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Figure 12. Equivalent stresses at (a) the neck and...

Figure 12. Equivalent stresses at (a) the neck and (b) the tip of the implant. Figure 12. Equivalent stresses at (a) the neck and (b) the tip of the implant.

Figure 11. The distribution of equivalent stress (...

Figure 11. The distribution of equivalent stress (MPa) around the first molar. Figure 11. The distribution of equivalent stress (MPa) around the first molar.

Figure 10. Displacement in the inferior-superior d...

Figure 10. Displacement in the inferior-superior direction (z-axis). (a) The contact model and (b) the fixation model. Figure 10. Displacement in the inferior-superior direction (z-axis). (a) The contact model and (b) the fixation model.

Figure 9. Displacement in the mesiodistal directio...

Figure 9. Displacement in the mesiodistal direction (y-axis). (a) The contact model and (b) the fixation model. Figure 9. Displacement in the mesiodistal direction (y-axis). (a) The contact model and (b) the fixation model.

Figure 8. Displacement in the buccolingual directi...

Figure 8. Displacement in the buccolingual direction (x-axis). (a) The contact model and (b) the fixation model. Figure 8. Displacement in the buccolingual direction (x-axis). (a) The contact model and (b) the fixation model.

Figure 7. The displacement of the three implants. ...

Figure 7. The displacement of the three implants. (M) Mesial side, (D) Distal side, (B) Buccal side, and (L) Lingual side are shown. Figure 7. The displacement of the three implants. (M) Mesial side, (D) Distal side, (B) Buccal side, and (L) Lingual side are shown.

Figure 6. Implant displacement under loading condi...

Figure 6. Implant displacement under loading conditions. Figure 6. Implant displacement under loading conditions.

Figure 5. An FEA model. (a) Buccal loading, (b) ce...

Figure 5. An FEA model. (a) Buccal loading, (b) central loading, and (c) lingual loading are shown. Figure 5. An FEA model. (a) Buccal loading, (b) central loading, and (c) lingual loading are shown.

Figure 4. An experimental model loading test. : A ...

Figure 4. An experimental model loading test. Figure 4. An experimental model loading test.

Figure 3. An experimental model. (a) Buccal loadin...

Figure 3. An experimental model. (a) Buccal loading, (b) central loading, and (c) lingual loading are shown. Figure 3. An experimental model. (a) Buccal loading, (b) central loading, and (c) lingual loading are shown.

Figure 2. Three implants were embedded in an artif...

Figure 2. Three implants were embedded in an artificial mandible. Figure 2. Three implants were embedded in an artificial mandible.

Figure 1. An artificial mandible. : A biomechanica...

Figure 1. An artificial mandible. Figure 1. An artificial mandible.

Table 7 Coefficients o...

Model Loading points Buccal loading Central loading Lingual loading Average The neck of the implant  Contact model   No. 34 9.62 ...

Table 6 Three-way ANOV...

Source Sum of squares df Mean squared F value p value The neck of the implant  A: Boundary conditions 64.725 1 ...

Table 5 Three-way ANOV...

Source Sum of squares df Mean squared F value p value Contact model  A: Observed area 22.324 1 22.324 ...

Table 4 Three-way ANOV...

Source Sum of squares df Mean squared F value p value Contact model  A: Observed area 116.630 1 116.63...

Table 3 Three-way ANOV...

Source Sum of squares df Mean squared F value p value Contact model  A: Observed area 16.346 1 16.346 ...

Table 2 Coefficients of ...

Model Loading Average Buccal loading Central loading Lingual loading Experimental model 2.49 4.76 4.90 4.05 ...

Table 1 Mechanical prope...

Material Young’s modulus (MPa) Poisson ratio Artificial cancellous bone 628 0.3 Artificial cortical bone 1,373 ...

About this article : A biomechanical investigation...

Omori, M., Sato, Y., Kitagawa, N. et al. A biomechanical investigation of mandibular molar implants: reproducibility and validity of a finite element analysis model. Int J Implant Dent 1, 10 (2015). https://doi.org/10.1186/s40729-015-0011-5 Download citation Received: 07 January 2015 Accepted: 24 March 2015 Published: 28 April 2015 DOI: https://doi.org/10.1186/s40729-015-...

Rights and permissions : A biomechanical investiga...

Open Access This article is distributed under the terms of the Creative Commons Attribution 4.0 International License (https://creativecommons.org/licenses/by/4.0), which permits use, duplication, adaptation, distribution, and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and in...

