Fracture resistance of metal-free composite crowns–effects of fiber reinforcement, thermal cycling, and cementation technique

The improved mechanical properties of contemporary composites have resulted in their extensive use for the restoration of posterior teeth. However, the influence of fiber reinforcement, cementation technique, and physical stress on the fracture resistance of metal-free crowns is unknown. This in vit...

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Bibliographic Details
Published in:The Journal of prosthetic dentistry 2004-09, Vol.92 (3), p.258-264
Main Authors: Lehmann, Franziska, Eickemeyer, Grit, Rammelsberg, Peter
Format: Article
Language:English
Subjects:
Air Abrasion, Dental
Cementation - methods
Composite Resins - chemistry
Crowns
Dental Materials - chemistry
Dental Restoration Failure
Dentistry
Glass - chemistry
Glass Ionomer Cements - chemistry
Humans
Magnesium Oxide - chemistry
Materials Testing
Polycarboxylate Cement - chemistry
Resin Cements - chemistry
Statistics, Nonparametric
Stress, Mechanical
Surface Properties
Thermodynamics
Tooth Preparation
Zinc Oxide - chemistry
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Summary:The improved mechanical properties of contemporary composites have resulted in their extensive use for the restoration of posterior teeth. However, the influence of fiber reinforcement, cementation technique, and physical stress on the fracture resistance of metal-free crowns is unknown. This in vitro study evaluated the effect of fiber reinforcement, physical stress, and cementation methods on the fracture resistance of posterior metal-free Sinfony crowns. Ninety-six extracted human third molars received a standardized tooth preparation: 0.5-mm chamfer preparation and occlusal reduction of 1.3 to 1.5 mm. Sinfony (nonreinforced crowns, n=48) and Sinfony-Vectris (reinforced crowns, n=48) crowns restoring original tooth contour were prepared. Twenty-four specimens of each crown type were cemented, using either glass ionomer cement (GIC) or resin cement. Thirty-two crowns (one third) were stored in humidity for 48 hours. Another third was exposed to 10,000 thermal cycles (TC) between 5°C and 55°C. The remaining third was treated with thermal cycling and mechanical loading (TCML), consisting of 1.2 million axial loads of 50 N. The artificial crowns were then vertically loaded with a steel sphere until failure occurred. Significant differences in fracture resistance (N) between experimental groups were assessed by nonparametric Mann-Whitney U-test (α=.05). Fifty percent of the Sinfony and Sinfony-Vectris crowns cemented with glass ionomer cement loosened after thermal cycling. Thermal cycling resulted in a significant reduction in the mean fracture resistance for Sinfony crowns cemented with GIC, from 2037 N to 1282 N ( P=.004). Additional fatigue produced no further effects. Fiber reinforcement significantly increased fracture resistance, from 1555 N to 2326 N ( P=.001). The minimal fracture resistance was above 600 N for all combinations of material, cement and loading. Fracture resistance of metal-free Sinfony crowns was significantly increased by fiber reinforcement. Adhesive cementation may be recommended to avoid cementation failure.
ISSN:0022-3913
1097-6841
DOI:10.1016/j.prosdent.2004.05.014