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ASTM Selected Technical Papers
Nontraditional Methods of Sensing Stress, Strain, and Damage in Materials and StructuresAvailable to Purchase
ISBN-10:
0-8031-2403-1
ISBN:
978-0-8031-2403-5
No. of Pages:
241
Publisher:
ASTM International
Publication date:
1997
eBook Chapter
Thermoelastic Stress Analysis of the Human Tibia Available to Purchase
By
K Hyodo
,
K Hyodo
1
Senior Researcher
, Mechanical Engineering Laboratory, Agency of Industrial Science and Technology, Ministry of International Trade and Industry
, Namiki 1-2, Tsukuba, 305
.Japan
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M Yamada
,
M Yamada
2
Orthopedist
, Kobe University School of Medicine
, Kusunoki 7-5-1, Chuo, Kobe, 650
.Japan
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T Tateishi
T Tateishi
3
Director of Bionic Design Group
, National Institute for Interdisciplinary Research, Agency of Industrial Science and Technology, Ministry of International Trade and Industry
, Higashi 1-1-4, Tsukuba, 305
.Japan
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Page Count:
11
-
Published:1997
Citation
Hyodo, K, Yamada, M, & Tateishi, T. "Thermoelastic Stress Analysis of the Human Tibia." Nontraditional Methods of Sensing Stress, Strain, and Damage in Materials and Structures. Ed. Lucas, G, & Stubbs, D. 100 Barr Harbor Drive, PO Box C700, West Conshohocken, PA 19428-2959 : ASTM International, 1997.
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The thermoelastic stress analysis method is a non-contact technique which utilizes the thermoelastic qualities of hard tissues such as bones. It enables easy measurement and imaging of surface stress distributions. Using this approach, we performed stress analyses of human tibias in simulated loading conditions at various modes of varus valgus loading on the knee joint. In normal loading, the greatest stress image was obtained on the posterior aspect, indicating that the majority of the stress was concentrated in the posterior part of the tibia. The epiphysis of the proximal tibia, which consists predominantly of cancellous bone, showed tensile stress and the diaphysis which consists of compact bone showed compressive stress in every plane. These results indicate that the tensile stress in the epiphyseal surface indirectly reflects the impact-absorbing properties of cancellous bone. Also, results demonstrated that small changes in the alignment of the knee joint have a great influence on the stress pattern of the proximal tibia.
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