The Response of Pediatric Ribs to Quasi-static Loading: Mechanical Properties and Microstructure

Traumatic injury is a major cause of death in the child population. Motor vehicle crashes account for a large portion of these deaths, and a considerable effort is put forth by the safety community to identify injury mechanisms and methods of injury prevention. However, construction of biofidelic anthropomorphic test devices and computational models for this purpose requires knowledge of bone properties that is difficult to obtain. The objective of this study is to characterize the relationship between mechanical properties and measures of skeletal development in the growing rib. Anterolateral segments of 44 ribs from 12 pediatric individuals (age range: 5 months to 9 years) were experimentally tested in three-point bending. Univariate mixed models were used to assess the predictive abilities of development-related variables (e.g., age, stature, histomorphometry, cross-sectional geometry) on mechanical variables (material and structural properties). Results show that stature, in addition to age, may be a reliable predictor of bone strength, and that histomorphometry has potential to explain bone properties and to further our understanding of fracture mechanisms. For example, percent secondary lamellar bone (%Sd.Ar) successfully predicts peak force (FP) and Young’s modulus (E). Application of these findings is not restricted to injury biomechanics, but can also be referenced in forensic and anthropological contexts.

[1]  Laura J. Freeman,et al.  The biomechanics of human ribs: material and structural properties from dynamic tension and bending tests. , 2007, Stapp car crash journal.

[2]  S. Goldstein,et al.  Biomechanics of Bone , 1993 .

[3]  H. Frost Tetracycline-based histological analysis of bone remodeling , 2005, Calcified Tissue Research.

[4]  H. Frost Review article mechanical determinants of bone modeling , 1982 .

[5]  S. Tadano,et al.  Effect of Gradual Demineralization on the Mineral Fraction and Mechanical Properties of Cortical Bone , 2009 .

[6]  R Vincentelli,et al.  The effect of Haversian remodeling on the tensile properties of human cortical bone. , 1985, Journal of biomechanics.

[7]  J A McGeough,et al.  Age-related changes in the tensile properties of cortical bone. The relative importance of changes in porosity, mineralization, and microstructure. , 1993, The Journal of bone and joint surgery. American volume.

[8]  R. Martin Porosity and specific surface of bone. , 1984, Critical reviews in biomedical engineering.

[9]  Michael Fitzharris,et al.  Injuries to children in child restraints , 2003 .

[10]  R. Raj,et al.  Measurement of viscosity of the grain-boundary phase in hot-pressed silicon nitride , 1976 .

[11]  N Yoganandan,et al.  Biomechanics of human thoracic ribs. , 1998, Journal of biomechanical engineering.

[12]  J. Currey,et al.  Differences in the tensile strength of bone of different histological types. , 1959, Journal of anatomy.

[13]  J. Currey,et al.  The mechanical properties of bone tissue in children. , 1975, The Journal of bone and joint surgery. American volume.

[14]  T. Einhorn,et al.  Biomechanics of Bone , 2002 .

[15]  C H Turner,et al.  Basic biomechanical measurements of bone: a tutorial. , 1993, Bone.

[16]  R. Cook,et al.  Advanced Mechanics of Materials , 1985 .

[17]  G. Stürtz,et al.  Biomechanical Data of Children , 1980 .

[18]  E. Sedlin 15 The Ratio of Cortical Area to Total Cross‐section Area in Rib Diaphysis: A Quantitative Index of Osteoporoses* , 1964 .

[19]  E. Kerley,et al.  The microscopic determination of age in human bone. , 1965, American journal of physical anthropology.

[20]  W C Hayes,et al.  Fatigue life of compact bone--II. Effects of microstructure and density. , 1976, Journal of biomechanics.

[21]  L. Bachrach Measuring Bone Mass in Children: Can We Really Do It? , 2006, Hormone Research in Paediatrics.

[22]  S. Cowin Bone mechanics handbook , 2001 .

[23]  Songbai Ji,et al.  Parametric study of head impact in the infant. , 2007, Stapp car crash journal.

[24]  King H. Yang,et al.  Pediatric material properties: a review of human child and animal surrogates. , 2007, Critical reviews in biomedical engineering.

[25]  C. Hirsch,et al.  Factors affecting the determination of the physical properties of femoral cortical bone. , 1966, Acta orthopaedica Scandinavica.

[26]  D. Waddington,et al.  Bone Strength During Growth: Influence of Growth Rate on Cortical Porosity and Mineralization , 2004, Calcified Tissue International.

[27]  W. Hayes,et al.  Bone compressive strength: the influence of density and strain rate. , 1976, Science.

[28]  S. Weiner,et al.  Bending and fracture of compact circumferential and osteonal lamellar bone of the baboon tibia , 2000, Journal of materials science. Materials in medicine.

