Table 1 Material properties
Table 1 Material properties
author: Sho Kayumi,Yoshiyuki Takayama,Atsuro Yokoyama,Nana Ueda | publisher: drg. Andreas Tjandra, Sp. Perio, FISID
Materials
Modulus of elasticity (MPa)
Poisson ratio
Enamel
80,000
0.3
Dentin
17,600
0.25
Inplant (titanium)
117,000
0.32
Superstructure (gold alloy)
94,000
0.3
Cortical bone
14,000
0.3
Cancellous bone
7,900
0.3
Serial posts:
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Effect of bite force in occlusal adjustment of dental implants
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Background : Effect of bite force in occlusal adjustment of dental implants
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Methods : Effect of bite force in occlusal adjustment of dental implants (1)
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Methods : Effect of bite force in occlusal adjustment of dental implants (2)
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Methods : Effect of bite force in occlusal adjustment of dental implants (3)
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Results : Effect of bite force in occlusal adjustment of dental implants (1)
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Results : Effect of bite force in occlusal adjustment of dental implants (2)
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Discussion : Effect of bite force in occlusal adjustment of dental implants (3)
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Discussion : Effect of bite force in occlusal adjustment of dental implants (3)
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Discussion : Effect of bite force in occlusal adjustment of dental implants (4)
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Table 1 Material properties
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Table 2 Size of each gap
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Figure 1. Finite element models (model-I and model-T)
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Figure 2. Boundary conditions to verify the displaceability of teeth
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Figure 3. Load-displacement curves of the springs
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Figure 4. Occlusal adjustment was simulated by altering the load-displacement curves of the springs
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Figure 5. Schematic diagram for each phase of the load-displacement curve
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Figure 6. FE model with natural dentition (model-N). Tooth root is displayed with permeability
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Figure 7. Load-displacement curve of the left canine
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Figure 8. Distribution of the occlusal forces
| Materials | Modulus of elasticity (MPa) | Poisson ratio |
|---|---|---|
| Enamel | 80,000 | 0.3 |
| Dentin | 17,600 | 0.25 |
| Inplant (titanium) | 117,000 | 0.32 |
| Superstructure (gold alloy) | 94,000 | 0.3 |
| Cortical bone | 14,000 | 0.3 |
| Cancellous bone | 7,900 | 0.3 |
- Effect of bite force in occlusal adjustment of dental implants
- Background : Effect of bite force in occlusal adjustment of dental implants
- Methods : Effect of bite force in occlusal adjustment of dental implants (1)
- Methods : Effect of bite force in occlusal adjustment of dental implants (2)
- Methods : Effect of bite force in occlusal adjustment of dental implants (3)
- Results : Effect of bite force in occlusal adjustment of dental implants (1)
- Results : Effect of bite force in occlusal adjustment of dental implants (2)
- Discussion : Effect of bite force in occlusal adjustment of dental implants (3)
- Discussion : Effect of bite force in occlusal adjustment of dental implants (3)
- Discussion : Effect of bite force in occlusal adjustment of dental implants (4)
- Table 1 Material properties
- Table 2 Size of each gap
- Figure 1. Finite element models (model-I and model-T)
- Figure 2. Boundary conditions to verify the displaceability of teeth
- Figure 3. Load-displacement curves of the springs
- Figure 4. Occlusal adjustment was simulated by altering the load-displacement curves of the springs
- Figure 5. Schematic diagram for each phase of the load-displacement curve
- Figure 6. FE model with natural dentition (model-N). Tooth root is displayed with permeability
- Figure 7. Load-displacement curve of the left canine
- Figure 8. Distribution of the occlusal forces