医学
腰椎
薄片
极限抗拉强度
胸椎
压缩(物理)
拉伤
应变计
腰椎
解剖
抗压强度
生物力学
复合材料
材料科学
作者
Michio Hongo,Eiji Abe,Yoichi Shimada,Hajime Murai,Noriyuki Ishikawa,Kôzô Satô
出处
期刊:Spine
[Lippincott Williams & Wilkins]
日期:1999-06-01
卷期号:24 (12): 1197-1202
被引量:80
标识
DOI:10.1097/00007632-199906150-00005
摘要
The surface strain distribution on the thoracic and lumbar vertebrae during axial compressive loading was examined.To examine the general mechanical behavior of the thoracic and lumbar vertebrae to evaluate their role in burst fractures.Burst fractures are generally characterized by injury to the middle column and fracturing of the superior endplate. However, results in previous biomechanical investigations have not shown how these fractures are initiated during compression.Twenty-one thoracic and lumbar vertebrae (5 T10, 10 L1, and 6 L4) with upper and lower vertebrae were studied. Three-axis rosette strain gauges were cemented to 11 sites on the vertebral surface. An axial compressive load was applied, and the strain was measured in each specimen. The strain recorded by each rosette gauge was converted into a tensile, compressive, and shear component.The highest tensile and compressive strain was recorded at the base of the pedicle. Shear strain in the vertebral body was significantly higher than that in the lamina at all three spinal levels. At L1 and L4, the tensile strain at the superior vertebral rim was higher than that at the inferior rim.The high tensile and compressive strains found at the base of the pedicle of T10, L1, and L4 indicate that the base of the pedicle is the site of fracture initiation. The higher tensile strain at the superior vertebral rim of L1 and L4 supports the clinical observation of the thoracolumbar burst fractures.
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