The architectural influences on vertebral cancellous bone strength and the effect of applied stresses on cancellous bone remodeling are not well understood. One reason for this is that the transmission of stress through cancellous bone has not been extensively investigated at the trabecular level. At this time, there is no theoretical model for cancellous bone that properly reproduces both the morphologic and mechanical aspects of this tissue. A mechanical model of cancellous bone is needed which: matches all standard stereological measures of trabecular hard tissue morphology; accurately predicts bone strength and stiffness in 3D; and also accurately predicts the tissue level stresses and strains. The development of this model is here in proposed. Advanced numerical methods for stress analysis of cellular structures will be used to define the basic model, and it will be validated by comparison of: (1) model predictions of stiffness and strength with experimental results for vertebral cancellous bone; (2) model predictions of structural failure pattern with actual failure patterns; and (3) model predictions of trabecular stress and strain with three-dimensional finite element stress analysis predictions of trabecular stress and strain. Development of this model will provide a basic tool for the understanding of cancellous bone remodeling and strength. It will be valuable for the examination of the effects of bone remodeling on vertebral bone strength and it will increase the understanding of the mechanical causes of vertebral collapse in osteopenic women.

Agency
National Institute of Health (NIH)
Institute
National Institute of Arthritis and Musculoskeletal and Skin Diseases (NIAMS)
Type
First Independent Research Support & Transition (FIRST) Awards (R29)
Project #
5R29AR040776-05
Application #
2080255
Study Section
Orthopedics and Musculoskeletal Study Section (ORTH)
Project Start
1991-07-01
Project End
1996-09-16
Budget Start
1995-07-01
Budget End
1996-09-16
Support Year
5
Fiscal Year
1995
Total Cost
Indirect Cost
Name
Henry Ford Health System
Department
Orthopedics
Type
Schools of Medicine
DUNS #
073134603
City
Detroit
State
MI
Country
United States
Zip Code
48202
Soicher, Matthew A; Christiansen, Blaine A; Stover, Susan M et al. (2014) Remineralized bone matrix as a scaffold for bone tissue engineering. J Biomed Mater Res A 102:4480-90
Hardisty, Michael R; Kienle, Daniel F; Kuhl, Tonya L et al. (2014) Strain-induced optical changes in demineralized bone. J Biomed Opt 19:35001
Hardisty, M R; Garcia, T C; Choy, S et al. (2013) Stress-whitening occurs in demineralized bone. Bone 57:367-74
Soicher, Matthew A; Christiansen, Blaine A; Stover, Susan M et al. (2013) Remineralization of demineralized bone matrix (DBM) via alternating solution immersion (ASI). J Mech Behav Biomed Mater 26:109-18
Tjhia, Crystal K; Stover, Susan M; Rao, D Sudhaker et al. (2012) Relating micromechanical properties and mineral densities in severely suppressed bone turnover patients, osteoporotic patients, and normal subjects. Bone 51:114-22
McCormack, Jordan; Stover, Susan M; Gibeling, Jeffery C et al. (2012) Effects of mineral content on the fracture properties of equine cortical bone in double-notched beams. Bone 50:1275-80
Tjhia, Crystal K; Odvina, Clarita V; Rao, D Sudhaker et al. (2011) Mechanical property and tissue mineral density differences among severely suppressed bone turnover (SSBT) patients, osteoporotic patients, and normal subjects. Bone 49:1279-89
Ciarelli, Traci E; Tjhia, Crystal; Rao, D Sudhaker et al. (2009) Trabecular packet-level lamellar density patterns differ by fracture status and bone formation rate in white females. Bone 45:903-8
Reimann, D A; Hames, S M; Flynn, M J et al. (1997) A cone beam computed tomography system for true 3D imaging of specimens. Appl Radiat Isot 48:1433-6