3-D finite element analysis of the effects of post location and loading location on stress distribution in root canals of the mandibular 1st molar

Yoon, Hong Gi; Oh, Hyun Keun; Lee, Dong Hoon; Shin, Joo Hee

doi:10.1590/1678-7757-2016-0406

Cited by 18 publications

(21 citation statements)

References 29 publications

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“…Between the tooth and the fixation cylinder, the contact was considered perfectly bonded. In all groups, the model fixation occurred at the base of the polyurethane cylinder with fixed zero nodal displacements [11], and an axial load of 300 N [16][17][18][19] was applied to the occlusal surface based on the tripoidism concept [20][21][22]. A mesh convergence test (10%) was performed to guarantee that it would not interfere with the results [23].…”

Section: Finite Element Analysis (Fea)mentioning

confidence: 99%

Endocrown restorations: Influence of dental remnant and restorative material on stress distribution

et al. 2018

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Section: Finite Element Analysis (Fea)mentioning

confidence: 99%

Endocrown restorations: Influence of dental remnant and restorative material on stress distribution

et al. 2018

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“…Its use is found in device testing and even tissue-response anticipation to certain devices or forces [35]. Studies have been conducted in general dentistry [36], endodontics [37,38], orthodontics, and especially oral implantology. Any implant test can be simulated (in vitro and in vivo), with almost immediate results and with a fraction of the cost of the physical tests.…”

Section: Introductionmentioning

confidence: 99%

New Dental Implant with 3D Shock Absorbers and Tooth-Like Mobility—Prototype Development, Finite Element Analysis (FEA), and Mechanical Testing

et al. 2019

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Background: Once inserted and osseointegrated, dental implants become ankylosed, which makes them immobile with respect to the alveolar bone. The present paper describes the development of a new and original implant design which replicates the 3D physiological mobility of natural teeth. The first phase of the test followed the resistance of the implant to mechanical stress as well as the behavior of the surrounding bone. Modifications to the design were made after the first set of results. In the second stage, mechanical tests in conjunction with finite element analysis were performed to test the improved implant design. Methods: In order to test the new concept, 6 titanium alloy (Ti6Al4V) implants were produced (milling). The implants were fitted into the dynamic testing device. The initial mobility was measured for each implant as well as their mobility after several test cycles. In the second stage, 10 implants with the modified design were produced. The testing protocol included mechanical testing and finite element analysis. Results: The initial testing protocol was applied almost entirely successfully. Premature fracturing of some implants and fitting blocks occurred and the testing protocol was readjusted. The issues in the initial test helped design the final testing protocol and the new implants with improved mechanical performance. Conclusion: The new prototype proved the efficiency of the concept. The initial tests pointed out the need for design improvement and the following tests validated the concept.

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“…Several factors influence the accuracy of the results of these calculations, such as type, arrangement, and number of elements of structure of interest. [122][123][124][125] In general, the initial steps of the FEM of simulated loads start with creating a finite element model with appropriate mesh density, followed by identifying proper material properties for each component. In later steps, by setting up the loading conditions and boundaries according to the proposed assumptions, the model can be accurately tested.…”

Section: Finite Element Methods (Fem)mentioning

confidence: 99%

“…119 Other laboratory studies use computational (digital) testing methods for analysing and obtaining information about the internal behaviour of the tested specimens such as the finite element method (FEM). [120][121][122][123][124][125] In contrast to experimental investigations on real in vitro or in vivo specimens, FEM has many benefits. It is a repeatable method that might be modified as it is needed, and there are no considerations for ethical approvals.…”

Section: Assessment Of Load-bearing Capacity and Clinical Prediction mentioning

confidence: 99%

“…In the field of dentistry, recent years have witnessed a growing academic interest in FEM as a research tool for analysing stress and deformations on structures of interest such as implants, bone, different kinds of teeth preparations, and post and core restorations. [120][121][122][123][124][125] The FEM of simulated occlusal loads can also be used to optimize the shape of restorations by studying the internal stress within teeth and restorations with different dental materials and designs.…”

Section: Assessment Of Load-bearing Capacity and Clinical Prediction mentioning

confidence: 99%

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Monolithic and semi-monolithic translucent zirconium-dioxide restorations : aspects on design, material and strength

Bakitian¹

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Objective: To evaluate fracture strength of veneered translucent zirconium dioxide crowns designed with different porcelain layer thicknesses. Materials and Methods: Sixty crowns, divided into six groups of 10, were used in this study. Groups were divided according to different thicknesses of porcelain veneer on translucent zirconium dioxide cores of equal thickness (0.5 mm). Porcelain thicknesses were 2.5, 2.0, 1.0, 0.8, 0.5 and 0.3 mm. Crowns were artificially aged before loaded to fracture. Determination of fracture mode was performed using light microscope. Results: Group 1.0 mm showed significantly (p .05) highest fracture loads (mean 1540 N) in comparison with groups 2.5, 2.0 and 0.3 mm (mean 851, 910 and 1202 N). There was no significant difference (p>.05) in fracture loads among groups 1.0, 0.8 and 0.5 mm (mean 1540, 1313 and 1286 N). There were significantly (p .05) more complete fractures in group 0.3 mm compared to all other groups which presented mainly cohesive fractures. Conclusions: Translucent zirconium dioxide crowns can be veneered with minimal thickness layer of 0.5 mm porcelain without showing significantly reduced fracture strength compared to traditionally veneered (1.0-2.0 mm) crowns. Fracture strength of micro-veneered crowns with a layer of porcelain (0.3 mm) is lower than that of traditionally veneered crowns but still within range of what may be considered clinically sufficient. Porcelain layers of 2.0 mm or thicker should be used where expected loads are low only.

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3-D finite element analysis of the effects of post location and loading location on stress distribution in root canals of the mandibular 1st molar

Cited by 18 publications

References 29 publications

Endocrown restorations: Influence of dental remnant and restorative material on stress distribution

Endocrown restorations: Influence of dental remnant and restorative material on stress distribution

New Dental Implant with 3D Shock Absorbers and Tooth-Like Mobility—Prototype Development, Finite Element Analysis (FEA), and Mechanical Testing

Monolithic and semi-monolithic translucent zirconium-dioxide restorations : aspects on design, material and strength

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