Highlights
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This study evaluates the flexural strength, Weibull modulus, and fracture mode of ceramic structures obtained by the CAD-on technique.
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This study tested the hypothesis that trilayer and monolithic structures show similar values for the evaluated properties.
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Monolithic and trilayer specimens showed similar mean flexural strengths, characteristic strengths and Weibull moduli.
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Considering the CAD-on technique, the trilayer structures showed greater fracture toughness than the monolithic zirconia specimens.
Abstract
Objective
To evaluate the flexural strength, Weibull modulus, fracture toughness, and failure behavior of ceramic structures obtained by the CAD-on technique, testing the null hypothesis that trilayer structures show similar properties to monolithic structures.
Methods
Bar-shaped (1.8 mm × 4 mm × 16 mm) monolithic specimens of zirconia (IPS e.max ZirCAD – Ivoclar Vivadent) and trilayer specimens of zirconia/fusion ceramic/lithium dissilicate (IPS e.max ZirCAD/IPS e.max CAD Crystall./Connect/IPS e.max CAD, Ivoclar Vivadent) were fabricated ( n = 30). Specimens were tested in flexure in 37 °C deionized water using a universal testing machine at a crosshead speed of 0.5 mm/min. Failure loads were recorded, and the flexural strength values were calculated. Fractography principles were used to examine the fracture surfaces under optical and scanning electron microscopy. Data were statistically analyzed using Student’s t -test and Weibull statistics ( α = 0.05).
Results
Monolithic and trilayer specimens showed similar mean flexural strengths, characteristic strengths, and Weibull moduli. Trilayer structures showed greater mean critical flaw and fracture toughness values than monolithic specimens ( p < 0.001). Most critical flaws in the trilayer groups were located on the Y-TZP surface subjected to tension and propagated catastrophically. Trilayer structures showed no flaw deflection at the interface.
Significance
Considering the CAD-on technique, the trilayer structures showed greater fracture toughness than the monolithic zirconia specimens.
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Introduction
The development of (poly)crystalline dental ceramics, particularly yttrium-oxide tetragonal partially stabilized zirconia (Y-TZP), and the introduction of CAD/CAM (computer-aided design/computer-aided machining) technology have increased the use of metal free restorations in dentistry. CAD/CAM systems rely primarily on three steps: scanning the tooth preparation, data processing and computer designing of the structure, and milling the pre-fabricated blocks. The use of pre-fabricated ceramic blocks and CAD/CAM technique can minimize internal defects and imperfections resulting from other fabrication methods, therefore improving the reliability and providing quality control .
Currently, most all-ceramic restorations are fabricated using a high crystalline content ceramic framework to provide strength and a veneering porcelain offering better esthetics . Studies have reported that all-ceramic restorations suffer from chipping, cracking, or delamination of the porcelain veneer during service . Chipping is the greatest cause of failure for zirconia-based all-ceramic restorations . Yet, all ceramic restorations fabricated by heat-pressing have showed less veneering chipping than restorations obtained by traditional layering .
The failure behavior of multilayered structures is influenced by the fracture toughness and elastic modulus mismatch between the ceramic layers, which result in a significant concentration of tensile stresses across the interface within the higher modulus material . In addition, the residual stresses are related to the materials thermal history, such as the coefficient of thermal expansion (CTE) mismatch between veneer and framework materials, fast heating and cooling rates of the restoration, and differences in the thermal diffusivity of the materials .
Lithium disilicate glass–ceramic was introduced to improve the mechanical behavior of feldsphatic porcelains and it has been suggested as an alternative veneering material for Y-TZP . Recently, a new technique named “CAD-on” was developed to produce all-ceramic crowns and bridges using a Y-TZP framework and a lithium disilicate ceramic veneer, which are both fabricated by the CAD–CAM technology. A fusion ceramic is used to bond the framework and the veneer structures. As a fairly new method, the literature is deficient on the multilayer structure obtained by the CAD-on technique.
Most all-ceramic restorations are multilayer structures and should be evaluated as such. Thermal residual stresses generated during the firing process, may induce crack propagation resulting in porcelain chipping or delamination. Such phenomenona can only be observed in multilayer structures . The material under tension and the interaction between the ceramic layers may affect the strength and the failure mode of multilayer structures .
Therefore, the aim of this study was to evaluate the flexural strength, the reliability, the fracture toughness, and the failure behavior of the ceramic structures obtained by the CAD-on technique, testing the null hypothesis that multilayer and monolithic structures show similar values for the evaluated properties.
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