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Osteoporosis International
Published in: Osteoporosis International 3/2015

01-03-2015 | Editorial

The complex relationship between bone remodeling and the physical and material properties of bone

Author: D. B. Burr

Published in: Osteoporosis International | Issue 3/2015

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Excerpt

Bone’s fracture resistance is dependent on the amount of bone, its architectural organization, and the material properties of the matrix that compose it. Although past concentration has been on mass and geometry, there is increasing recognition that bone’s material properties play a critical role in its fracture resistance. Unlike bone mass which is determined by one feature—how much?—or architecture, which is determined by two features—amount and location—material properties are determined by a dynamic complex and multi-level set of molecular components and processes that are interdependent. This includes the materials themselves—collagen, mineral, noncollagenous proteins, and water—how they are assembled, and the nature of the interfaces between them. These properties of the material are, in turn, partly dependent on the rate of bone turnover. As turnover decreases, bone’s mean tissue age becomes older, causing the collagen to become more highly cross-linked, the mineral to accumulate and contribute to increasing homogeneity, and the tissue to become less hydrated (only partly because mineral displaces some of the water). During aging, each of these features contributes to decrease the ductility of the bone, which in turn contributes to the skeletal fragility caused by bone loss and measured by BMD. …
Literature
1.
Ural A, Janeiro C, Karim L, Diab T, Dl V (2015) Association between non-enzymatic glycation, resorption, and microdamage in human tibial cortices. Osteoporos Int. doi:10.​1007/​s00198-014-2938-4
2.
Herman BC, Cardoso L, Majeska RJ, Jepsen KJ, Schaffler MB (2010) Activation of bone remodeling after fatigue: Differential response to linear microcracks and diffuse damage. Bone 47:766–772CrossRefPubMedCentralPubMed
3.
Seref-Ferlenguez Z, Basta-Pijakic J, Kennedy OD, Philemon CJ, Schaffler MB (2014) Structural and mechanical repair of diffuse damage in cortical bone in vivo. J Bone Miner Res. doi:10.​1002/​jbmr2309
4.
5.
Parfitt AM (2002) Targeted and nontargeted remodeling: Relationship to basic multicellular unit origination and progression. Bone 30:5–7CrossRefPubMed
6.
Odetti P, Rossi S, Monacelli F, Poggi A, Cirnigliaro M, Federici M, Federici A (2005) Advanced glycation end products and bone loss during aging. Ann NY Acad Sci 1043:710–717CrossRefPubMed
7.
Okazaki K, Yamaguchi T, Tanaka K-I, Notsu M, Ogawa N, Yano S, Sugimoto T (2012) Advanced glycation end products (AGEs), but not high glucose, inhibit osteoblastic differentiation of mouse stromal ST2 cells. Calcif Tiss Int 91:286–296CrossRef
8.
Alikhani M, Alikhani Z, Boyd C, MacLellan CM, Raptis M, Liu R et al (2007) Advanced glycation end products stimulate osteoblast apoptosis via the MAP kinase and cytosolic apoptotic pathways. Bone 40:345–353CrossRefPubMedCentralPubMed
9.
Zhou Z, Han JY, Xi CX, Xie JX, Feng X, Wang CY et al (2008) HMGB1 regulates RANKL-induced osteoclastogenesis in a manner dependent on RAGE. J Bone Miner Res 23:1084–1096CrossRefPubMedCentralPubMed
10.
Saito M, Marumo K (2010) Collagen cross-links as a determinant of bone quality: a possible explanation for bone fragility in aging, osteoporosis, and diabetes mellitus. Osteoporos Int 21:195–214CrossRefPubMed
11.
Tang SY, Allen MR, Phipps R, Burr DB, Vashishth D (2009) Changes in non-enzymatic glycation and its association with altered mechanical properties following 1-year treatment with risedronate or alendronate. Osteoporos Int 20:887–894CrossRefPubMedCentralPubMed
12.
Zioupos P, Wang XT, Currey JD (1996) The accumulation of fatigue microdamage in human cortical bone of two different ages in vitro. Clin Biomech 11:365–375CrossRef
13.
Tang SY, Vashishth D (2010) Non-enzymatic glycation alters microdamage formation in human cancellous bone. Bone 46:148–154CrossRefPubMed
14.
Follet H, Viguet-Carrin S, Burt-Pichat B, Dépalle BY, Gineyts E et al (2011) Effects of preexisting microdamage, collagen cross-links, degree of mineralization age, and architecture on compressive mechanical properties of elderly human vertebral trabecular bone. J Orthop Res 29:481–488CrossRefPubMed
15.
Follet H, Farlay D, Bala Y, Viguet-Carrin S, Gineyts E, Burt-Pichat B et al (2013) Determinants of microdamage in elderly human vertebral trabecular bone. PLoS ONE 8:355232CrossRef
16.
17.
Schaffler MB, Burr DB (1988) Stiffness of compact bone: Effects of porosity and density. J Biomech 21:13–16CrossRefPubMed
18.
Jowsey J (1960) Age changes in human bone. Clin Orthop Rel Res 17:210–217
19.
Ortner DJ (1975) Aging effects on osteon remodeling. Calcif Tiss Res 18:27–36CrossRef
20.
Martin RB, Burr DB (1989) Structure, function and adaptation of compact bone. Raven Press, New York, ch.8
21.
Simmons ED Jr, Pritzker KPH, Grynpas MD (1991) Age-related changes in the human femoral cortex. J Orthop Res 9:155–167CrossRefPubMed
22.
Thompson DD (1980) Age changes in bone mineralization, cortical thickness and Haversian canal area. Calcif Tiss Int 31:5–11CrossRef
23.
Schaffler MB, Choi K, Milgrom C (1995) Aging and bone matrix microdamage accumulation in human compact bone. Bone 17:521–525CrossRefPubMed
24.
Norman TL, Wang Z (1997) Microdamage of human cortical bone: Incidence and morphology in long bones. Bone 20:375–379CrossRefPubMed
25.
Bajaj D, Geissler JR, Allen MR, Burr DB, Fritton JC (2014) The resistance of cortical bone tissue to failure under cyclic loading is reduced with alendronate. Bone 64:57–64CrossRefPubMed
26.
27.
De Laet CEDH, van Hout BA, Burger H, Hofman A, Pols HAP (1997) Bone density and risk of hip fracture in men and women: Cross-sectional analysis. Br Med J 315:221–225
28.
Kanis JA, Johnell O, Oden A, Dawson A, De Laet C, Jonsson B (2001) Ten year probabilities of osteoporotic fractures according to BMD and diagnostic thresholds. Osteoporos Int 12:989–995CrossRefPubMed
Metadata
Title
The complex relationship between bone remodeling and the physical and material properties of bone
Author
D. B. Burr
Publication date
01-03-2015
Publisher
Springer London
Published in
Osteoporosis International / Issue 3/2015
Print ISSN: 0937-941X
Electronic ISSN: 1433-2965
DOI
https://doi.org/10.1007/s00198-014-2970-4

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