Analysis of cementless implants using interface nonlinear friction—Experimental and finite element studies

• Published in: Journal of biomechanics Vol. 30; no. 2; pp. 121 - 129
• Main Authors: Dammak, M., Shirazi-Adl, A., Zukor, D.J.
• Format: Journal Article
• Language: English
• Published: United States Elsevier Ltd 01.02.1997
• Subjects: Bone and Bones - surgery; Bone Cements; Bone Nails; Bone Plates; Bone Screws; Computer Simulation; Elasticity; Equipment Design; Forecasting; Friction; Humans; Interface; Materials Testing; Models, Biological; Pliability; Polyurethanes; Porosity; Post; Pressure; Prostheses and Implants; Reproducibility of Results; Screw; Stress, Mechanical; Surface Properties; Total joint replacement; Total joint replacement; Screw; Friction; Post; Interface
• ISSN: 0021-9290; 1873-2380
• DOI: 10.1016/S0021-9290(96)00110-8

Measured interface nonlinear friction properties are used to develop models to study the short-term fixation response of smooth- and porous-surfaced posts, bone screws, and plates fixed with and without posts/screws. Experimental studies are carried out to validate the model predictions and identify the relative role of posts and screws in fixation of a plate on a polyurethane block under symmetric/eccentric axial compression loads. The idealized Coulomb's friction is also used for the sake of comparison. The incorporation of measured nonlinear, rather than the idealized Coulomb, friction is essential to compute realistic results. For plate fixation, the experimental and finite element results show that the screw fixation yields the stiffest response followed by the smooth- and then porous-coated post fixation. For example, under 1000N eccentric axial compression, the edge of the plate opposite the loaded edge is measured to lift by 1147 ± 72, 244 ± 38, or 112 ± 28 μm, respectively, for the cases with no fixation, with smooth-surfaced posts, or with screws. The corresponding models predict, respectively, values of 1538, 347, or 259 μm and also 556 μm for the plate fixed with porous coated posts. The satisfactory agreement between numerical and experimental results confirms the importance of proper interface modelling for the analysis of posts, screws, and complex fixation systems. This becomes further evident when considering cementless implants in which the bone-implant interface exhibits relatively large displacements as the maximum resistance force is reached. The developed models can be used to investigate the post-operative short-term stability of various cementless implant designs.