Bruno Jetté1, Vladimir Brailovski2, Mathieu Dumas3, Charles Simoneau4, Patrick Terriault5. 1. Ecole de technologie superieure, Department of Mechanical Engineering, 1100 Notre-Dame Street West, Montreal, Quebec, Canada H3C1K3. Electronic address: bruno.jette.1@etsmtl.net. 2. Ecole de technologie superieure, Department of Mechanical Engineering, 1100 Notre-Dame Street West, Montreal, Quebec, Canada H3C1K3. Electronic address: vladimir.brailovski@etsmtl.ca. 3. Ecole de technologie superieure, Department of Mechanical Engineering, 1100 Notre-Dame Street West, Montreal, Quebec, Canada H3C1K3. Electronic address: mathieu.dumas.1@etsmtl.net. 4. Ecole de technologie superieure, Department of Mechanical Engineering, 1100 Notre-Dame Street West, Montreal, Quebec, Canada H3C1K3. Electronic address: charles.simoneau.1@ens.etsmtl.ca. 5. Ecole de technologie superieure, Department of Mechanical Engineering, 1100 Notre-Dame Street West, Montreal, Quebec, Canada H3C1K3. Electronic address: patrick.terriault@etsmtl.ca.
Abstract
BACKGROUND: The current total hip prostheses with dense femoral stems are considerably stiffer than the host bones, which leads to such long-term complications as aseptic loosening, and eventually, the need for a revision. Consequently, the lifetime of the implantation does not match the lifetime expectation of young patients. METHOD: A femoral stem design featuring a porous structure is proposed to lower its stiffness and allow bone tissue ingrowth. The porous structure is based on a diamond cubic lattice in which the pore size and the strut thickness are selected to meet the biomechanical requirements of the strength and the bone ingrowth. A porous stem and its fully dense counterpart are produced by laser powder-bed fusion using Ti-6Al-4V alloy. To evaluate the stiffness reduction, static testing based on the ISO standard 7206-4 is performed. The experimental results recorded by digital image correlation are analyzed and compared to the numerical model. RESULTS & CONCLUSIONS: The numerical and experimental force-displacement characteristics of the porous stem show a 31% lower stiffness as compared to that of its dense counterpart. Moreover, the correlation analysis of the total displacement and equivalent strain fields allows the preliminary validation of the numerical model of the porous stem. Finally, the analysis of the surface-to-volume and the strength-to-stiffness ratios of diamond lattice structures allow the assessment of their potential as biomimetic constructs for load-bearing orthopaedic implants.
BACKGROUND: The current total hip prostheses with dense femoral stems are considerably stiffer than the host bones, which leads to such long-term complications as aseptic loosening, and eventually, the need for a revision. Consequently, the lifetime of the implantation does not match the lifetime expectation of young patients. METHOD: A femoral stem design featuring a porous structure is proposed to lower its stiffness and allow bone tissue ingrowth. The porous structure is based on a diamond cubic lattice in which the pore size and the strut thickness are selected to meet the biomechanical requirements of the strength and the bone ingrowth. A porous stem and its fully dense counterpart are produced by laser powder-bed fusion using Ti-6Al-4V alloy. To evaluate the stiffness reduction, static testing based on the ISO standard 7206-4 is performed. The experimental results recorded by digital image correlation are analyzed and compared to the numerical model. RESULTS & CONCLUSIONS: The numerical and experimental force-displacement characteristics of the porous stem show a 31% lower stiffness as compared to that of its dense counterpart. Moreover, the correlation analysis of the total displacement and equivalent strain fields allows the preliminary validation of the numerical model of the porous stem. Finally, the analysis of the surface-to-volume and the strength-to-stiffness ratios of diamond lattice structures allow the assessment of their potential as biomimetic constructs for load-bearing orthopaedic implants.
Authors: Hassan Mehboob; Faris Tarlochan; Ali Mehboob; Seung-Hwan Chang; S Ramesh; Wan Sharuzi Wan Harun; Kumaran Kadirgama Journal: J Mater Sci Mater Med Date: 2020-08-20 Impact factor: 3.896