多孔钛修复兔桡骨节段性骨缺损的组织学与生物力学研究

Zhang Hong-fang, Zhao Chao-yong, Fan Hong-song, Zhang Hui, Pei Fu-xing, Wang Guang-lin

Department of Orthopedics, West China Hospital, Sichuan University, Chengdu 610041, China.

Beijing Da Xue Xue Bao Yi Xue Ban. 2011 Oct 18;43(5):724-9.

OBJECTIVE

To investigate the therapeutic effects of porous titanium (Ti) on the recovery of rabbit radial bone defect.

METHODS

Bone defects were artificially made in 30 New Zealand rabbits by resecting the 1 cm substantial osseo with periosteum of both radii. The left anterior limbs were implanted with porous titanium, while the right anterior limbs with porous hydroxyapatite (HA). The rabbits were sacrificed at three time points. Both the radii healing statuses were observed by histology and histomorphometry analyses by means of computer graphic processing at the end of 8, 12 and 24 weeks, and biomechanical analyses at the end of 12 and 24 weeks.

RESULTS

The histology examination showed that mass newly formed bone had grown into most pores of both the specimens. Along with prolongation of times after operation, the ingrowths of bone cells and effects of bone remodeling in the research side were nearly the same as those in the control side at the end of 12 and 24 weeks. The interface between the new bone and implants showed tight contact in both the groups without an obvious fibrous tissue. The results of histomorphometrical analyses showed that a statistically significant difference was not obtained for % bone area (bone area/ gross implant) between both the groups (P>0.05).However, the results of maximum failure load for the Ti group and the HA group were (107.34±27.44) N and (93.42±21.18) N at the end of 12 weeks, (118.56±24.65) N and (102.15±23.37) N at the end of 24 weeks, respectively. Biomechanical properties of the Ti group was stronger than that of the HA group, however, a statistically significant difference was not obtained between both the groups (P=0.102).

CONCLUSION

Porous titanium scaffold can promote the formation of new bone, which contributes to the healing of long tubular bone defect. The porous titanium can enhance the bone repairing effect on segmental bone defect nearly the same as porous hydroxyapatite .

目的

探讨多孔钛对兔桡骨缺损修复的治疗效果。

方法

将30只新西兰兔双侧桡骨1cm骨段及骨膜切除造成骨缺损。左前肢植入多孔钛，右前肢植入多孔羟基磷灰石（HA）。于3个时间点处死兔子。分别在8、12和24周结束时，通过组织学和组织形态计量学分析（借助计算机图形处理）观察双侧桡骨愈合情况，并在12和24周结束时进行生物力学分析。

结果

组织学检查显示，大量新形成的骨长入了两个标本的大部分孔隙。随着术后时间延长，在12和24周结束时，研究侧骨细胞的长入及骨重塑效果与对照侧相近。两组新骨与植入物之间的界面均紧密接触，无明显纤维组织。组织形态计量学分析结果显示，两组间骨面积百分比（骨面积/植入物总面积）差异无统计学意义（P>0.05）。然而，钛组和HA组在12周结束时的最大破坏载荷分别为（107.34±27.44）N和（93.42±21.18）N，在24周结束时分别为（118.56±24.65）N和（102.15±23.37）N。钛组的生物力学性能强于HA组，但两组间差异无统计学意义（P=0.102）。

结论

多孔钛支架可促进新骨形成，有助于长管状骨缺损的愈合。多孔钛对节段性骨缺损的骨修复效果与多孔羟基磷灰石相近。

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