Effect of three different veneering techniques on the stress distribution and in vitro fatigue behavior of core-veneer all-ceramic fixed partial dentures.

Alexandre Luiz Souto Borges,Anna Karina Figueiredo Costa,João Paulo Mendes Tribst,Alana Barbosa Alves Pinto,Amanda Maria De Oliveira Dal Piva

doi:10.34172/joddd.2021.032

Alexandre Luiz Souto Borges, Anna Karina Figueiredo Costa + Show 3 more

Open Access

https://doi.org/10.34172/joddd.2021.032

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Abstract

Background. The present study aimed to evaluate the influence of the veneering technique on the tensile stress distribution and survival of full-ceramic fixed dental prostheses (FDPs). Methods. A three-dimensional model of an FDP was modeled on a second premolar and a second molar with a pontic between them for finite element analysis (FEA). The groups were divided according to the veneering technique: conventional stratification, rapid layer, and CAD-on techniques. A mesh control test determined the number of elements and nodes. The materials’ properties were attributed to each solid component with isotropic, homogeneous, and linear elastic behavior. For the in vitro fatigue test (n=30), the FDPs were cemented on dentin analog abutments and submitted to 2×106 mechanical cycles (100 N at 3 Hz). Results. Maximum principal stress showed that the connector between the pontic and the second molar concentrated higher stresses, regardless of the techniques: Rapid layer (6 MPa) > CAD-on (5.5 MPa) > conventional stratification (4 MPa). The conventional stratification technique concentrated high stresses at the interface between the framework and veneering ceramic (2 MPa), followed by the rapid layer (1.8 MPa) and CAD-on (1.5 MPa) techniques. The crowns fabricated using the rapid layer and CAD-on techniques exhibited a 100% survival rate, while the conventional stratification group had 0% survival. Conclusion. Even with similar stress distribution between the veneering techniques, the conventional stratification technique was more prone to failure under fatigue due to higher defects incorporated than CAD-on and rapid layer techniques.

Highlights

All-ceramic restorations are increasingly indicated as an alternative to full-metal or metal-ceramic prostheses.[1,2] All-ceramic restorations can provide excellent mimicry of the optical properties of natural teeth and present adequate biocompatibility.[3]
This study aimed to evaluate the influence of three different veneering techniques on the tensile stress distribution and survival of full-ceramic fixed dental prostheses (FDPs)
This study demonstrated that the technique used to create the interface between veneering ceramic and yttria-stabilized tetragonal zirconia polycrystal (Y-TZP) core could affect FDP survival

Summary

Introduction

All-ceramic restorations are increasingly indicated as an alternative to full-metal or metal-ceramic prostheses.[1,2] All-ceramic restorations can provide excellent mimicry of the optical properties of natural teeth and present adequate biocompatibility.[3] Polished or glazed dental ceramics accumulate less biofilm,[4] are less prone to failure,[5] and exhibit low thermal conductivity associated with high abrasion resistance and color stability.[6,7] Despite these favorable properties, there is concern regarding the fracture resistance of all-ceramic restorations in situations where masticatory loads are higher, such as fixed partial dentures in the posterior region. Even with similar stress distribution between the veneering techniques, the conventional stratification technique was more prone to failure under fatigue due to higher defects incorporated than CAD-on and rapid layer techniques

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