Matsumoto T, Yoshino M, Uesugi K, Tanaka M
Division of Bioengineering, Osaka University Graduate School of Engineering Science, Machikaneyama-cho 1-3, Toyonaka, Osaka 560-8531, Japan.
Bone. 2007 Aug;41(2):239-46. doi: 10.1016/j.bone.2007.04.192. Epub 2007 May 6.
The canal network in cortical bone is an indispensable basis of bone vascularity, and its structure changes according to bone growth. Using monochromatic synchrotron radiation microCT (SRmicroCT), we evaluated the structural change of the canal network in growing rat tibiae and the response of this network to disuse. Tibiae were harvested from both hindlimbs of 9- and 14-week-old male Wistar rats subjected to unilateral sciatic neurectomy (SN) at 6 weeks of age (W9, n=8; W14, n=8) and from intact hindlimbs of 6-week-old rats (W6, n=8). Images of distal diaphyseal segments were reconstructed by SRmicroCT with a voxel size of 5.83 mum and then translated into local mineral densities using a calibrated relation between linear absorption coefficients and the concentration of K(2)HPO(4) solution. The canal network was segmented by simple thresholding at a bone mineral density of 0.82 g.cm(-3) and its structural properties were determined. In intact hindlimbs, the canal network showed a biphasic change with growth, as represented by increases followed by decreases in canal volume fraction (Ca.vol.f), the density of canals running longitudinally (Ca.num.d), and the density of canal connections (Ca.con.d): Ca.vol.f=2.2, 3.1, and 1.8%, Ca.num.d=77, 98, and 70 mm(-2), and Ca.con.d=18, 41, and 21 mm(-3) in W6, W9, and W14, respectively. In SN hindlimbs, bone growth deceleration was accompanied by a 16% smaller Ca.vol.f and a 22% smaller Ca.con.d in W9 and a 27% smaller Ca.vol.f, a 12% smaller Ca.num.d, and a 39% smaller Ca.con.d in W14 than those in intact hindlimbs. Furthermore, the canal branching structure became more treelike in SN hindlimbs. The effect of SN on the canal network appeared mainly in the periosteal sector of the anteriolateral cortex in W9 and spread throughout the cortex in W14. These findings will lead to a better understanding of microcirculation in cortical bone growth.
皮质骨中的管网络是骨血管形成不可或缺的基础,其结构随骨生长而变化。我们使用单色同步辐射显微CT(SRmicroCT)评估了生长中大鼠胫骨管网络的结构变化以及该网络对废用的反应。从6周龄时接受单侧坐骨神经切除术(SN)的9周龄和14周龄雄性Wistar大鼠的双侧后肢采集胫骨(W9,n = 8;W14,n = 8),并从6周龄大鼠的完整后肢采集胫骨(W6,n = 8)。通过体素大小为5.83μm的SRmicroCT重建远端骨干段的图像,然后利用线性吸收系数与K₂HPO₄溶液浓度之间的校准关系将其转换为局部矿物质密度。通过在骨矿物质密度为0.82 g·cm⁻³时进行简单阈值分割来划分管网络,并确定其结构特性。在完整后肢中,管网络随生长呈现双相变化,表现为管体积分数(Ca.vol.f)、纵向管密度(Ca.num.d)和管连接密度(Ca.con.d)先增加后减少:W6、W9和W14中Ca.vol.f分别为2.2%、3.1%和1.8%,Ca.num.d分别为77、98和70 mm⁻²,Ca.con.d分别为18、41和21 mm⁻³。在SN后肢中,与完整后肢相比,W9中骨生长减速伴随着Ca.vol.f小16%和Ca.con.d小22%,W14中Ca.vol.f小27%、Ca.num.d小12%和Ca.con.d小39%。此外,SN后肢中的管分支结构变得更像树状。SN对管网络的影响在W9时主要出现在前外侧皮质的骨膜部分,在W14时扩展至整个皮质。这些发现将有助于更好地理解皮质骨生长中的微循环。
