effects of cemented and noncemented implantation methods were also considered in this study. Strain energy and von Mises stresses were determined at the femoral proximal metaphysis and interfaces of the implanted femur components, respectively. Results demonstrated that the strain energy increased proportionally with increasing volume fraction gradient exponent, whereas the interface stresses decreased on the prostheses surfaces. A limited increase was also observed at the surfaces of the bone and cement. The periprosthetic femur with a noncemented prosthesis exhibited higher strain energy than with a cemented prosthesis. Radial prostheses implantation displayed more strain energy than longitudinal prostheses implantation in the femoral proximal part. Functionally graded materials also increased strain energy and exhibited promising potentials as substitutes of conventional materials to decrease stress shielding and to enhance total hip replacement lifespan. � 2013 John Wiley & Sons, Ltd. Final 2023-12-29T07:43:50Z 2023-12-29T07:43:50Z 2013 Article 10.1002/cnm.2583 2-s2.0-84888881813 https://www.scopus.com/inward/record.uri?eid=2-s2.0-84888881813&doi=10.1002%2fcnm.2583&partnerID=40&md5=4409ed2bd644a0fe25ef19721e8f0c8c https://irepository.uniten.edu.my/handle/123456789/29980 29 12 1412 1427 Scopus |
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Femoral prosthesis Finite element analysis Strain energy Stress shielding Total hip replacement Finite Element Analysis Hip Prosthesis Materials Testing Prosthesis Design Stress, Mechanical Arthroplasty Bone cement Finite element method Functionally graded materials Hip prostheses Mechanical properties Shielding Strain energy Volume fraction femoral prosthesis finite element analysis strain energy stress shielding total hip replacement 3D finite element model Conventional materials Femoral prosthesis Functionally graded Gradient exponents Stress shielding Total hip replacement (THR) Transverse planes article femoral prosthesis finite element analysis hip prosthesis materials testing mechanical stress prosthesis strain energy Stress shielding total hip prosthesis Prosthetics |
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Femoral prosthesis Finite element analysis Strain energy Stress shielding Total hip replacement Finite Element Analysis Hip Prosthesis Materials Testing Prosthesis Design Stress, Mechanical Arthroplasty Bone cement Finite element method Functionally graded materials Hip prostheses Mechanical properties Shielding Strain energy Volume fraction femoral prosthesis finite element analysis strain energy stress shielding total hip replacement 3D finite element model Conventional materials Femoral prosthesis Functionally graded Gradient exponents Stress shielding Total hip replacement (THR) Transverse planes article femoral prosthesis finite element analysis hip prosthesis materials testing mechanical stress prosthesis strain energy Stress shielding total hip prosthesis Prosthetics Oshkour A.A. A Abu Osman N. Davoodi M.M. Yau Y.H. Tarlochan F. B Wan Abas W.A. Bayat M. Finite element analysis on longitudinal and radial functionally graded femoral prosthesis |
| description |
This study focused on developing a 3D finite element model of functionally graded femoral prostheses to decrease stress shielding and to improve total hip replacement performance. The mechanical properties of the modeled functionally graded femoral prostheses were adjusted in the sagittal and transverse planes by changing the volume fraction gradient exponent. Prostheses with material changes in the sagittal and transverse planes were considered longitudinal and radial prostheses, respectively. The effects of cemented and noncemented implantation methods were also considered in this study. Strain energy and von Mises stresses were determined at the femoral proximal metaphysis and interfaces of the implanted femur components, respectively. Results demonstrated that the strain energy increased proportionally with increasing volume fraction gradient exponent, whereas the interface stresses decreased on the prostheses surfaces. A limited increase was also observed at the surfaces of the bone and cement. The periprosthetic femur with a noncemented prosthesis exhibited higher strain energy than with a cemented prosthesis. Radial prostheses implantation displayed more strain energy than longitudinal prostheses implantation in the femoral proximal part. Functionally graded materials also increased strain energy and exhibited promising potentials as substitutes of conventional materials to decrease stress shielding and to enhance total hip replacement lifespan. � 2013 John Wiley & Sons, Ltd. |
| author2 |
35727035100 |
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35727035100 Oshkour A.A. A Abu Osman N. Davoodi M.M. Yau Y.H. Tarlochan F. B Wan Abas W.A. Bayat M. |
| format |
Article |
| author |
Oshkour A.A. A Abu Osman N. Davoodi M.M. Yau Y.H. Tarlochan F. B Wan Abas W.A. Bayat M. |
| author_sort |
Oshkour A.A. |
| title |
Finite element analysis on longitudinal and radial functionally graded femoral prosthesis |
| title_short |
Finite element analysis on longitudinal and radial functionally graded femoral prosthesis |
| title_full |
Finite element analysis on longitudinal and radial functionally graded femoral prosthesis |
| title_fullStr |
Finite element analysis on longitudinal and radial functionally graded femoral prosthesis |
| title_full_unstemmed |
Finite element analysis on longitudinal and radial functionally graded femoral prosthesis |
| title_sort |
finite element analysis on longitudinal and radial functionally graded femoral prosthesis |
| publishDate |
2023 |
| _version_ |
1806427903767871488 |