Shear Strength and Fatigue Properties of Human Cortical Bone Determined from Pure Shear Tests

Shear properties of bone have been inferred from torsion tests. However, torsion often causes spiral fracture planes that correspond to tensile rather than shear failure. We measured the shear properties of human cortical bone in both longitudinal and transverse directions using pure shear tests. Shearing applied transverse to the bone long axis caused fracture along a 45 degrees plane that coincided with maximum tension. This fracture pattern is similar to spiral fractures caused by torsion. Shear strength along the bone axis was 51.6 MPa or about 35% less than that determined using torsion tests. Fatigue tests of human cortical bone in pure shear were conducted. The results agreed well with previous measurements of cortical bone fatigue life in tension and compression, when normalized to strength. Using tibial shear strain magnitudes measured previously for human volunteers, we estimated the fatigue life of cortical bone for different activities, and speculate that shear fatigue failure is a probable cause of tibial stress fractures resulting from impact loading.

[1]  V. Frankel,et al.  Uniaxial fatigue of human cortical bone. The influence of tissue physical characteristics. , 1981, Journal of biomechanics.

[2]  A. Burstein,et al.  The elastic and ultimate properties of compact bone tissue. , 1975, Journal of biomechanics.

[3]  Subrata Saha,et al.  Longitudinal shear properties of human compact bone and its constituents, and the associated failure mechanisms , 1977 .

[4]  F. G. Evans,et al.  Strength of human compact bone under repetitive loading. , 1957, Journal of applied physiology.

[5]  W C Van Buskirk,et al.  A continuous wave technique for the measurement of the elastic properties of cortical bone. , 1984, Journal of biomechanics.

[6]  J. Lafferty,et al.  The Influence of Stress Frequency on the Fatigue Strength of Cortical Bone , 1979 .

[7]  L. Lanyon,et al.  Limb mechanics as a function of speed and gait: a study of functional strains in the radius and tibia of horse and dog. , 1982, The Journal of experimental biology.

[8]  C T Rubin,et al.  Functional strains and cortical bone adaptation: epigenetic assurance of skeletal integrity. , 1990, Journal of biomechanics.

[9]  Z. Hashin,et al.  A method to produce uniform plane-stress states with applications to fiber-reinforced materials , 1978 .

[10]  W C Hayes,et al.  Fatigue life of compact bone--I. Effects of stress amplitude, temperature and density. , 1976, Journal of biomechanics.

[11]  D B Burr,et al.  In vivo measurement of human tibial strains during vigorous activity. , 1996, Bone.

[12]  D. Burr,et al.  Bone Microdamage and Skeletal Fragility in Osteoporotic and Stress Fractures , 1997, Journal of bone and mineral research : the official journal of the American Society for Bone and Mineral Research.

[13]  W. T. Dempster,et al.  Compact bone as a non-isotropic material. , 1952, The American journal of anatomy.

[14]  D R Carter,et al.  Bone creep-fatigue damage accumulation. , 1989, Journal of biomechanics.

[15]  D. Carter,et al.  Cyclic mechanical property degradation during fatigue loading of cortical bone. , 1996, Journal of biomechanics.

[16]  D T Davy,et al.  Anisotropic yield behavior of bone under combined axial force and torque. , 1985, Journal of biomechanics.

[17]  R. J. Gray,et al.  Compressive fatique behaviour of bovine compact bone. , 1974, Journal of biomechanics.

[18]  D M Nunamaker,et al.  Fatigue fractures in thoroughbred racehorses: Relationships with age, peak bone strain, and training , 1990, Journal of orthopaedic research : official publication of the Orthopaedic Research Society.

[19]  C. Milgrom,et al.  In-vivo strain measurements to evaluate the strengthening potential of exercises on the tibial bone. , 2000, The Journal of bone and joint surgery. British volume.