Additional information : A biomechanical investiga...

Miyuki Omori, Yuji Sato, Noboru Kitagawa, Yuta Shimura and Manabu Ito declare that they have no competing interests. MO drafted the manuscript. YS contributed advice regarding the manuscript. All authors have read and approved the final manuscript.

Author information : A biomechanical investigation...

Department of Geriatric Dentistry, Showa University, School of Dentistry, 2-1-1 Kitasenzoku, Ota-ku, Tokyo, 145-8515, Japan Miyuki Omori, Yuji Sato, Noboru Kitagawa, Yuta Shimura & Manabu Ito You can also search for this author in PubMed Google Scholar You can also search for this author in PubMed Google Scholar You can also search for this author in PubMed Google Scholar You can also...

Acknowledgements : A biomechanical investigation o...

The authors would like to express their deep appreciation to the teaching staff of the Geriatric Dentistry course at Showa University Dental Hospital for their help and cooperation. This study was supported by a Grant-in-Aid for Scientific Research from the Ministry of Education, Culture, Sports, Science, and Technology (Showa University Grant-in-Aid for Scientific Research (C)) (Grant Number 2546...

References : A biomechanical investigation of mand...

Tada S, Stegaroiu R, Kitamura E, Miyakawa O, Kusakari H. Influence of implant design and bone quality on stress/strain distribution in bone around implants: a 3-dimensional finite element analysis. Int J Oral Maxillofac Implants. 2003;18:357–68. Sevimay M, Turhan F, Kilicarslan MA, Eskitascioglu G. Three-dimensional finite element analysis of the effect of different bone quality on stress distr...

References : A biomechanical investigation of mand...

Matsunaga S, Ide Y. Morphological characteristics of peri-implant trabecular bone using μ-CT and its mechanical evaluation. BONE. 2009;23:289–92 [in Japanese]. Yokoyama M. Modeling techniques and stress analysis in finite element methods. Tokyo: Yokendo; 2007. p. 1–22 [in Japanese]. Sato Y, Shindoi N, Hosokawa R, Tsuga K, Akagawa Y. A biomechanical effect of wide implant placement and offse...

References : A biomechanical investigation of mand...

Morita Y, Qian L, Todo M, Matsushita Y, Arakawa K, Koyano K. Stress and strain distribution analyses of porcine mandibular periodontium by experimental mechanics and finite element analysis. Jpn J Clin Biomech. 2009;30:7–13 [in Japanese]. Taira S. Modern material mechanics. Tokyo: Ohmsha; 2011. p. 235–8 [in Japanese]. Morita Y. Experimental study on displacement and strain distributions arou...

References : A biomechanical investigation of mand...

Frost HM. Wolff’s Law and bone’s structural adaptations to mechanical usage: an overview for clinicians. Angle Orthod. 1994;64:175–88. Duyck J, Rønold HJ, Van Oosterwyck H, Naert I, Vander Sloten J, Ellingsen JE. The influence of static and dynamic loading on marginal bone reactions around osseointegrated implants: an animal experimental study. Clin Oral Implants Res. 2001;12:207–18. Qu...

Abbreviations : A biomechanical investigation of m...

finite element analysis computed tomography coefficient of variation computer-aided design/computer-aided manufacturing analysis of variance

Conclusions : A biomechanical investigation of man...

With the objective of verifying the reproducibility and validity of three-dimensional finite element models, we fabricated finite element models and multiple models in which implants were embedded in artificial mandibles and compared implant displacements under various loading conditions; the results obtained produced the following conclusions: The CVs as calculated from the amount of displacemen...

Discussion : A biomechanical investigation of mand...

The equivalent stress values of the contact model were higher at the implant neck than the tip, and the stress generation range was also broader. However, in the fixation model, the implant neck and tip had substantially equivalent values and the stress generation range was also narrower than that of the contact model. This shows that under immediate loading conditions, there is a high likelihood ...

Discussion : A biomechanical investigation of mand...

It has been reported that when micromovement of an implant occurs, an ingrowth of soft tissue occurs after the implant is embedded; therefore, it is difficult to achieve osseointegration [32-34]. Brunski et al. [35] reported that when immediate loading or early loading is carried out, micromovements of the implant should be controlled to 100 μm or less and excessive movement of the implant not o...

Discussion : A biomechanical investigation of mand...

