Biomechanical effects of the porous structure of Gyroid and Voronoi hip implants: a finite element analysis using an experimentally validated model
Total hip arthroplasty (THA) is most likely one of the most successful surgical procedures in medicine. It is estimated that three in four patients live beyond the first post-operative year, so appropriate surgery is needed to alleviate an otherwise long-standing suboptimal functional level. However...
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| Online Access: | http://eprints.utm.my/105542/1/MuhammadHanifRamlee2023_BiomechanicalEffectsofthePorousStructure.pdf http://eprints.utm.my/105542/ http://dx.doi.org/10.3390/ma16093298 |
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my.utm.1055422024-04-30T08:15:38Z http://eprints.utm.my/105542/ Biomechanical effects of the porous structure of Gyroid and Voronoi hip implants: a finite element analysis using an experimentally validated model Mohd. Salaha, Zatul Faqihah Muhammad Imam Ammarullah, Muhammad Imam Ammarullah Abdullah, Nik Nur Ain Azrin Abd. Aziz, Aishah Umairah Gan, Hong Seng Abdullah, Abdul Halim Abdul Kadir, Mohammed Rafiq Ramlee, Muhammad Hanif Q Science (General) TK Electrical engineering. Electronics Nuclear engineering Total hip arthroplasty (THA) is most likely one of the most successful surgical procedures in medicine. It is estimated that three in four patients live beyond the first post-operative year, so appropriate surgery is needed to alleviate an otherwise long-standing suboptimal functional level. However, research has shown that during a complete THA procedure, a solid hip implant inserted in the femur can damage the main arterial supply of the cortex and damage the medullary space, leading to cortical bone resorption. Therefore, this study aimed to design a porous hip implant with a focus on providing more space for better osteointegration, improving the medullary revascularisation and blood circulation of patients. Based on a review of the literature, a lightweight implant design was developed by applying topology optimisation and changing the materials of the implant. Gyroid and Voronoi lattice structures and a solid hip implant (as a control) were designed. In total, three designs of hip implants were constructed by using SolidWorks and nTopology software version 2.31. Point loads were applied at the x, y and z-axis to imitate the stance phase condition. The forces represented were x = 320 N, y = −170 N, and z = −2850 N. The materials that were used in this study were titanium alloys. All of the designs were then simulated by using Marc Mentat software version 2020 (MSC Software Corporation, Munich, Germany) via a finite element method. Analysis of the study on topology optimisation demonstrated that the Voronoi lattice structure yielded the lowest von Mises stress and displacement values, at 313.96 MPa and 1.50 mm, respectively, with titanium alloys as the materials. The results also indicate that porous hip implants have the potential to be implemented for hip implant replacement, whereby the mechanical integrity is still preserved. This result will not only help orthopaedic surgeons to justify the design choices, but could also provide new insights for future studies in biomechanics. MDPI 2023-05 Article PeerReviewed application/pdf en http://eprints.utm.my/105542/1/MuhammadHanifRamlee2023_BiomechanicalEffectsofthePorousStructure.pdf Mohd. Salaha, Zatul Faqihah and Muhammad Imam Ammarullah, Muhammad Imam Ammarullah and Abdullah, Nik Nur Ain Azrin and Abd. Aziz, Aishah Umairah and Gan, Hong Seng and Abdullah, Abdul Halim and Abdul Kadir, Mohammed Rafiq and Ramlee, Muhammad Hanif (2023) Biomechanical effects of the porous structure of Gyroid and Voronoi hip implants: a finite element analysis using an experimentally validated model. Materials, 16 (9). pp. 1-20. ISSN 1996-1944 http://dx.doi.org/10.3390/ma16093298 DOI:10.3390/ma16093298 |
