Bone as a Structural Material

Elizabeth A Zimmermann; Robert O Ritchie

doi:10.1002/adhm.201500070

Bone as a Structural Material

Standard

Bone as a Structural Material. / Zimmermann, Elizabeth A; Ritchie, Robert O.

In: ADV HEALTHC MATER, Vol. 4, No. 9, 24.06.2015, p. 1287-304.

Research output: SCORING: Contribution to journal › SCORING: Journal article › Research › peer-review

Harvard

Zimmermann, EA & Ritchie, RO 2015, 'Bone as a Structural Material', ADV HEALTHC MATER, vol. 4, no. 9, pp. 1287-304. https://doi.org/10.1002/adhm.201500070

APA

Zimmermann, E. A., & Ritchie, R. O. (2015). Bone as a Structural Material. ADV HEALTHC MATER, 4(9), 1287-304. https://doi.org/10.1002/adhm.201500070

Vancouver

Zimmermann EA, Ritchie RO. Bone as a Structural Material. ADV HEALTHC MATER. 2015 Jun 24;4(9):1287-304. https://doi.org/10.1002/adhm.201500070

Bibtex

@article{2a0dfea14b2149798af36d2a49caded6,

title = "Bone as a Structural Material",

abstract = "As one of the most important natural materials, cortical bone is a composite material comprising assemblies of tropocollagen molecules and nanoscale hydroxyapatite mineral crystals, forming an extremely tough, yet lightweight, adaptive and multi-functional material. Bone has evolved to provide structural support to organisms, and therefore its mechanical properties are vital physiologically. Like many mineralized tissues, bone can resist deformation and fracture from the nature of its hierarchical structure, which spans molecular to macroscopic length-scales. In fact, bone derives its fracture resistance with a multitude of deformation and toughening mechanisms that are active at most of these dimensions. It is shown that bone's strength and ductility originate primarily at the scale of the nano to submicrometer structure of its mineralized collagen fibrils and fibers, whereas bone toughness is additionally generated at much larger, micro- to near-millimeter, scales from crack-tip shielding associated with interactions between the crack path and the microstructure. It is further shown how the effectiveness with which bone's structural features can resist fracture at small to large length-scales can become degraded by biological factors such as aging and disease, which affect such features as the collagen cross-linking environment, the homogeneity of mineralization, and the density of the osteonal structures.",

author = "Zimmermann, {Elizabeth A} and Ritchie, {Robert O}",

note = "{\textcopyright} 2015 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.",

year = "2015",

month = jun,

day = "24",

doi = "10.1002/adhm.201500070",

language = "English",

volume = "4",

pages = "1287--304",

journal = "ADV HEALTHC MATER",

issn = "2192-2640",

publisher = "John Wiley and Sons Ltd",

number = "9",

}

RIS

TY - JOUR

T1 - Bone as a Structural Material

AU - Zimmermann, Elizabeth A

AU - Ritchie, Robert O

PY - 2015/6/24

Y1 - 2015/6/24

N2 - As one of the most important natural materials, cortical bone is a composite material comprising assemblies of tropocollagen molecules and nanoscale hydroxyapatite mineral crystals, forming an extremely tough, yet lightweight, adaptive and multi-functional material. Bone has evolved to provide structural support to organisms, and therefore its mechanical properties are vital physiologically. Like many mineralized tissues, bone can resist deformation and fracture from the nature of its hierarchical structure, which spans molecular to macroscopic length-scales. In fact, bone derives its fracture resistance with a multitude of deformation and toughening mechanisms that are active at most of these dimensions. It is shown that bone's strength and ductility originate primarily at the scale of the nano to submicrometer structure of its mineralized collagen fibrils and fibers, whereas bone toughness is additionally generated at much larger, micro- to near-millimeter, scales from crack-tip shielding associated with interactions between the crack path and the microstructure. It is further shown how the effectiveness with which bone's structural features can resist fracture at small to large length-scales can become degraded by biological factors such as aging and disease, which affect such features as the collagen cross-linking environment, the homogeneity of mineralization, and the density of the osteonal structures.

AB - As one of the most important natural materials, cortical bone is a composite material comprising assemblies of tropocollagen molecules and nanoscale hydroxyapatite mineral crystals, forming an extremely tough, yet lightweight, adaptive and multi-functional material. Bone has evolved to provide structural support to organisms, and therefore its mechanical properties are vital physiologically. Like many mineralized tissues, bone can resist deformation and fracture from the nature of its hierarchical structure, which spans molecular to macroscopic length-scales. In fact, bone derives its fracture resistance with a multitude of deformation and toughening mechanisms that are active at most of these dimensions. It is shown that bone's strength and ductility originate primarily at the scale of the nano to submicrometer structure of its mineralized collagen fibrils and fibers, whereas bone toughness is additionally generated at much larger, micro- to near-millimeter, scales from crack-tip shielding associated with interactions between the crack path and the microstructure. It is further shown how the effectiveness with which bone's structural features can resist fracture at small to large length-scales can become degraded by biological factors such as aging and disease, which affect such features as the collagen cross-linking environment, the homogeneity of mineralization, and the density of the osteonal structures.

U2 - 10.1002/adhm.201500070

DO - 10.1002/adhm.201500070

M3 - SCORING: Journal article

C2 - 25865873

VL - 4

SP - 1287

EP - 1304

JO - ADV HEALTHC MATER

JF - ADV HEALTHC MATER

SN - 2192-2640

IS - 9

ER -