Musculoskeletal Research Center and Department of Orthopaedic Surgery, Washington University School of Medicine, 660 South Euclid Avenue, Campus Box 8233, St. Louis, MO 63110, USA.
Musculoskeletal Research Center and Department of Orthopaedic Surgery, Washington University School of Medicine, 660 South Euclid Avenue, Campus Box 8233, St. Louis, MO 63110, USA.
J Biomech. 2014 Jan 22;47(2):451-7. doi: 10.1016/j.jbiomech.2013.10.052. Epub 2013 Nov 13.
Axial compression of the mouse tibia is used to study strain-adaptive bone (re)modeling. In some studies, comparisons between mice of different ages are of interest. We characterized the tibial deformation and force-strain relationships in female C57Bl/6 mice at 5-, 12- and 22-months age. A three-gauge experimental method was used to determine the strain distribution at the mid-diaphysis, while specimen-specific finite element analysis was used to examine strain distribution along the tibial length. The peak strains in the tibial mid-diaphyseal cross-section are compressive and occur at the postero-lateral apex. The magnitudes of these peak compressive strains are 1.5 to 2 times those on the opposite, antero-medial face (a site often used for strain gauge placement). For example, -10 N force applied to a 5-months old mouse engenders a peak compressive strain of -2800 µε and a tensile strain on the antero-medial face of +1450 µε. The orientation of the neutral axis at the mid-diaphysis did not differ with age (p=0.46), indicating a similar deformation mode in young and old tibiae. On the other hand, from 5- to 22-months there is a 25% reduction in cortical thickness and moment of inertia (p<0.05), resulting in significantly greater tibial strain magnitudes in older mice for equivalent applied force (p<0.05). We conclude that comparisons of tibial loading responses in young-adult and old C57Bl/6 tibiae are facilitated by similar deformation pattern across ages, but that modest adjustment of force levels is required to engender matching peak strains.
轴向压缩的小鼠胫骨用来研究应变适应骨(重新)建模。在一些研究中,不同年龄的小鼠之间的比较是很有意义的。我们的特点是胫骨变形和力 - 应变关系在女性 C57Bl/6 小鼠在 5 , 12 至 22 个月的年龄。一个三规实验方法用于确定在中骨干的应变分布,而具体的标本有限元分析用于检查应变分布沿胫骨长度。在胫骨中干骺端截面的峰值应变是压缩应变,并发生在后外侧尖。这些峰值压缩应变的幅度为 1.5 至 2 倍,在相反的,前 - 内侧面(一个经常用于应变片放置的位置)。例如, -10 N 的力施加到 5 个月大的老鼠引起一个峰值压缩应变-2800 μ ε和拉伸应变在前 - 内侧面的+1450 μ ε。在中干骺端的中性轴的方向没有随着年龄的变化而不同(p=0.46 ),表明在年轻和老年胫骨中具有相似的变形模式。另一方面,从 5 至 22 个月,皮质厚度和转动惯量减少了 25 %(p<0.05 ),导致在老年小鼠中胫骨应变幅度显著增大对于等效的施加力(p<0.05 )。我们得出结论,在年轻和老年 C57Bl/6 胫骨的胫骨加载响应的比较是通过相似的变形模式来促进的,但需要适度调整力水平以产生匹配的峰值应变。