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This is an open access journal, and articles are distributed under the terms of the Creative Commons Attribution-NonCommercial-ShareAlike 4.0 License, which allows others to remix, tweak, and build upon the work non-commercially, as long as appropriate credit is given and the new creations are licensed under the identical terms.
The present study aimed to evaluate the stress distribution of porous tantalum implant and titanium solid implant assisted overdenture (IAO) in mandibular bone by utilizing three-dimensional (3D) finite element (FE) analysis.
In this FE study, an existing cone-beam volumetric tomography scan of a patient without any maxillofacial anomaly with an available acceptable IAO for mandible was used to attain the compartments of a completely edentulous mandible. Zimmer trabecular implants and locator attachment systems were selected as the case group (Model B), and Zimmer Screw-Vent implants and locator attachment system were chosen for the control (Model A), as overdenture attachments in the present study. The mandibular overdenture was scanned and digitized as a FE model. Two 3D FE models were designed as edentulous lower jaws, each with four implants in the anterior section of the mandible. Three forms of loads were directed to the IAO in each model: Vertical loads on the left first molar vertical molar (VM). Vertical loads on the lower incisors (VI). Inclined force buccolingually applied at left first molar (IM).
Under all loading conditions, the maximum strain values in peri-implant bone in Model A were less than Model B. Under VI, the greatest stress value around abutments in both models was about 2–3 times higher than the other loads. Under VM and IM loads, no significant difference was observed between models.
Using trabecular metal implants instead of solid implants reduces strain values around both cortical and trabecular bone.
Edentulous patients with mandibular bone resorption deal with the problem of adjustment to mastication and report disappointment with their conventional full dentures regularly.
Nowadays, locator attachments have received a lot of attention, due to its self-alignment, satisfactory retention, and minimum height requirements. In addition, nonsplinting implant is necessary for locator attachment system and is shown to provide superior retention, compared to other stud attachments for overdentures, which can address an increased load to the implants.
Recently, dental implants have been introduced with porous tantalum parts.
Hypothetically, this porous tantalum trabecular metal™ added to conventional titanium implants may function as a helpful choice for patients with a less dense bone.
Finite element analysis (FEA) is considered a method for finding a solution to a multifaceted mechanical problem by separating the problem domain into a pool of more modest domains.
The application of porous tantalum implants has been emphasized due to the benefits of IAO in edentulous patients, as well as the problems and challenges related to the success of titanium implants for treating patients with poor bone quality. However, the data are not enough regarding the behavior and function of these implants. Thus, further studies should be conducted for a better understanding of the mechanical properties among these types of implants. Therefore, the present study aimed to evaluate the stress distribution of tantalum porous implant and titanium solid IAO in mandibular bone by utilizing three-dimensional (3D) FEA.
Model design
In this FE study, an existing cone-beam volumetric tomography (CBVT) scan of a patient without any maxillofacial anomaly and average craniofacial proportions with an available acceptable IAO for mandible was used to attain the compartments of a completely edentulous mandible. Then, the CBVT scanning files were imported into Mimics10.0 (Materialise, Leuven, Belgium).
Zimmer trabecular implants (Zimmer Dental trabecular metal implant, TMM4B10, 4.1 mm × 10 mm, Zimmer Dental, Carlsbad, USA) and locator attachment systems (LOCATOR abutment, TLOC3/4, 3.5 mm × 4.1 mm, Zimmer Dental, Carlsbad, USA) were selected as the case group, and Zimmer Screw-Vent implants (Zimmer tapered Screw-Vent implant, TSVM4B10, 4.1 mm × 10 mm, Zimmer Dental, Carlsbad, USA) and locator attachment system (LOCATOR abutment, TLOC3/4, 3.5 mm × 4.1 mm, Zimmer Dental, Carlsbad, USA) were chosen for the control, as overdenture attachments in the present study. The size of the implants and their attachments for both models was 4.1 mm × 10 mm and 3.5 mm × 4.1 mm (width × length), respectively.
The implant-abutment complex was digitized using the Optical digitizing system ATOS II (GOM, Braun-Schweig, Germany). The mandibular overdenture was scanned and modeled as a wax rim with a denture base omitting the teeth to make the FE model simpler, as the 3D geometries of the lower jaw bone and prosthetic units were modeled in SolidWorks 2015 (Solidworks Corporation, MA, USA).
In addition, Abaqus 6.9 (Dassault Systems Simulia Corp, Providence, RI, USA) was used to mesh the structures of the lower jaw, overdenture, implant, and locator systems. Two 3D FE models were designed as edentulous lower jaws, each with four implants in the anterior section of the mandible in the interforaminal region to retain an overdenture. The implants were vertically placed and distributed between mental foramina at least 5 mm mesial to the mental foramen, and 10 mm distance to each other.
The models were meshed with 3D four-node tetrahedron elements. The overall numbers of elements and nodes in Model A are 192,409 and 272,478, and in Model B are 170,470 and 242,201, respectively
(a) solid fixture; (b) trabecular fixture; (c) fixtures inserted in mandibular bone; (d and e) finite element models of locator attachment overdenture supported by solid and trabecular metal implant.
