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跟腱冲击样机械加载联合脱蛋白松质骨支架植入修复兔节段性骨缺损。

Combination of Heel-strike like Mechanical Loading with Deproteinized Cancellous Bone Scaffold Implantation to Repair Segmental Bone Defects in Rabbits.

机构信息

Center for Orthopedics, Affiliated Southeast Hospital of Xiamen University/175th Hospital of People's Liberation Army, Zhangzhou, P. R. China, 363000.

出版信息

Int J Med Sci. 2017 Jul 19;14(9):871-879. doi: 10.7150/ijms.19613. eCollection 2017.

DOI:10.7150/ijms.19613
PMID:28824324
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5562194/
Abstract

Under physiological conditions bone defects often occur at mechanical load bearing sites and bone substitutes used for regeneration should be similarly subjected to mechanical loading stress. In this study, we investigated whether a novel heel-strike like mechanical loading method can be used as a complementary therapy to promote bone regeneration following bone substitute grafting. To test this, three groups of rabbits with segmental bone defects in the tibia were implanted with bovine deproteinized cancellous bone scaffold (DCBS), with one group also receiving heel-strike like mechanical loading generated by a rap stress stimulator. From weeks 4-12 post-operation X-ray and micro-CT scanning showed that rabbits receiving combination therapy had significantly more callus at the bone defect. Moreover, bone defects in the combination group were completely replaced with new bone at week 12, while the DCBS implantation alone group healed only partially and rabbits receiving neither DCBS nor mechanical loading developed only small calluses throughout the observation period. Analysis of micro-CT scanning results demonstrated that new bone density in the combination group was significantly higher than the DCBS only group at weeks 4 and 12 (<0.05). H&E staining results also indicated a significantly higher percentage of new bone in the bone defect area and a lower percentage of residual scaffold in the combination group compared to the DCBS only group (<0.05). Thus, this heel-strike like mechanical loading method appears to accelerate bone regeneration following substitute implantation by restoring a local mechanical loading environment in segmental bone defects.

摘要

在生理条件下,骨缺损经常发生在机械承重部位,用于再生的骨替代物也应同样受到机械加载应力的作用。在这项研究中,我们研究了一种新的足跟冲击样机械加载方法是否可以作为一种补充治疗方法,以促进骨替代物移植后的骨再生。为此,我们将三组胫骨节段性骨缺损的兔子分别植入牛脱蛋白松质骨支架(DCBS),其中一组还接受足跟冲击样机械加载,由 Rap 应力刺激器产生。术后 4-12 周的 X 射线和微 CT 扫描显示,接受联合治疗的兔子在骨缺损处有更多的骨痂。此外,在联合组中,骨缺损在 12 周时完全被新骨取代,而单独植入 DCBS 组仅部分愈合,既未植入 DCBS 也未接受机械加载的兔子在整个观察期间仅形成少量骨痂。微 CT 扫描结果分析表明,在第 4 和 12 周时,联合组的新骨密度明显高于单独 DCBS 组(<0.05)。H&E 染色结果还表明,与单独 DCBS 组相比,联合组骨缺损区域的新骨比例明显更高,残留支架比例更低(<0.05)。因此,这种足跟冲击样机械加载方法似乎通过恢复节段性骨缺损局部机械加载环境,加速了替代物植入后的骨再生。

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