In vivo fracture resistance of implant-supported all-ceramic restorations.

STATEMENT OF PROBLEM Because of their specific mechanical properties, all-ceramic restorations demonstrate a lower fracture resistance than ceramic restorations supported by metal substructures. However, advances have been made in the fabrication of high-strength all-ceramic abutments for anterior implants. No previous study has compared the fracture loads between 2 different all-ceramic abutments restored by glass-ceramic crowns. PURPOSE The purpose of this in vitro investigation was to quantify the fracture load of implanted-supported Al(2)O(3) and ZrO(2) abutments restored with glass-ceramic crowns. MATERIALS AND METHODS Two ceramic abutments were tested: an Al(2)O(3) abutment (CerAdapt) and a ZrO(2) abutment (Wohlwend Innovative). The abutments (n = 10) were placed on Brånemark dental implants and prepared for restoration with glass-ceramic crowns (IPS Empress). After fabrication, in accordance with the manufacturer's guidelines, the crowns were bonded to the all-ceramic abutments with a dual-polymerizing resin luting agent. The fracture loads (N) were determined by force application at an angle of 30 degrees by use of a computer-controlled universal testing device. The data were analyzed with the unpaired t test (alpha=.05). RESULTS Statistical analysis showed significant differences between both groups (P=.001) of all-ceramic abutments, with mean fracture load values of 280.1 N (+/- 103.1) for the Al(2)O(3) abutments and 737.6 N (+/- 245.0) for the ZrO(2) abutments. CONCLUSION Within the limitations of this study, both all-ceramic abutments exceeded the established values for maximum incisal forces reported in the literature (90 to 370 N). The ZrO(2) abutments were more than twice as resistant to fracture as the Al(2)O(3)-abutments.

[1]  G E Carlsson,et al.  Functional state, bite force and postural muscle activity in patients with osseointegrated oral implant bridges. , 1979, Acta odontologica Scandinavica.

[2]  L. Pröbster Compressive strength of two modern all-ceramic crowns. , 1992, The International journal of prosthodontics.

[3]  F. Burke,et al.  The effect of different ceramic materials on the fracture resistance of dentin-bonded crowns. , 1977, Quintessence International.

[4]  H Tsuru,et al.  Tissue compatibility and stability of a new zirconia ceramic in vivo. , 1992, The Journal of prosthetic dentistry.

[5]  G. Sjögren,et al.  Clinical examination of leucite-reinforced glass-ceramic crowns (Empress) in general practice: a retrospective study. , 1999, The International journal of prosthodontics.

[6]  C. Piconi,et al.  Zirconia as a ceramic biomaterial. , 1999, Biomaterials.

[7]  S. Tsutsumi,et al.  Effect of magnesia investments in the dental casting of pure titanium or titanium alloys. , 1982, Dental materials journal.

[8]  J. Beumer,et al.  The Branemark implant system : clinical and laboratory procedures , 1990 .

[9]  P Schärer,et al.  Heat-pressed ceramics: technology and strength. , 1992, The International journal of prosthodontics.

[10]  M. Fradeani,et al.  Clinical experience with Empress crowns. , 1997, The International journal of prosthodontics.

[11]  J A Sorensen,et al.  IPS Empress crown system: three-year clinical trial results. , 1998, Journal of the California Dental Association.

[12]  L. Pröbster,et al.  The influence of different cementation modes on the fracture resistance of feldspathic ceramic crowns. , 1997, The International journal of prosthodontics.

[13]  R R Seghi,et al.  Relative flexural strength of six new ceramic materials. , 1995, The International journal of prosthodontics.

[14]  S. Rosenstiel,et al.  Relative fracture toughness and hardness of new dental ceramics. , 1995, The Journal of prosthetic dentistry.

[15]  B. Calès,et al.  Long-term in vivo and in vitro aging of a zirconia ceramic used in orthopaedy. , 1994, Journal of biomedical materials research.

[16]  M Heller,et al.  Mechanical properties and short-term in-vivo evaluation of yttrium-oxide-partially-stabilized zirconia. , 1989, Journal of biomedical materials research.

[17]  N Funduk,et al.  The effect of surface grinding and sandblasting on flexural strength and reliability of Y-TZP zirconia ceramic. , 1999, Dental materials : official publication of the Academy of Dental Materials.

[18]  J. Strub,et al.  Fracture strength of 5 different all-ceramic crown systems. , 1998, The International journal of prosthodontics.

[19]  A. Odén,et al.  Bonding to densely sintered alumina surfaces: effect of sandblasting and silica coating on shear bond strength of luting cements. , 2000, The International journal of prosthodontics.

[20]  M. Kern,et al.  Bonding to alumina ceramic in restorative dentistry: clinical results over up to 5 years. , 1998, Journal of dentistry.

[21]  Theo Fett,et al.  Ceramics: Mechanical Properties, Failure Behaviour, Materials Selection , 1999 .

[22]  D Edelhoff,et al.  Ceramic abutments--a new era in achieving optimal esthetics in implant dentistry. , 2000, The International journal of periodontics & restorative dentistry.

[23]  M. Walter,et al.  Reliability and Properties of Ground Y-TZP-Zirconia Ceramics , 2002, Journal of dental research.

[24]  G. Quinn,et al.  Fracture toughness (KIc) of a dental porcelain determined by fractographic analysis. , 1999, Dental materials : official publication of the Academy of Dental Materials.

[25]  J W Osborn,et al.  The effect of pressure on a maximum incisal bite force in man. , 1997, Archives of oral biology.

[26]  T. Dérand,et al.  Bond strength of luting cements to zirconium oxide ceramics. , 2000, The International journal of prosthodontics.