On the in vitro Fatigue Behavior of Human Dentin: Effect of Mean Stress

Abstract

Human dentin is susceptible to failure under repetitive cyclic-fatigue loading. This investigation seeks to address the paucity of data that reliably quantify this phenomenon. Specifically, the effect of alternating vs. mean stresses, characterized by the stress- or load-ratio R (ratio of minimum-to-maximum stress), was investigated for three R values (−1, 0.1, and 0.5). Dentin was observed to be prone to fatigue failure under cyclic stresses, with susceptibility varying, depending upon the stress level. The “stress-life” (S/N) data obtained are discussed in the context of constant-life diagrams for fatigue failure. The results provide the first fatigue data for human dentin under tension-compression loading and serve to map out safe and unsafe regimes for failure over a wide range of in vitro fatigue lives (< 10³ to > 10⁶ cycles).

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References

Anderson DJ -1956-. Measurement of stress in mastication I. J Dent Res35:664–670.

Arola D, Rouland JA, Zhang D -2002-. Fatigue and fracture of bovine dentin. Exp Mech42:380–388.

Basquin OH -1910-. The exponential law of endurance tests. Proc Am Soc Test Mater10:625–630.

Craig RG, Peyton FA -1958-. Elastic and mechanical properties of human dentin. J Dent Res37:710–718.

Gerber H -1874-. Bestimmung der Zulässigen Spannungen in Eisen-konstruktionen. Z Bayer Arch Ingenieur-Vereins6:101–110.

Goodis HE, Marshall GW Jr, White JM, Gee L, Hornberger B, Marshall SJ -1993-. Storage effects on dentin permeability and shear bond strengths. Dent Mater9:79–84.

Goodman J -1899-. Mechanics applied to engineering. London: Longmans Green.

Jones S, Boyde A -1984-. Ultrastructure of dentin and dentinogenesis. In: Dentin and dentinogenesis. Linde A, editor. Boca Raton: CRC Press, pp. 81–134.

Kinney JH, Marshall SJ, Marshall GW -2003-. The mechanical properties of human dentin: a critical review and re-evaluation of the dental literature. Crit Rev Oral Biol Med14:13–29.

10.

Lehman ML -1967-. Tensile strength of human dentin. J Dent Res46:197–201.

11.

Levitch LC, Bader JD, Shugars DA, Heymann HO -1994-. Non-carious cervical lesions. J Dent Res22:195–207.

12.

Morrow JD -1968-. Fatigue design handbook. In: Advances in engineering. Vol. 4. Warrendale: Society of Automotive Engineers, pp. 21–29.

13.

Nalla RK, Imbeni V, Kinney JH, Staninec M, Marshall SJ, Ritchie RO -2003a-. In vitro fatigue behavior of human dentin with implications for life prediction. J Biomed Mater Res66-A-:10–20.

14.

Nalla RK, Kinney JH, Ritchie RO -2003b-. Effect of orientation on the in vitro fracture toughness of dentin: the role of toughening mechanisms. Biomaterials24:3955–3968.

15.

Rasmussen ST, Patchin RE, Scott DB, Heuer AH -1976-. Fracture properties of human enamel and dentin. J Dent Res55:154–164.

16.

Sano H, Ciucchi B, Matthews WG, Pashley DH -1994-. Tensile properties of mineralized and demineralized human and bovine dentin. J Dent Res73:1205–1211.

17.

Söderberg CR -1939-. Factor of safety and working stress. Trans Am Soc Mech Eng52:13–28.

18.

Suresh S -1998-. Fatigue of materials. 2nd ed. Cambridge: Cambridge University Press.

19.

Ten Cate AR -1994-. Oral histology. In: Development, structure and function. Vol. 4. St. Louis: Mosby, p. 173.

20.

Tonami K, Takahashi H -1997-. Effects of aging on tensile fatigue strength of bovine dentin. Dent Mater J16:156–169.

21.

Wiskott HW, Nicholls JJ, Belser UC -1995-. Stress fatigue: basic principles and prosthodontic implications. Int J Prosthodont8:105–116.