The Spatial Distribution of Fatigue Microdamage Accumulation in Cortical Bone and Factors Influencing Fracture Risk

Human cortical bone, like many engineering materials, exhibits damage and fracture, due to cyclic loading and overloading, such as that experienced by the loadbearing long bones. Unlike engineering materials, bone possesses a unique ability to repair damage and reduce fracture risk. However, in cases such as athletes and military recruits, the rate and extent of damage formation can exceed the rate of repair, resulting in increased fracture risk until the damage is diagnosed and rest prescribed. In the elderly, and especially those afflicted with metabolic bone diseases such as osteoporosis, the rate of bone resorption exceeds the rate of formation of new bone, resulting in reduced cortical thickness, increased intracortical porosity and, thus, increased fracture risk.

The overall objective of this project was to nondestructively investigate the spatial distribution of fatigue microdamage accumulation in cortical bone and factors that, upon interaction with microdamage, influence fracture susceptibility. Contrast-enhanced micro-CT detected increased microdamage in whole rat femora loaded in cyclic three-point bending relative to non-loaded controls, as well as the volumetric spatial distribution of microdamage relative to the whole bone morphology and non-uniform strain distribution resulting from bending. Spatial correlations between intracortical porosity, elevated mineralization, and fatigue microdamage were investigated by combining, for the first time, sequential, nondestructive, three-dimensional micro-CT measurements of each in cortical bone specimens subjected to cyclic loading followed by an overload to fracture. Microdamage at the fracture initiation site was found to be spatially correlated with intracortical porosity, but not highly mineralized tissue. The new spatial correlation methods were subsequently utilized to investigate the effects of age and loading mode on the fracture susceptibility of human cortical bone specimens. Interestingly, the influence of porosity on the initiation and propagation of microdamage was decreased in elderly (i.e., greater than 80 y/o) versus postmenopausal women donors. The observed spatial correlation between intracortical porosity and microdamage motivated future work exploring statistical predictions of fracture susceptibility based on spatial measurements of intracortical porosity, for example pore area, which predicted fracture susceptibility in a preliminary specimen cohort.

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Year

Entry

2001

Siris ES, Miller PD, Barrett-Connor E, Faulkner KG, Wehren LE, Abbott TA, Berger ML, Santora AC, Sherwood LM. Identification and fracture outcomes of undiagnosed low bone mineral density in postmenopausal women: results from the national osteoporosis risk assessment. JAMA. December 12, 2001;286(22):2815-2822.

1989

Schaffler MB, Radin EL, Burr DB. Mechanical and morphological effects of strain rate on fatigue of compact bone. Bone. 1989;10(3):207-214.

1988

Schaffler MB, Burr DB. Stiffness of compact bone: effects of porosity and density. J Biomech. 1988;21(1):13-16.

2007

Wang X, Masse DB, Leng H, Hess KP, Ross RD, Roeder RK, Niebur GL. Detection of trabecular bone microdamage by micro-computed tomography. J Biomech. 2007;40(15):3397-3403.

2007

Tang SY, Vashishth D. A non-invasive in vitro technique for the three-dimensional quantification of microdamage in trabecular bone. Bone. May 2007;40(5):1259-1264.