Volume effects on fatigue life of equine cortical bone

Journal of Biomechanics

Volumn 40, Issue 16, 2007, Pages 3548-3554

  Bigley, R F ^a   Gibeling, J C ^b   Stover, S M ^c   Hazelwood, S J ^a   Fyhrie, D P ^a   Martin, R B ^a  

^a UNIVERSITY OF CALIFORNIA   (United States)

^b Department of Chemical Engineering and Materials Science

^c UNIVERSITY OF CALIFORNIA   (United States)

Author keywords

Equine third metacarpal; Failure; Fatigue life; Volume; Weibull analysis

Indexed keywords

BIOMECHANICS; DEFECTS; FATIGUE OF MATERIALS; MICROSTRUCTURE;

EQUINE CORTICAL BONE; EQUINE THIRD METACARPAL; WEIBULL ANALYSIS;

BONE;

ARTICLE; BIOMECHANICS; BONE STRENGTH; CORTICAL BONE; FATIGUE; FATIGUE LIFE; HORSE; LINEAR REGRESSION ANALYSIS; LOADING TEST; MATERIAL STATE; MECHANICAL STRESS; METACARPAL BONE; MORPHOMETRICS; NONHUMAN; PRIORITY JOURNAL; PROBABILITY; STATISTICAL ANALYSIS; YOUNG MODULUS;

ANIMALS; BONE DENSITY; COMPRESSIVE STRENGTH; COMPUTER SIMULATION; FEMALE; HORSES; MALE; METACARPAL BONES; MODELS, BIOLOGICAL; ORGAN SIZE; WEIGHT-BEARING;

EID: 36249017401     PISSN: 00219290     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.jbiomech.2007.05.025     Document Type: Article

References (38)

