A modified Coulomb's law for the tangential debonding of osseointegrated implants
Katharina Immel, Thang X. Duong, Vu-Hieu Nguyen, Guillaume Haiat and, Roger A. Sauer

TL;DR
This paper introduces a modified Coulomb's law with a state variable friction model to better predict tangential debonding of osseointegrated implants, improving accuracy over traditional models.
Contribution
It presents a new friction formulation combining Coulomb's law with a displacement-dependent coefficient, calibrated with experimental data for enhanced debonding prediction.
Findings
Close agreement with experimental torque data (error < 2.25%)
Improved estimates of bone shear modulus and adhesion energy
Effective modeling of partial osseointegration
Abstract
Cementless implants are widely used in orthopedic and oral surgery. However, debonding-related failure still occurs at the bone-implant interface. It remains difficult to predict such implant failure since the underlying osseointegration phenomena are still poorly understood. Especially in terms of friction and adhesion at the macro-scale, there is a lack of data and reliable models. The aim of this work is to present a new friction formulation that can model the tangential contact behavior between osseointegrated implants and bone tissue, with focus on debonding. The classical Coulomb's law is combined with a state variable friction law to model a displacement-dependent friction coefficient. A smooth state function, based on the sliding distance, is used to model implant debonding. The formulation is implemented in a 3D nonlinear finite element framework, and it is calibrated with…
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Taxonomy
TopicsContact Mechanics and Variational Inequalities · Adhesion, Friction, and Surface Interactions · Dynamics and Control of Mechanical Systems
