Interface micromotion of cementless hip stems in simulated hip arthroplasty
Problem statement: The design of hip prostheses has evolved over time due to various complications found after hip replacement surgery. The currently commercially available cementless femoral stems can be categorized into one of three major types, straight cylindrical, tapered rectangular and anatom...
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my.utm.128992011-07-06T01:32:45Z http://eprints.utm.my/id/eprint/12899/ Interface micromotion of cementless hip stems in simulated hip arthroplasty Abdul-Kadir, Mohammed Rafiq Kamsah, Nazri TJ Mechanical engineering and machinery Problem statement: The design of hip prostheses has evolved over time due to various complications found after hip replacement surgery. The currently commercially available cementless femoral stems can be categorized into one of three major types, straight cylindrical, tapered rectangular and anatomical. Each type proposes a unique concept to achieve primary stability-a major requirement for bone healing process. Virtual analyses have been made on individual implants, but comparison between the three major types is required to determine the strength and weaknesses of the design concepts. Approach: Three types of implants were modeled in three dimensions-the straight cylindrical, rectangular taper and anatomical. The size of the three implants was carefully designed to fit and fill the canal of a femur reconstructed from a computed tomography image dataset. Hip arthroplasty was simulated virtually by inserting the hip stem into the femoral canal. Finite element method was used in conjunction with a specialized sub-routine to measure micromotion at the bone-implant interface under loads simulating physiological walking and stair-climbing. Another sub-routine was used to assign bone properties based on the grayscale values of the CT image. Results: All the three types of cementless hip stems were found to be stable under both walking and stair climbing activities. Large micromotion values concentrated around the proximal and distal part of the stems. Conclusion/Recommendations: The three major types of hip stems were compared in this study and all of them were found to be stable after simulated physiological activities. Science Publications 2009 Article PeerReviewed Abdul-Kadir, Mohammed Rafiq and Kamsah, Nazri (2009) Interface micromotion of cementless hip stems in simulated hip arthroplasty. American Journal of Applied Sciences . pp. 1682-1689. ISSN 1546-9239 http://dx.doi.org/10.3844/ajassp.2009.1682.1689 doi:10.3844/ajassp.2009.1682.1689 |
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TJ Mechanical engineering and machinery Abdul-Kadir, Mohammed Rafiq Kamsah, Nazri Interface micromotion of cementless hip stems in simulated hip arthroplasty |
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Problem statement: The design of hip prostheses has evolved over time due to various complications found after hip replacement surgery. The currently commercially available cementless femoral stems can be categorized into one of three major types, straight cylindrical, tapered rectangular and anatomical. Each type proposes a unique concept to achieve primary stability-a major requirement for bone healing process. Virtual analyses have been made on individual implants, but comparison between the three major types is required to determine the strength and weaknesses of the design concepts. Approach: Three types of implants were modeled in three dimensions-the straight cylindrical, rectangular taper and anatomical. The size of the three implants was carefully designed to fit and fill the canal of a femur reconstructed from a computed tomography image dataset. Hip arthroplasty was simulated virtually by inserting the hip stem into the femoral canal. Finite element method was used in conjunction with a specialized sub-routine to measure micromotion at the bone-implant interface under loads simulating physiological walking and stair-climbing. Another sub-routine was used to assign bone properties based on the grayscale values of the CT image. Results: All the three types of cementless hip stems were found to be stable under both walking and stair climbing activities. Large micromotion values concentrated around the proximal and distal part of the stems. Conclusion/Recommendations: The three major types of hip stems were compared in this study and all of them were found to be stable after simulated physiological activities. |
| format |
Article |
| author |
Abdul-Kadir, Mohammed Rafiq Kamsah, Nazri |
| author_facet |
Abdul-Kadir, Mohammed Rafiq Kamsah, Nazri |
| author_sort |
Abdul-Kadir, Mohammed Rafiq |
| title |
Interface micromotion of cementless hip stems in simulated hip arthroplasty |
| title_short |
Interface micromotion of cementless hip stems in simulated hip arthroplasty |
| title_full |
Interface micromotion of cementless hip stems in simulated hip arthroplasty |
| title_fullStr |
Interface micromotion of cementless hip stems in simulated hip arthroplasty |
| title_full_unstemmed |
Interface micromotion of cementless hip stems in simulated hip arthroplasty |
| title_sort |
interface micromotion of cementless hip stems in simulated hip arthroplasty |
| publisher |
Science Publications |
| publishDate |
2009 |
| url |
http://eprints.utm.my/id/eprint/12899/ http://dx.doi.org/10.3844/ajassp.2009.1682.1689 |
| _version_ |
1643646064714055680 |
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13.160551 |