1. Bazant Z.P. Scaling of Structural Strength (2005), Elsevier, Burlington, MA pp. 1-20, 53-76
2. Bigley R.F., Griffin L.V., Christensen L., and Vandenbosch R. Osteon interfacial strength and histomorphometry of equine cortical bone. Journal of Biomechanics 39 (2006) 1629-1640
3. Boyce T.M., Fyhrie D.P., Glotkowski M.C., Radin E.L., and Schaffler M.B. Damage type and strain mode associations in human compact bone bending fatigue. Journal of Orthopaedic Research 16 (1998) 322-329
4. Buckwalter J.A., Glimcher M.J., Cooper R.R., and Recker R. Bone biology .1. Structure, blood-supply, cells, matrix, and mineralization. Journal of Bone and Joint Surgery-American 77A (1995) 1256-1275
5. Cattell M.K., and Kibble K.A. Determination of the relationship between strength and test method for glass fibre epoxy composite coupons using Weibull analysis. Materials and Design 22 (2001) 245-250
6. Choi K., and Goldstein S.A. A comparison of the fatigue behavior of human trabecular and cortical bone tissue. Journal of Biomechanics 25 (1992) 1371-1381
7. Currey J.D. Three analogies to explain the mechanical properties of bone. Biorheology 2 (1964) 1-10
8. Currey J.D. Tensile yield in compact bone is determined by strain, post-yield behaviour by mineral content. Journal of Biomechanics 37 (2004) 549-556
9. Daly R.M., Saxon L., Turner C.H., Robling A.G., and Bass S.L. The relationship between muscle size and bone geometry during growth and in response to exercise. Bone 34 (2004) 281-287
10. Gibeling J.C., Shelton D.R., and Malik C.L. Application of fracture mechanics to the study of crack propagation in bone. In: Rack H., et al. (Ed). Structural Biomaterials for the 21st Century (2001), The Minerals, Metals and Materials Society, Warrendale, PA 239-254
11. Gibson V.A., Stover S.M., Martin R.B., Gibeling J.C., Willits N.H., Gustafson M.B., and Griffin L.V. Fatigue behavior of the equine third metacarpus: mechanical property analysis. Journal of Orthopaedic Research 13 (1995) 861-868
12. Gibson V.A., Stover S.M., Gibeling J.C., Hazelwood S.J., and Martin R.B. Osteonal effects on elastic modulus and fatigue life in equine bone. Journal of Biomechanics 39 (2006) 217-225
13. Griffith A.A. The phenomena of rupture and flow in solids. Philosophical Transactions of the Royal Society 221 (1920) 162-198
14. Gustafson M.B., Martin R.B., Gibson V., Storms D.H., Stover S.M., Gibeling J., and Griffin L. Calcium buffering is required to maintain bone stiffness in saline solution. Journal of Biomechanics 29 (1996) 1191-1194
15. Hertzberg R.W. Deformation and Fracture Mechanics of Engineering Materials (1996), Wiley, New York pp. 266-272
16. Hogan H.A. Micromechanics modeling of Haversian cortical bone properties. Journal of Biomechanics 25 (1992) 549-556
17. Martin R.B. Is all cortical bone remodeling initiated by microdamage?. Bone 30 (2002) 8-13
18. Martin R.B. Fatigue damage, remodeling, and the minimization of skeletal weight. Journal of Theoretical Biology 220 (2003) 271-276
19. Martin R.B. Fatigue microdamage as an essential element of bone mechanics and biology. Calcified Tissue International 73 (2003) 101-107
20. Martin R.B., Gibson V.A., Stover S.M., Gibeling J.C., and Griffin L.V. Osteonal structure in the equine third metacarpus. Bone 19 (1996) 165-171
21. Martin R.B., Burr D.B., and Sharkey N.A. Skeletal Tissue Mechanics (1998), Springer, New York pp. 29-30, 131-134, 143-151
22. Mori S., and Burr D.B. Increased intracortical remodeling following fatigue damage. Bone 14 (1993) 103-109
23. Nunamaker D.M., Butterweck D.M., and Provost M.T. Fatigue fractures in Thoroughbred racehorses: relationships with age, peak bone strain, and training. Journal of Orthopaedic Research 8 (1990) 604-611
24. O'Brien F.J., Taylor D., and Lee T.C. Microcrack accumulation at different intervals during fatigue testing of compact bone. Journal of Biomechanics 36 (2003) 973-980
25. O'Brien F.J., Taylor D., and Clive Lee T. The effect of bone microstructure on the initiation and growth of microcracks. Journal of Orthopaedic Research 23 (2005) 475-480
26. Rentzsch W.H. A simple tool for designing with ceramics. Advanced Engineering Materials 5 (2003) 218-222
27. Schaffler M.B., Burr D.B., and Frederickson R.G. Morphology of the osteonal cement line in human bone. Anatomical Record 217 (1987) 223-228
28. Schaffler M.B., Radin E.L., and Burr D.B. Long-term fatigue behavior of compact bone at low strain magnitude and rate. Bone 11 (1990) 321-326
29. Schaffler M.B., Choi K., and Milgrom C. Aging and matrix microdamage accumulation in human compact bone. Bone 17 (1995) 521-525
30. Skedros J.G., Dayton M.R., Sybrowsky C.L., Bloebaum R.D., and Bachus K.N. Are uniform regional safety factors an objective of adaptive modeling/remodeling in cortical bone?. Journal of Experimental Biology 206 (2003) 2431-2439
31. Taylor D. Fatigue of bone and bones: an analysis based on stressed volume. Journal of Orthopaedic Research 16 (1998) 163-169
32. Taylor D., and Kuiper J.H. The prediction of stress fractures using a "stressed volume" concept. Journal of Orthopaedic Research 19 (2001) 919-926
33. Taylor D., O'Brien F., Prina-Mello A., Ryan C., O'Reilly P., and Lee T.C. Compression data on bovine bone confirms that a "stressed volume" principle explains the variability of fatigue strength results. Journal of Biomechanics 32 (1999) 1199-1203
34. Taylor D., Casolari E., and Bignardi C. Predicting stress fractures using a probabilistic model of damage, repair and adaptation. Journal of Orthopaedic Research 22 (2004) 487-494
35. Wang X., and Puram S. The toughness of cortical bone and its relationship with age. Annals of Biomedical Engineering 32 (2004) 123-135
36. Weibull W. A statistical distribution function of wide applicability. Journal of Applied Mechanics 18 (1951) 293-297
37. Wisnom M.R. Size effects in the testing of fibre-composite materials. Composites Science and Technology 59 (1999) 1937-1957
38. Yeh, O. C., Martin, R. B., 2003. Volume effects in bone fatigue: Implications for bone adaptation and remodeling. In 50th Annual Meeting of Orthopaedic Research Scoiety. San Francisco.