TY - JOUR
T1 - Experimental validation of a microcracking-based toughening mechanism for cortical bone
AU - Vashishth, D.
AU - Tanner, K. E.
AU - Bonfield, W.
N1 - Funding Information:
This work has been funded by the IRC programme grant received from the Engineering and Physical Science Research Council. The authors are grateful to Dr. Z. Luklinska and Mr. R. Whitenstall for their help with the scanning electron microscopy.
PY - 2003/1/1
Y1 - 2003/1/1
N2 - It has been proposed that cortical bone derives its toughness by forming microcracks during the process of crack propagation (J. Biomech. 30 (1997) 763; J. Biomech. 33 (2000) 1169). The purpose of this study was to experimentally validate the previously proposed microcrack-based toughening mechanism in cortical bone. Crack initiation and propagation tests were conducted on cortical bone compact tension specimens obtained from the antlers of red deer. For these tests, the main fracture crack was either propagated to a predetermined crack length or was stopped immediately after initiating from the notch. The microcracks produced in both groups of specimens were counted in the same surface area of interest around and below the notch, and crack growth resistance and crack propagation velocity were analyzed. There were more microcracks in the surface area of interest in the propagation than in initiation specimens showing that the formation of microcracks continued after the initiation of a fracture crack. Crack growth resistance increased with crack extension, and crack propagation velocity vs. crack extension curves demonstrated the characteristic jump increase and decrease pattern associated with the formation of microcracks. The scanning electron micrographs of crack initiation and propagation displayed the formation of a frontal process zone and a wake, respectively. These results support the microcrack-based toughening mechanism in cortical bone. Bone toughness is, therefore, determined by its ability to form microcracks during fracture.
AB - It has been proposed that cortical bone derives its toughness by forming microcracks during the process of crack propagation (J. Biomech. 30 (1997) 763; J. Biomech. 33 (2000) 1169). The purpose of this study was to experimentally validate the previously proposed microcrack-based toughening mechanism in cortical bone. Crack initiation and propagation tests were conducted on cortical bone compact tension specimens obtained from the antlers of red deer. For these tests, the main fracture crack was either propagated to a predetermined crack length or was stopped immediately after initiating from the notch. The microcracks produced in both groups of specimens were counted in the same surface area of interest around and below the notch, and crack growth resistance and crack propagation velocity were analyzed. There were more microcracks in the surface area of interest in the propagation than in initiation specimens showing that the formation of microcracks continued after the initiation of a fracture crack. Crack growth resistance increased with crack extension, and crack propagation velocity vs. crack extension curves demonstrated the characteristic jump increase and decrease pattern associated with the formation of microcracks. The scanning electron micrographs of crack initiation and propagation displayed the formation of a frontal process zone and a wake, respectively. These results support the microcrack-based toughening mechanism in cortical bone. Bone toughness is, therefore, determined by its ability to form microcracks during fracture.
KW - Antler
KW - Cortical bone fracture
KW - Crack growth resistance
KW - Crack propagation velocity
KW - Frontal process zone
UR - http://www.scopus.com/inward/record.url?scp=0037212784&partnerID=8YFLogxK
U2 - 10.1016/S0021-9290(02)00319-6
DO - 10.1016/S0021-9290(02)00319-6
M3 - Article
C2 - 12485646
AN - SCOPUS:0037212784
SN - 0021-9290
VL - 36
SP - 121
EP - 124
JO - Journal of Biomechanics
JF - Journal of Biomechanics
IS - 1
ER -