In the experimental and contact models, the absolute values of displacement under loading were different, but aspects of the displacement under loading conditions caused by differences in the loading points were similar and showed similar tendencies. The correlation coefficient of the two was 0.925, representing a significant and strong correlation (p 

Discussion : A biomechanical investigation of mand...

In the experimental model, an implant cavity 3.0 mm in diameter was formed prior to embedding an implant 3.75 mm in diameter. In theory, the threads were completely mechanically fitted to the artificial mandibular bone. It does not osseointegrate, but does represent the circumstances of immediate loading in a state of full contact with the bone. The contact model reproduced the state of contact ...

Discussion : A biomechanical investigation of mand...

When a three-dimensional FEA is used to analyze the mechanics of peri-implant bone, it is ideal to construct an FEA model that approximates the material properties and structures of an actual mandible. Moreover, the results should be compared with the behavior of an implant in an actual mandible. However, in an actual oral cavity, individual differences exist resulting from bone morphology and phy...

Results : A biomechanical investigation of mandibu...

Central loading resulted in the lowest equivalent stress value, while buccal and lingual loading showed substantially similar values (Figure 12b). In the bone surrounding the implant tip, the loading point was a significant factor for the equivalent stress value (p 

Results : A biomechanical investigation of mandibu...

At all three loading sites, no. 36 had the greatest displacement; the more mesial the implant, the less the displacement, and the distal portions showed a sinking displacement (Figure 10). Central loading resulted in the least displacement; buccal and lingual loading showed substantially similar displacements. Compared with the contact model, the fixation model demonstrated less displacement, but...

Results : A biomechanical investigation of mandibu...

Figure 6 and Table 2 show the results for implant displacement under 100 N of vertical loading at each loading point and in each model. The implant displacement under loading conditions in the experimental model and the two FEA models showed a tendency to exhibit the smallest values under central loading; substantially similar values were exhibited in buccal and lingual loading. Buccal loading...

Methods : A biomechanical investigation of mandibu...

Regarding displacement under loading, a one-way analysis of variance (ANOVA) was used to investigate statistically significant differences between the loading sites. A three-way ANOVA was used to investigate statistically significant differences in three-dimensional implant displacements under loading conditions. The assessment site, dental formula, and loading point were used as intra-subject par...

Methods : A biomechanical investigation of mandibu...

Implant displacement measurements under loading conditions were measured using an Instron-type universal testing machine (Instron‐5500R®, Instron Japan, Kanagawa, Japan) for the experimental model. The experimental models were placed on the worktable of an Instron-type universal testing machine, and compression tests were performed using a conical jig. A vertical load was applied at a rate of 0...

Methods : A biomechanical investigation of mandibu...

The experimental models were fixed in a micro-CT scanner (inspeXio SMX-90CT, SHIMADZU, Kyoto, Japan) and scanned under the following imaging conditions: tube voltage, 90 kV; tube current, 109 nA; and slice thickness, 100 μm. FEA software (Mechanical Finder®, Research Center of Computational Mechanics, Tokyo, Japan) was used to construct three-dimensional FEA models from the resulting computed...

Methods : A biomechanical investigation of mandibu...

An artificial mandibular bone (P9-X.1135, Nissin Dental Products, Kyoto, Japan) with free-end edentulism of the left mandibular first premolar (no. 34), second premolar (no. 35), and first molar (no. 36) was used (Figure 1). The model is composed of a two-layer structure of artificial cortical bone (urethane resin) and artificial cancellous bone (urethane resin foam). Using the anatomical crown ...

Background : A biomechanical investigation of mand...

With the purpose of verifying the reproducibility and validity of a three-dimensional finite element model, the displacements of implants embedded in an experimental model and in three-dimensional FEA models constructed from the experimental model were compared under various loading conditions.

Background : A biomechanical investigation of mand...

Bone remodeling to maintain osseointegration between bone and implant is absolutely essential to ensure favorable results and long-term stability in implant treatment [1,2]. Bone remodeling requires that various stresses generated around the bone caused by the occlusal load applied to the implant be within an appropriate range. Concentrations of stress at the bone-implant interface, which are caus...

Abstract : A biomechanical investigation of mandib...

Three-dimensional finite element analysis (FEA) is effective in analyzing stress distributions around dental implants. However, FEA of living tissue involves many conditions, and the structures and behaviors are complex; thus, it is difficult to ensure the validity of the results. To verify reproducibility and validity, we embedded implants in experimental models and constructed FEA models; implan...