Stress Distribution Around Single Short Dental Implants: A Finite Element Study

Bhat, Vidya; Premkumar, Priyanka; Shenoy, Kamalakanth

doi:10.1007/s13191-014-0390-y

Cited by 20 publications

(12 citation statements)

References 17 publications

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“…Assessing the effect of the axial force, was detected the distribution of uniform stress in peri-implant bone without concentrations in a specific surface area of the implant [24,25,27,28,36]. These FEA findings are close to results of in vivo studies.…”

Section: Discussionsupporting

confidence: 68%

“…Also, implant design characteristics were described as factors causing the stress. The alteration of stress was related with implant length [21,24,29], width [21,25,26,28-31], macro-relief as thread [28,32], and micro-relief as porosity [27]. Some of the articles emphasized that stress changes were caused by platform switching connection [20-22,33].…”

Section: Resultsmentioning

confidence: 99%

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The Prosthetic Influence and Biomechanics on Peri-Implant Strain: a Systematic Literature Review of Finite Element Studies

Maminskas¹,

Puišys²,

Kuoppala³

et al. 2016

JOMR

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ObjectivesTo systematically review risks of mechanical impact on peri-implant strain and prosthetic influence on stability across finite element studies.Material and MethodsAn online literature search was performed on MEDLINE and EMBASE databases published between 2011 and 2016. Following keywords tiered screening and selection of the title, abstract and full-text were performed. Studies of finite element analysis (FEA) were considered for inclusion that were written in English and revealed stress concentrations or strain at peri-implant bone level.ResultsThere were included 20 FEA studies in total. Data were organized according to the following topics: bone layers, type of bone, osseointegration level, bone level, design of implant, diameter and length of implant, implant-abutment connection, type of supra-construction, loading axis, measurement units. The stress or strain at implant-bone contact was measured over all studies and numerical values estimated. Risks of overloading were accented as non-axial loading, misfits, cantilevers and the stability of peri-implant bone was related with the usage of platform switch connection of abutment.ConclusionsPeri-implant area could be affected by non-axial loading, cantilever prosthetic elements, crown/implant ratio, type of implant-abutment connection, misfits, properties of restoration materials and antagonistic tooth. The heterogeneity of finite element analysis studies limits systematization of data. Results of these studies are comparable with other findings of in vitro, in vivo, prospective and retrospective studies.

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Section: Discussionsupporting

confidence: 68%

Section: Resultsmentioning

confidence: 99%

The Prosthetic Influence and Biomechanics on Peri-Implant Strain: a Systematic Literature Review of Finite Element Studies

Maminskas¹,

Puišys²,

Kuoppala³

et al. 2016

JOMR

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“…Heat-cured resin was used for fabricating the models as its modulus of elasticity is closer to natural cancellous bone. [ 9 10 11 ] The models were designed with a slit in the center of the base to simulate the L-shape and the flexion of the mandible. Implant analogs of dimension 3.75 mm × 11.5 mm were placed in the following tooth positions; 36, 33, 43, 46.…”

Section: Discussionmentioning

confidence: 99%

Effect of joining the sectioned implant-supported prosthesis on the peri-implant strain generated in simulated mandibular model

Singh

Nair

Shetty

2017

J Indian Prosthodont Soc

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Aim:The aim of this study is to evaluate the strain developed in simulated mandibular model before and after the joining of an implant-supported screw-retained prosthesis by different joining techniques, namely, arc welding, laser welding, and soldering.Materials and Methods:A specimen simulating a mandibular edentulous ridge was fabricated in heat-cured acrylic resin. 4-mm holes were drilled in the following tooth positions; 36, 33, 43, 46. Implant analogs were placed in the holes. University of California, Los Angeles, abutment was attached to the implant fixture. Eight strain gauges were attached to the acrylic resin model. Six similar models were made. Implant-supported screw-retained fixed prosthesis was fabricated in nickel-chromium alloy. A load of 400 N was applied on the prosthesis using universal testing machine. Resultant strain was measured in each strain gauge. All the prostheses were sectioned at the area between 36 and 33, 33 and 43, and 43 and 46 using 35 micrometer carborundum disc, and strain was measured in each strain gauge after applying a load of 400 N on the prosthesis. Specimens were joined by arc welding, soldering, and laser welding. After joining, a load of 400 N was applied on each prosthesis and the resultant strain was measured in each strain gauge.Results:Highest mean strain values were recorded before sectioning of the prostheses (889.9 microstrains). Lowest mean strain values were recorded after sectioning the prosthesis and before reuniting it (225.0 microstrains).Conclusions:Sectioning and reuniting the long-span implant prosthesis was found to be a significant factor in influencing the peri-implant strain.

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“…Many current in vivo and in vitro studies have tried to assess the impact of implant dimensions on the stress transmitted to the peri-implant tissue but have yet to reach a clear conclusion on this complex matter. [ 4 5 6 7 8 ] Some studies have reported that a larger implant may lead to smaller stress values in the peri-implant bone. [ 5 6 7 ] However, other studies show that smaller implants used in resorbed mandibles have a comparable long-term survival rate and stress values to larger implants.…”

Section: Introductionmentioning

confidence: 99%

“…[ 4 5 6 7 8 ] Some studies have reported that a larger implant may lead to smaller stress values in the peri-implant bone. [ 5 6 7 ] However, other studies show that smaller implants used in resorbed mandibles have a comparable long-term survival rate and stress values to larger implants. [ 4 5 6 ] Furthermore, there is a lack of studies on the importance of bone geometry and its influence on the implant induced stress at the crestal bone level, since implant dimensions, stress, and bone geometry are all inter-related and should not be studied separately.…”

Section: Introductionmentioning

confidence: 99%

Influence of implant dimensions in the resorbed and bone augmented mandible: A finite element study

Forna

Moldoveanu

2020

Contemp Clin Dent

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Aims: The scope of this study was to analyze the influence of clinically feasible implant diameter and length on the stress transmitted to the peri-implant bone in the case of a resorbed and bone augmented mandible through finite element analysis. Settings and Design: The study was carried out in silico . Subjects and Methods: Resorbed and bone-augmented 3D models were derived from in vivo cone-beam computed tomography scans of the same patient. Corresponding implant systems were modeled with the diameter ranging from 3.3 to 6 mm and length ranging from 5 to 13 mm, and masticatory loads were applied on the abutment surface. Statistical Analysis Used: None. Results: In the bone augmented ridge, maximum stress values in the peri-implant region drastically decreased only when using implants of a diameter of 5 mm and 6 mm. Implants up to 4 mm in diameter led to comparable stress values with the ones obtained in the resorbed ridge, when using the larger implants. The increase of length reduced stress in the resorbed mandible, whereas in the bone augmented model, it led to small variations only in implants up to 4 mm in diameter. Conclusions: It was concluded that bone augmentation provides the optimal framework for clinicians to use larger implants, which, in turn, reduces stress in the peri-implant region. Diameter and length play an equally important role in decreasing stress. Implant dimensions should be carefully considered with ridge geometry.

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Stress Distribution Around Single Short Dental Implants: A Finite Element Study

Cited by 20 publications

References 17 publications

The Prosthetic Influence and Biomechanics on Peri-Implant Strain: a Systematic Literature Review of Finite Element Studies

The Prosthetic Influence and Biomechanics on Peri-Implant Strain: a Systematic Literature Review of Finite Element Studies

Effect of joining the sectioned implant-supported prosthesis on the peri-implant strain generated in simulated mandibular model

Influence of implant dimensions in the resorbed and bone augmented mandible: A finite element study

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