Survival Predictions of Ceramic Crowns Using Statistical Fracture Mechanics

• Published in: Journal of dental research Vol. 96; no. 5; pp. 509 - 515
• Main Authors: Nasrin, S., Katsube, N., Seghi, R.R., Rokhlin, S.I.
• Format: Journal Article
• Language: English
• Published: Los Angeles, CA SAGE Publications 01.05.2017; SAGE PUBLICATIONS, INC
• Subjects: Accuracy; Ceramics - chemistry; Computer Simulation; Crowns; Dental Porcelain - chemistry; Dental Restoration Failure; Dental Stress Analysis; Dentists; Failure; Finite Element Analysis; Finite element method; Fracture mechanics; Lithium; Mastication; Metal fatigue; Probability; Research Reports; Statistical prediction; Stress analysis; Survival; Survival analysis; Teeth; Yttrium; Zirconia; mathematical modeling; computer simulation; mastication; finite element analysis; minimally invasive dentistry; stress analysis
• ISSN: 0022-0345; 1544-0591
• DOI: 10.1177/0022034516688444

This work establishes a survival probability methodology for interface-initiated fatigue failures of monolithic ceramic crowns under simulated masticatory loading. A complete 3-dimensional (3D) finite element analysis model of a minimally reduced molar crown was developed using commercially available hardware and software. Estimates of material surface flaw distributions and fatigue parameters for 3 reinforced glass-ceramics (fluormica [FM], leucite [LR], and lithium disilicate [LD]) and a dense sintered yttrium-stabilized zirconia (YZ) were obtained from the literature and incorporated into the model. Utilizing the proposed fracture mechanics–based model, crown survival probability as a function of loading cycles was obtained from simulations performed on the 4 ceramic materials utilizing identical crown geometries and loading conditions. The weaker ceramic materials (FM and LR) resulted in lower survival rates than the more recently developed higher-strength ceramic materials (LD and YZ). The simulated 10-y survival rate of crowns fabricated from YZ was only slightly better than those fabricated from LD. In addition, 2 of the model crown systems (FM and LD) were expanded to determine regional-dependent failure probabilities. This analysis predicted that the LD-based crowns were more likely to fail from fractures initiating from margin areas, whereas the FM-based crowns showed a slightly higher probability of failure from fractures initiating from the occlusal table below the contact areas. These 2 predicted fracture initiation locations have some agreement with reported fractographic analyses of failed crowns. In this model, we considered the maximum tensile stress tangential to the interfacial surface, as opposed to the more universally reported maximum principal stress, because it more directly impacts crack propagation. While the accuracy of these predictions needs to be experimentally verified, the model can provide a fundamental understanding of the importance that pre-existing flaws at the intaglio surface have on fatigue failures.