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Mechanical Properties of Bone
- 1. Mechanical Properties of Bone Human knowledge and human power meet in one; for where the cause is not known the effect cannot be produced. ~ Sir Francis Bacon BIOE 3200 - Fall 2014 Nova special, “Making Stuff Stronger”: https://www.youtube.com/watch?v=KE- Y45WjiP0&list=PL9OMJke2jE_CuZgiOUJ0frfw3TRLKQByw&index=1
- 2. Learning Objectives Conduct stress analysis on bone sample ◦ Identify the source of anisotropic material properties ◦ Analyze how changes in bone composition affect stress and strain within bone BIOE 3200 - Fall 2014
- 3. How is mechanical testing conducted? Apply force, measure deformation - OR - Pull (or push) a known distance, measure force Example of tensile testing: ◦ https://www.youtube.co m/watch?v=67fSwIjYJ- BIOE 3200 - Fall 2014 From http://web.ecs.baylor.edu/faculty/Skurla/research.htm
- 4. Bone BIOE 3200 - Fall 2014
- 5. BIOE 3200 - Fall 2014
- 6. BIOE 3200 - Fall 2014
- 7. Bone is anisotropic: material properties are different in different directions. Bone is a composite of mainly collagen and minerals (hydroxyapatite, or calcium) ◦ Collagen has a low E, high tensile strength, low compressive strength ◦ Hydroxyapatite is stiff, brittle, high compressive strength Anisotropic material that can resist different types of forces Strongest in compression, weakest in shear, intermediate in tension BIOE 3200 - Fall 2014
- 8. What gives bone its anisotropic properties? Cortical bone ◦ E affected mainly by mineral content ◦ Resists torque (concentric lamellae) Cancellous bone ◦ 25% as dense as cortical ◦ 10% as stiff as cortical ◦ 500% as ductile as cortical ◦ Resists BIOE 3200 - Fall 2014
- 9. Bone is a dynamic material Self-repairs (osteoclasts, osteoblasts) Changes with aging: becomes stiffer and less ductile Changes with lack of weight-bearing: becomes weaker BIOE 3200 - Fall 2014
Editor's Notes
- Stress/strain graphs – elastic region, E = slope (stiffness); Hooke’s Law (elastic materials like springs); beyond yield point, plastic deformation, elastic strain + plastic strain = total ε “2% Yield” – the point at which if the load is removed, all but 2% of the deformation is recovered Define LEHI material: Linear stress-strain behavior; Elastic (no dissipation of energy; load/unload curve are the same); Homogeneous (same material behavior throughout body; Isotropic (same material properties in all directions)
- Trabecular bone E = 15 GPa; Cortical bone E = 20 GPa; Esteel = 200 GPa; polymers, E < 1
- Polyethylene (HDPE) – common implant material: E = about 0.8
- Discuss factors contributing to anisotropic properties of bone; if stress is the same, why would strain be different in different orientations?
- Be careful when citing material properties for bone; Only valid for bone with the same microstructure and in the same environment as the test specimen