Fig. 8. Maximum von Mises stress value in implant bodies (MPa)
Fig. 8. Maximum von Mises stress value in implant bodies (MPa)
Fig. 7. Von Mises stress distribution in implant bodies. (right: buccal side, left: lingual side)
Fig. 7. Von Mises stress distribution in implant bodies. (right: buccal side, left: lingual side)
Fig. 6. Largest maximum principle stress value in cortical bone (MPa)
Fig. 6. Largest maximum principle stress value in cortical bone (MPa)
Fig. 5. Distribution of the maximum principle stress in the surrounding bone (occlusal view)
Fig. 5. Distribution of the maximum principle stress in the surrounding bone (occlusal view)
Fig. 4. Distribution of the maximum principle stress in the surrounding bone (right: buccal side, left: lingual side)
Fig. 4. Distribution of the maximum principle stress in the surrounding bone (right: buccal side, left: lingual side)
Fig. 3. Assembly of implant and bone models. A static load of 100 N was applied obliquely from the buccal side to the occlusal plane of the superstructure at 30 to the long axis of the implant
Fig. 3. Assembly of implant and bone models. A static load of 100 N was applied obliquely from the buccal side to the occlusal plane of the superstructure at 30 to the long axis of the implant
Fig. 2. Models of different implant body lengths
Fig. 2. Models of different implant body lengths
Fig. 1. Three-dimensional CAD model. (upper: a abutment screw, b superstructure, c implant body; Lower: bone model)
Fig. 1. Three-dimensional CAD model. (upper: a abutment screw, b superstructure, c implant body; Lower: bone model)
Young’s modulus (GPa)Poisson’s ratioReferenceAbutment screw (Ti-6Al-4V)1100.33[19]Superstructure (gold alloy)96.60.35[20]Cortical bone130.3[21]Cancellous bone1.370.3[21]Implant body (cpTi)1100.34 Implant body (TiZr)97.30.36 Table 1 Mechanical properties of each model component
Araki, H., Nakano, T., Ono, S. et al. Three-dimensional finite element analysis of extra short implants focusing on implant designs and materials. Int J Implant Dent 6, 5 (2020). https://doi.org/10.1186/s40729-019-0202-6
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Received: 20 August 2019
Accepted: 11 December 2019
Published: 29 January 2020
DOI: https://doi.org/10.1186/s40729-019-0202-6
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Department of Fixed Prosthodontics, Osaka University Graduate School of Dentistry, Osaka, 565-0871, Japan
Haruka Araki, Tamaki Nakano, Shinji Ono & Hirofumi Yatani
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This research was supported by Grants-in-Aid for Scientific Research T15K204780 and T15K111560 from the Japan Society for the Promotion of Science.
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Within the limitations of this study, the following conclusions were drawn.
The stress distribution in the cortical bone and implant body was smaller in the TL implant than in the BL implant.
The TiZr alloy had a lower elastic modulus than cpTi, and the stress distribution generated in the cortical bone and implant body was also lower.
The stress distribution generated in the cortical bone an...
Clinically, it is generally considered that the crown length increases proportionally when the length of the implant body decreases because of alveolar bone resorption. However, most previous studies performing FEA of short implants have analyzed them with a standard crown length [38]. In this study, the distance from the tip of the implant body to the occlusal plane was standardized to make the a...
The difference in the implant body structure between the submerged and non-submerged implants greatly affected the stress distribution. Since the TL implant body lies above the bone level rather than level with the crestal bone, it was found that the stress concentrates above the apex of the alveolar bone, regardless of the material type. As a result, the maximum stress value in the cortical bone ...
Overloading, which is one of the factors contributing to bone resorption around an implant body, can lead to complications because force is applied beyond the prosthodontic or biological tolerance [23]. It is believed that when stress of a certain magnitude is applied to the bone, microscopic bone destruction occurs resulting in bone resorption [24, 25]. Because implants do not have buffering mech...
The distribution of the maximum principal stress in the cortical bone concentrated on the neck of the implant body. In the TL implants, tensile stress was concentrated on the buccal side and compressive stress on the lingual side. In the BL implants, tensile stress concentration was observed on the lingual side. The distributions were similar between the cpTi and TiZr implants (Figs. 4 and 5). Th...
