Fatigue and fracture of bovine dentin

In this paper, the fatigue and fracture properties of bovine dentin are evaluated usingin vitro experimental analyses. Double cantilever beam (DCB) specimens were prepared from bovine maxillary molars and subjected to zeroto-tension cyclic loads. The fatigue crack growth rate was evaluated as a function of the dentin tubule orientation using the Paris law. Wedge-loaded DCB specimens were also prepared and subjected to monotonic opening loads. Moiré interferometry was used to acquire the in-plane displacement field during stable crack growth, and the instantaneous wedge load and crack length were acquired to evaluate the crack growth resistance and crack tip opening displacement (CTOD) with crack extension. The rate of fatigue crack growth was generally larger for crack propagation occurring perpendicular to the dentin tubules. The Moiré fringe fields documented during monotonic crack growth exhibited non-linear deformation occurring within a confined region adjacent to the crack tip. Both the wedge load and CTOD response provided evidence that a fracture process zone contributes to energy dissipation during crack extension and that dentin exhibits a risingR-curve behavior. Results from this preliminary investigation are being used as a guide for an evaluation of the fatigue and fracture properties of human dentin.

[1]  Brian Lawn,et al.  Fracture of brittle solids: Atomic aspects of fracture , 1993 .

[2]  P. C. Paris,et al.  On cracks in rectilinearly anisotropic bodies , 1965 .

[3]  P. Lambrechts,et al.  Comparative SEM and TEM Examination of the Ultrastructure of the Resin-Dentin Interdiffusion Zone , 1993, Journal of dental research.

[4]  M E Gher,et al.  Clinical survey of fractured teeth. , 1987, Journal of the American Dental Association.

[5]  P. C. Paris,et al.  A Critical Analysis of Crack Propagation Laws , 1963 .

[6]  F. Nishimura,et al.  [Fracture toughness of human enamel]. , 1989, Shika zairyo, kikai = Journal of the Japanese Society for Dental Materials and Devices.

[7]  E. D. Rekow,et al.  Enamel Subsurface Damage Due to Tooth Preparation with Diamonds , 1997, Journal of dental research.

[8]  W. Geurtsen,et al.  Comparison of the number and diameter of dentinal tubules in human and bovine dentine by scanning electron microscopic investigation. , 2000, Archives of oral biology.

[9]  G. Marshall,et al.  The mechanical properties of human dentin: a critical review and re-evaluation of the dental literature. , 2003, Critical reviews in oral biology and medicine : an official publication of the American Association of Oral Biologists.

[10]  S. Rasmussen,et al.  Fracture Properties of Human Enamel and Dentin in an Aqueous Environment , 1984, Journal of dental research.

[11]  W. Geurtsen,et al.  Bovine dentin as a substitute for human dentin in shear bond strength measurements. , 1999, American journal of dentistry.

[12]  E Romberg,et al.  Indentation Damage and Mechanical Properties of Human Enamel and Dentin , 1998, Journal of dental research.

[13]  W. G. Matthews,et al.  Tensile Properties of Mineralized and Demineralized Human and Bovine Dentin , 1994, Journal of dental research.

[14]  D. Watts,et al.  Fracture Toughness of Human Dentin , 1986, Journal of dental research.

[15]  W H Douglas,et al.  Structure-Property Relations and Crack Resistance at the Bovine Dentin-Enamel Junction , 1994, Journal of dental research.

[16]  W. Hayes,et al.  The fracture mechanics of fatigue crack propagation in compact bone. , 1976, Journal of biomedical materials research.

[17]  R. F. Bunshah,et al.  Fracture Toughness of Human Enamel , 1981, Journal of dental research.

[18]  C. E. Cameron,et al.  The cracked tooth syndrome: additional findings. , 1976, Journal of the American Dental Association.

[19]  D. Arola,et al.  The failure of amalgam dental restorations due to cyclic fatigue crack growth , 1999, Journal of materials science. Materials in medicine.

[20]  D. Pashley,et al.  Thickness and morphology of resin-infiltrated dentin layer in young, old, and sclerotic dentin. , 1999, Operative dentistry.

[21]  S. Yokozeki,et al.  Moiré interferometry. , 1979, Applied optics.

[22]  G. Marshall,et al.  Atomic force microscope measurements of the hardness and elasticity of peritubular and intertubular human dentin. , 1996, Journal of biomechanical engineering.

[23]  J. Hood,et al.  The effects of dehydration and rehydration on some mechanical properties of human dentine. , 1993, Journal of biomechanics.

[24]  A. Heuer,et al.  Fracture Properties of Human Enamel and Dentin , 1976, Journal of dental research.

[25]  G. Marshall,et al.  A controlled clinical study of amalgam restorations: survival, failures, and causes of failure. , 1989, Dental materials : official publication of the Academy of Dental Materials.

[26]  M. Spector,et al.  Fracture of Human Dentin : A High Resolution Scanning Electron Microscope Study , 1976, Journal of dental research.

[27]  G W Marshall,et al.  The dentin substrate: structure and properties related to bonding. , 1997, Journal of dentistry.

[28]  W. Eakle,et al.  Fractures of posterior teeth in adults. , 1986, Journal of the American Dental Association.