Material characteristics
The edentulous jaw was united a 2 mm continuous cortical bone layer around a cancellous bone core with D2 (Hounsfield number of 850–1250) density, covered by a 1 mm-thick mucosa. The locator attachment system included abutment, nylon replacement male, and titanium cap. The abutment and cap were made of Ti6Al4V titanium alloy, as it is the case for the implant. The material properties of the cortical and cancellous bone, mucosa, and prosthetic units were determined from the amounts obtained from the literature
Contact management
Implants were considered entirely as osseointegrated. Thus, a mechanically flawless boundary was supposed to be between implant and bone. However, the boundary between the overdenture and the mucosa was not immobile while functioning. Instead, the overdenture was able to rotate and slide on the mucosa in various directions. To mimic this dislodgment, we assumed that sliding friction existed between the overdenture and mucosa. The coefficient of sliding friction between the overdenture and mucosa was set as 0.334. The models were restrained at the nodes on the mesial and distal bone in all degrees of freedom.
Loading conditions
Three forms of load were directed to the overdenture in each model to mimic functional loading as follows:
100 N vertical loads on the left first molar (VM)
100 N vertical loads on the lower incisors (VI) 100 N, 45° angled force buccolingually applied at the center of the left first molar (IM).
Strain distribution in peri-implant cortical bone
Strain distribution in the bone under VI loading condition. (a) Model A; (b) Model B. Colors indicate the level of strain from dark blue (lowest) to red (highest). The arrows show the sites with peak strain values. Strain distribution in the cortical bone under VM loading condition. (a) Model A; (b) Model B. Colors indicate the level of strain from dark blue (lowest) to red (highest). The arrows show the sites with peak strain values. Strain distribution in the cortical bone under IM loading condition. (a) Model A; (b) Model B. Colors indicate the level of strain from dark blue (lowest) to red (highest). The arrows show the sites with peak strain values.
Stress in abutments
The maximum stress values in the abutments subjected to three loading conditions in each model are shown in
Pressure on the mucosa
Pressure distribution on the mucosa of Model A under a VI (a), VM (b), IM (c) load (the cold tone describes the area - where contact with the denture was close and tight, while the warm tone presents the area where the denture is tilted and detached from the mucosa). Pressure distribution on the mucosa of Model B under the VI (a), VM (b), IM (c) load (the cold tone describes the area where contact with the denture was close and tight, while the warm tone presents the area where the denture tilted and separated from the mucosa).
Under VM and IM loads, no significant difference was observed between models, but the pressure on the mucosa was higher in Model B under VI load.
The present study aimed to decide on the ideal implant design to support an overdenture in various loading conditions. Based on the results, the loading site was the most important parameter affecting the stress distribution in the whole system. Further, the inclined load on molar teeth induced higher stress levels on the cortical bone around the closest implant to the load site in both models, while vertical loads on the first molar tooth produced the lowest stress. Liu et al. and Chang et al. reported similar results in their studies.
The FEA result biologically revealed acceptable strain values in the bone surrounding the implants subjected to VI and VM loading conditions given that the mentioned value is below the biological resistance limits of bone, which is 2500 με. However, when the models were subjected to IM loading conditions, a pathologic strain value around cortical bone was evident which may cause micromovements at the bone-implant interface, leading to the occurrence of marginal bone loss. Jingyin et al. reported that the maximum strain value in the peri-implant bone under IM loading conditions was lower than 2500 με. This controversy is probably caused by different jaw model designs and its effect on implant position.
Assessing the maximum stresses on the cortical and cancellous bone units revealed that greatest von Mises stresses on the cortical bone segments were much higher than the von Mises stresses on the cancellous bone segment. It means that the cortical bone segment provides superior support for the implant than the trabecular segment. Due to the tight contact between the cortical bone and implant, the loading applied to the implant is mostly transmitted into the thin cortical bone layer, which explains the clinical marginal bone loss around the implants. However, the results of the present study indicated that trabecular implants can help a better stress distribution between cortical and trabecular bone and can be a promising alternative for improved implant survival rate due to their low elastic modulus.
As described in the study of Topkaya and Solmaz, the stresses in the bone around the implants were found to be higher than the stresses measured on the jawbone. This could be explained by the high elastic modulus of the Ti6Al4V implant material, compared to the cortical and trabecular bone, which may decrease the elastic modulus of the trabecular metal implants leading to better stress distribution at the implant periphery.
In addition, under VI, which simulated the act of cutting food with anterior teeth, the largest stress value in the abutments in both models was 2–3 times higher than those in the other three models, indicating that possible damage to the abutments may happen more easily subjected to VI load.
In previous studies, the boundary between the denture and the mucosa was supposed to be immobile for simplifying modeling and computations.
Based on the results, the largest pressure on the mucosa was recorded under IM loading conditions at the lateral side of the posterior region in both models. The second maximum pressure on the mucosa occurred under VI loading, due to the rotation of overdenture on the labial aspect of the mandibular ridge. In this regard, the results are in line with the study of Liu et al. Except for VI load, the change in the implant type made no difference in pressure on the mucosa. The largest pressure on mucosa under VI load was higher in Model B.
The FE models designed for the present study allows for representing a more comprehensive and complex geometry. On the other hand, the innate limitations of the FEA considering strain distribution should be highlighted.
Based on the results, the following conclusions were made:
First, applying trabecular metal implant instead of solid implants reduced strain values around the both cortical and trabecular bone Second, IM load-induced greater stress values in peri-implant bone in both models Third, stress concentration on locator attached to reticular implant was significantly less than locator attachment on solid implants.
Finally, no significant difference was observed in pressure on the mucosa between trabecular and solid implants.
Acknowledgment
This study was conducted based on a grant from the Tabriz University of Medical Science. The authors declare no conflict(s) of interest related to the publication of this study.
Financial support and sponsorship
This study was conducted based on a grant from Tabriz University of Medical Science.
Conflicts of interest
The authors of this manuscript declare that they have no conflicts of interest, real or perceived, financial or non-financial in this article.