Effect of orthopedic implants on canine long bone compression stiffness: a combined experimental and computational approach

Osteosynthesis for canine long bones is a complex process requiring knowledge of biology, surgical techniques and (bio)mechanical principles. Subject-specific finite element analysis constitutes a promising tool to evaluate the effect of surgical intervention on the global properties of a bone–impla...

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Bibliographic Details
Published in:Proceedings of the Institution of Mechanical Engineers. Part H, Journal of engineering in medicine Journal of engineering in medicine, 2020-03, Vol.234 (3), p.255-264
Main Authors: Laurent, Cédric P, Böhme, Béatrice, Verwaerde, Jolanthe, Papeleux, Luc, Ponthot, Jean-Philippe, Balligand, Marc
Format: Article
Language:English
Subjects:
Animal biology
Animals
Bioengineering
Biomaterials
Biomechanical Phenomena
Biomechanics
Biomedical materials
Biotechnology
Bone implants
Bones
Cell Behavior
Cellular Biology
Compression
Compression tests
Compressive Strength
Computer applications
Computer simulation
Dogs
Engineering Sciences
Finite Element Analysis
Finite element method
Humerus - physiology
Imaging
Life Sciences
Locking
Long bone
Material properties
Materials
Materials and structures in mechanics
Mechanical properties
Mechanical Tests
Mechanics
Mechanics of materials
Orthopaedic implants
Orthopedics
Osteosynthesis
Physics
Prostheses and Implants
Solid mechanics
Stiffness
Structural mechanics
Subcellular Processes
Surgical implants
Transplants & implants
Veterinary medicine and animal Health
Veterinary surgeons
Vibrations
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Description
Summary:Osteosynthesis for canine long bones is a complex process requiring knowledge of biology, surgical techniques and (bio)mechanical principles. Subject-specific finite element analysis constitutes a promising tool to evaluate the effect of surgical intervention on the global properties of a bone–implant construct, but suffers from a lack of validation. In this study, the biomechanical behavior of 10 canine humeri was compared before and after creation of a 10 mm bone defect stabilized with an eight-hole locking compression plate (Synthes®) and two locking screws on each fragment. The response under compression of both intact and plated samples was measured experimentally and reproduced with a finite element model. The experimental stiffness ratio between plated and intact bone was equal to 0.39 ± 0.06. A subject-specific finite element analysis including density-dependent elasto-plastic material properties for canine bone and automatic generation of orthopedic implants was then conducted to recover these experimental results. The stiffness of intact and plated samples could be predicted, with no significant differences with experimental data. The simulated stiffness ratio between plated and intact canine bone was equal to 0.43 ± 0.03. This study constitutes a first step toward the building of a virtual database of pre-computed cases, aiming at helping the veterinary surgeons to make decisions regarding the most suited orthopedic solution for a given dog and a given fracture.
ISSN:0954-4119
2041-3033
DOI:10.1177/0954411919882603