Effect of Tunnel Structure of β-TCP on Periodontal Repair in Class III Furcation Defects in Dogs

Bioceramics Development and Applications Pub Date : 2014-01-23 DOI:10.4172/2090-5025.1000073

A. Saito, E. Saito, Y. Ueda, Y. Shibukawa, Yoshiyuki Honma, Tomomi Takahashi, M. Kimura, Y. Kuboki, Hiroshi ka

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引用次数: 4

Abstract

Background: The pore characteristics of bone graft materials play an important role in bone regeneration. Previous studies have reported that a pore size of 100 ~ 400 μm effectively induces vascular invasion and cell population within the materials. Many graft materials used recently have macropore (200 ~ 600 μm) or micropore (0.1 ~ 1 μm) structures. We devised a bone material with a tunnel pipe structure and pore size of 300 μm. The present study evaluated periodontal healing following implantation of this new bone graft material in furcation class III defects. Methods: Thirty mandibular premolar teeth of five beagles were used. After class III furcation defects were surgically created, each furcation was randomly treated with: 1) β-TCP with a tunnel pipe structure (tunnel group) (n=10); 2) Granular β-TCP (granular group) (n=10); and 3) No implant material (control group) (n=10). The dogs were sacrificed 8 weeks post-surgery and healing was evaluated histologically. Results: In the tunnel group, down growth of junctional epithelium was significantly less than that in the other two groups (P <0.01) and bone formation and blood capillary invasion were observed in the inner part of pores of the implanted material in the furcation. However, little bone formation was observed between the granules in the granular group. Conclusion: β- TCP with a tunnel pipe structure and pore size of 300 μm promotes bone regeneration and new cementum formation in class III furcation defects.

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β-TCP隧道结构对犬ⅲ类功能缺损牙周修复的影响

背景:骨移植材料的孔隙特性在骨再生中起着重要作用。已有研究表明，孔径在100 ~ 400 μm之间，可有效诱导材料内部血管的侵入和细胞的聚集。目前使用的接枝材料多为大孔(200 ~ 600 μm)或微孔(0.1 ~ 1 μm)结构。设计了孔径为300 μm的隧道管结构骨材料。本研究评估了这种新型骨移植材料在III级骨缺损植入后的牙周愈合情况。方法:选用5只小猎犬的下颌前磨牙30颗。手术制造III类分叉缺损后，每个分叉随机处理:1)带隧道管结构的β-TCP(隧道组)(n=10);2)颗粒β-TCP(颗粒组)(n=10);3)无种植体材料(对照组)(n=10)。术后8周处死狗，组织学评价其愈合情况。结果:隧道组大鼠连接上皮向下生长明显低于其他两组(P <0.01)，植入材料内孔内可见骨形成及毛细血管浸润。然而，在颗粒组中，颗粒之间几乎没有骨形成。结论:β- TCP具有隧道管结构，孔径为300 μm，可促进III级骨缺损的骨再生和新骨质的形成。

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Bioceramics Development and Applications

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