Department of Orthopaedic Surgery, Thomas Jefferson University, Philadelphia, Pennsylvania, USA.
Am J Physiol Cell Physiol. 2010 Nov;299(5):C922-9. doi: 10.1152/ajpcell.00465.2009. Epub 2010 Jul 21.
Whereas recent work has demonstrated the role of oxygen tension in the regulation of skeletal cell function and viability, the microenvironmental oxemic status of bone cells remains unknown. In this study, we have employed the Krogh cylinder model of oxygen diffusion to predict the oxygen distribution profiles in cortical and cancellous bone. Under the assumption of saturation-type Michaelis-Menten kinetics, our numerical modeling has indicated that, under steady-state conditions, there would be oxygen gradients across mature osteons and trabeculae. In Haversian bone, the calculated oxygen tension decrement ranges from 15 to 60%. For trabecular bone, a much shallower gradient is predicted. We note that, in Haversian bone, the gradient is largely dependent on osteocyte oxygen utilization and tissue oxygen diffusivity; in trabecular bone, the gradient is dependent on oxygen utilization by cells lining the bone surface. The Krogh model also predicts dramatic differences in oxygen availability during bone development. Thus, during osteon formation, the modeling equations predict a steep oxygen gradient at the initial stage of development, with the gradient becoming lesser as osteonal layers are added. In contrast, during trabeculum formation, the oxygen gradient is steepest when the diameter of the trabeculum is maximal. Based on these results, it is concluded that significant oxygen gradients exist within cortical and cancellous bone and that the oxygen tension may regulate the physical dimensions of both osteons and bone trabeculae.
虽然最近的研究已经证明了氧张力在调节骨骼细胞功能和活力方面的作用,但骨细胞的微环境氧合状态仍然未知。在这项研究中,我们采用了克罗格圆柱模型来预测皮质骨和松质骨中的氧气分布情况。在假设饱和型米氏动力学的情况下,我们的数值模拟表明,在稳态条件下,成熟的骨单位和小梁之间会存在氧气梯度。在哈弗斯骨中,计算出的氧张力下降幅度在 15%到 60%之间。对于松质骨,预测的梯度要浅得多。我们注意到,在哈弗斯骨中,梯度主要取决于骨细胞的氧气利用和组织氧气扩散率;在松质骨中,梯度取决于骨表面细胞的氧气利用。克罗格模型还预测了骨骼发育过程中氧气供应的显著差异。因此,在骨单位形成过程中,模型方程预测在发育的初始阶段存在陡峭的氧气梯度,随着骨单位层的增加,梯度变得较小。相比之下,在小梁形成过程中,当小梁直径最大时,氧气梯度最为陡峭。基于这些结果,可以得出结论,皮质骨和松质骨中存在显著的氧气梯度,并且氧张力可能调节骨单位和骨小梁的物理尺寸。