To validate the accuracy of the FEA model, microstrain of the surrounding bone were compared with the results of in vitro experiment measured with strain gauge [22]. In the literature, it was reported that microstrain of 59.3876 ± 24.7185 μe at the neck of implant and 17.3456 ± 12.9147 μe at the apical occurred in a bovine bone under an oblique load of 120 N. Under the same conditi...
TL and BL three-dimensional computer-aided design (CAD) implant models were created using the CAD function in computer-aided engineering software (SolidWorks 2014, Dassault Systèmes SolidWorks Corporation, MA, USA), and they were created with reference to conical connection implant used clinically. The connection part of superstructure has a tapered 15° conical shape without any special locking ...
Dental implants are widely used as a treatment option to replace a defective prosthesis. In recent years, treatment using short implants, which are ≤ 8 mm in length, has been increasing in cases with vertical bone resorption [1]. It is thought that this will become more popular as the number of patients who require minimally invasive treatment, such as older patients and those with chronic d...
When using short implants, fracture of the implant body and bone resorption are a concern because stress concentrates on and around a short implant. The purpose of this research is to investigate the differences in stress distribution between tissue level (TL) and bone level (BL) implant body designs, and between commercially pure titanium (cpTi) and the newer titanium–zirconium (TiZr) alloy in ...
Within the limitations of this study, the following conclusions were drawn.
The stress distribution in the cortical bone and implant body was smaller in the TL implant than in the BL implant.
The TiZr alloy had a lower elastic modulus than cpTi, and the stress distribution generated in the cortical bone and implant body was also lower.
The stress distribution generated in the cortical bone and ...
Clinically, it is generally considered that the crown length increases proportionally when the length of the implant body decreases because of alveolar bone resorption. However, most previous studies performing FEA of short implants have analyzed them with a standard crown length [38]. In this study, the distance from the tip of the implant body to the occlusal plane was standardized to make the a...
The difference in the implant body structure between the submerged and non-submerged implants greatly affected the stress distribution. Since the TL implant body lies above the bone level rather than level with the crestal bone, it was found that the stress concentrates above the apex of the alveolar bone, regardless of the material type. As a result, the maximum stress value in the cortical bone ...
Overloading, which is one of the factors contributing to bone resorption around an implant body, can lead to complications because force is applied beyond the prosthodontic or biological tolerance [23]. It is believed that when stress of a certain magnitude is applied to the bone, microscopic bone destruction occurs resulting in bone resorption [24, 25]. Because implants do not have buffering mech...
The distribution of the maximum principal stress in the cortical bone concentrated on the neck of the implant body. In the TL implants, tensile stress was concentrated on the buccal side and compressive stress on the lingual side. In the BL implants, tensile stress concentration was observed on the lingual side. The distributions were similar between the cpTi and TiZr implants (Figs. 4 and 5). Th...
To validate the accuracy of the FEA model, microstrain of the surrounding bone were compared with the results of in vitro experiment measured with strain gauge [22]. In the literature, it was reported that microstrain of 59.3876 ± 24.7185 μe at the neck of implant and 17.3456 ± 12.9147 μe at the apical occurred in a bovine bone under an oblique load of 120 N. Under the same conditi...
TL and BL three-dimensional computer-aided design (CAD) implant models were created using the CAD function in computer-aided engineering software (SolidWorks 2014, Dassault Systèmes SolidWorks Corporation, MA, USA), and they were created with reference to conical connection implant used clinically. The connection part of superstructure has a tapered 15° conical shape without any special locking ...
Dental implants are widely used as a treatment option to replace a defective prosthesis. In recent years, treatment using short implants, which are ≤ 8 mm in length, has been increasing in cases with vertical bone resorption [1]. It is thought that this will become more popular as the number of patients who require minimally invasive treatment, such as older patients and those with chronic d...
When using short implants, fracture of the implant body and bone resorption are a concern because stress concentrates on and around a short implant. The purpose of this research is to investigate the differences in stress distribution between tissue level (TL) and bone level (BL) implant body designs, and between commercially pure titanium (cpTi) and the newer titanium–zirconium (TiZr) alloy in ...