[29]  G. Pharr,et al.  Microstructural elasticity and regional heterogeneity in human femoral bone of various ages examined by nano-indentation. , 2002, Journal of biomechanics.

[30]  D. Burr,et al.  Stiffness of compact bone: effects of porosity and density. , 1988, Journal of biomechanics.

[31]  J. Currey The effect of porosity and mineral content on the Young's modulus of elasticity of compact bone. , 1988, Journal of biomechanics.

[32]  S. Cowin,et al.  Bone Mechanics Handbook, 2nd Edition. - , 2003 .

[33]  Joel D Stitzel,et al.  Regional variation in the structural response and geometrical properties of human ribs. , 2005, Annual proceedings. Association for the Advancement of Automotive Medicine.

[34]  C. Hernandez How can bone turnover modify bone strength independent of bone mass? , 2008, Bone.

[35]  P Zioupos,et al.  The effects of ageing and changes in mineral content in degrading the toughness of human femora. , 1997, Journal of biomechanics.

[36]  Martin Rb Porosity and specific surface of bone. , 1984 .

[37]  Sundeep Khosla,et al.  Sex steroids and the construction and conservation of the adult skeleton. , 2002, Endocrine reviews.

[38]  W. Hayes,et al.  Relations between tensile impact properties and microstructure of compact bone , 1977, Calcified Tissue Research.

[39]  F. Linde,et al.  The effect of different storage methods on the mechanical properties of trabecular bone. , 1993, Journal of biomechanics.

[40]  R. Martin,et al.  The effects of collagen fiber orientation, porosity, density, and mineralization on bovine cortical bone bending properties. , 1993, Journal of biomechanics.

[41]  S. Boonen,et al.  The bone quality framework: determinants of bone strength and their interrelationships, and implications for osteoporosis management. , 2005, Clinical therapeutics.

[42]  B. Epker,et al.  Correlation of Bone Resorption and Formation with the Physical Behavior of Loaded Bone , 1965, Journal of dental research.

[43]  H. Frost,et al.  Age and sex related changes in the amount of cortex of normal human ribs. , 1966, Acta orthopaedica Scandinavica.

[44]  A. M. Parfitt,et al.  The two faces of growth: Benefits and risks to bone integrity , 1994, Osteoporosis International.

[45]  H. Frost From Wolff's law to the Utah paradigm: Insights about bone physiology and its clinical applications , 2001, The Anatomical record.

[46]  H. Frost Mechanical determinants of bone modeling. , 1982, Metabolic bone disease & related research.

[47]  H. W. Morrow,et al.  Statics and Strength of Materials , 1981 .

[48]  H. Frost Skeletal structural adaptations to mechanical usage (SATMU): 2. Redefining Wolff's Law: The remodeling problem , 1990, The Anatomical record.

[49]  H. Frost,et al.  Haversian bone formation rates determined by a new method in a mastodon, and in human diabetes mellitus and osteoporosis , 2005, Calcified Tissue Research.

[50]  H. Frost Secondary osteon populations: An algorithm for determining mean bone tissue age , 1987 .

[51]  K. Gerstle Advanced Mechanics of Materials , 2001 .

[52]  H. Frost,et al.  Comparison of Amounts of Remodeling Activity in Opposite Cortices of Ribs in Children and Adults , 1966, Journal of dental research.

[53]  S. Margulies,et al.  Infant skull and suture properties: measurements and implications for mechanisms of pediatric brain injury. , 2000, Journal of biomechanical engineering.

[54]  T. Binkley,et al.  Methods for measurement of pediatric bone , 2008, Reviews in Endocrine and Metabolic Disorders.

[55]  Harold M. Frost,et al.  AGE CHANGES IN RESORPTION IN HUMAN RIB CORTEX. , 1963, Journal of gerontology.

[56]  Joel D Stitzel,et al.  Defining regional variation in the material properties of human rib cortical bone and its effect on fracture prediction. , 2003, Stapp car crash journal.

[57]  M. Viceconti,et al.  Compressive behaviour of child and adult cortical bone. , 2011, Bone.

[58]  R. E. Fulton Literature Review : STRUCTURAL SYSTEMS -- STATICS, DYNAMICS AND STABILITY Moshe F. Rubinstein Prentice-Hall, Inc. , Englewood Cliffs, N.J. (1970) , 1972 .

[59]  M. Schultz,et al.  A distinct region of microarchitectural variation in femoral compact bone: Histomorphology of the endosteal lamellar pocket , 2011 .

[60]  I. Stein,et al.  Human ribs: static testing as a promising medical application. , 1973, Journal of biomechanics.

[61]  John W. Melvin,et al.  The Biomechanics of Trauma , 1984 .

[62]  S. Weiner,et al.  On the relationship between the microstructure of bone and its mechanical stiffness. , 1992, Journal of biomechanics.

[63]  George Sanger,et al.  Structure and Mechanics , 1991 .