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Q Science (General) TK Electrical engineering. Electronics Nuclear engineering Mohd. Salaha, Zatul Faqihah Muhammad Imam Ammarullah, Muhammad Imam Ammarullah Abdullah, Nik Nur Ain Azrin Abd. Aziz, Aishah Umairah Gan, Hong Seng Abdullah, Abdul Halim Abdul Kadir, Mohammed Rafiq Ramlee, Muhammad Hanif Biomechanical effects of the porous structure of Gyroid and Voronoi hip implants: a finite element analysis using an experimentally validated model |
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Total hip arthroplasty (THA) is most likely one of the most successful surgical procedures in medicine. It is estimated that three in four patients live beyond the first post-operative year, so appropriate surgery is needed to alleviate an otherwise long-standing suboptimal functional level. However, research has shown that during a complete THA procedure, a solid hip implant inserted in the femur can damage the main arterial supply of the cortex and damage the medullary space, leading to cortical bone resorption. Therefore, this study aimed to design a porous hip implant with a focus on providing more space for better osteointegration, improving the medullary revascularisation and blood circulation of patients. Based on a review of the literature, a lightweight implant design was developed by applying topology optimisation and changing the materials of the implant. Gyroid and Voronoi lattice structures and a solid hip implant (as a control) were designed. In total, three designs of hip implants were constructed by using SolidWorks and nTopology software version 2.31. Point loads were applied at the x, y and z-axis to imitate the stance phase condition. The forces represented were x = 320 N, y = −170 N, and z = −2850 N. The materials that were used in this study were titanium alloys. All of the designs were then simulated by using Marc Mentat software version 2020 (MSC Software Corporation, Munich, Germany) via a finite element method. Analysis of the study on topology optimisation demonstrated that the Voronoi lattice structure yielded the lowest von Mises stress and displacement values, at 313.96 MPa and 1.50 mm, respectively, with titanium alloys as the materials. The results also indicate that porous hip implants have the potential to be implemented for hip implant replacement, whereby the mechanical integrity is still preserved. This result will not only help orthopaedic surgeons to justify the design choices, but could also provide new insights for future studies in biomechanics. |
| format |
Article |
| author |
Mohd. Salaha, Zatul Faqihah Muhammad Imam Ammarullah, Muhammad Imam Ammarullah Abdullah, Nik Nur Ain Azrin Abd. Aziz, Aishah Umairah Gan, Hong Seng Abdullah, Abdul Halim Abdul Kadir, Mohammed Rafiq Ramlee, Muhammad Hanif |
| author_facet |
Mohd. Salaha, Zatul Faqihah Muhammad Imam Ammarullah, Muhammad Imam Ammarullah Abdullah, Nik Nur Ain Azrin Abd. Aziz, Aishah Umairah Gan, Hong Seng Abdullah, Abdul Halim Abdul Kadir, Mohammed Rafiq Ramlee, Muhammad Hanif |
| author_sort |
Mohd. Salaha, Zatul Faqihah |
| title |
Biomechanical effects of the porous structure of Gyroid and Voronoi hip implants: a finite element analysis using an experimentally validated model |
| title_short |
Biomechanical effects of the porous structure of Gyroid and Voronoi hip implants: a finite element analysis using an experimentally validated model |
| title_full |
Biomechanical effects of the porous structure of Gyroid and Voronoi hip implants: a finite element analysis using an experimentally validated model |
| title_fullStr |
Biomechanical effects of the porous structure of Gyroid and Voronoi hip implants: a finite element analysis using an experimentally validated model |
| title_full_unstemmed |
Biomechanical effects of the porous structure of Gyroid and Voronoi hip implants: a finite element analysis using an experimentally validated model |
| title_sort |
biomechanical effects of the porous structure of gyroid and voronoi hip implants: a finite element analysis using an experimentally validated model |
| publisher |
MDPI |
| publishDate |
2023 |
| url |
http://eprints.utm.my/105542/1/MuhammadHanifRamlee2023_BiomechanicalEffectsofthePorousStructure.pdf http://eprints.utm.my/105542/ http://dx.doi.org/10.3390/ma16093298 |
| _version_ |
1800082626587918336 |
| score |
13.1944895 |