组织工程化韧带：用于牙齿替代的植入物构建体。

Tissue-engineered ligament: implant constructs for tooth replacement.

机构信息

Natural Implant, 38 rue Jim Sevellec, Brest, France.

出版信息

J Clin Periodontol. 2010 Aug 1;37(8):750-8. doi: 10.1111/j.1600-051X.2010.01588.x. Epub 2010 Jun 9.

DOI:10.1111/j.1600-051X.2010.01588.x

PMID:20546087

Abstract

AIM

A tissue-engineered periodontal ligament (PDL) around implants would represent an important new therapeutic tool to replace lost teeth. The PDL is the key to tooth anchoring; it connects tooth root and alveolar bone, and it sustains bone formation.

MATERIALS AND METHODS

Cells were isolated from PDL and cultured in a bioreactor on titanium pins. After the formation of multiple cellular layers, pins were implanted in enlarged dental alveolae.

MAIN OUTCOME MEASURES

Cell-covered implants integrated without adverse effects, and induced bone in their vicinity.

RESULTS

A histological examination of a dog model revealed that cells were arranged in a typical ligament-like fashion. In human patients, product safety was ascertained for 6-60 months. Probing and motility assessments suggested that the implants were well integrated with mechanical properties similar to those of teeth. Radiographs demonstrated the regeneration of deficient alveolar bone, the development of a lamina dura adjacent to a mineral-devoid space around the implant and implant migration in an intact bone structure.

CONCLUSIONS

New tissue consistent with PDL developed on the surface of dental implants after implantation. This proof-of-principal investigation demonstrates the application of ligament-anchored implants, which have potential advantages over osseointegrated oral implants.

摘要

目的

在种植体周围构建组织工程化牙周韧带（PDL）将成为替代缺失牙齿的重要新型治疗手段。PDL 是牙齿固定的关键，它连接牙根和牙槽骨，并维持骨形成。

材料和方法

从 PDL 中分离细胞，在钛针上的生物反应器中培养。形成多层细胞后，将针植入扩大的牙槽中。

主要观察指标

细胞覆盖的植入物无不良反应地整合，并在其附近诱导骨形成。

结果

对犬模型的组织学检查显示，细胞呈典型的韧带样排列。在人类患者中，6-60 个月的产品安全性得到了证实。探查和活动性评估表明，植入物与牙齿具有相似的机械性能，且整合良好。射线照片显示，缺损牙槽骨得到了再生，在植入物周围的矿物质缺失空间旁边形成了硬骨膜，植入物在完整的骨结构中发生了迁移。

结论

植入后，牙种植体表面形成了与 PDL 一致的新组织。这一初步研究证明了韧带锚固植入物的应用，其具有优于骨整合口腔植入物的潜在优势。

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组织工程化韧带：用于牙齿替代的植入物构建体。

Tissue-engineered ligament: implant constructs for tooth replacement.

机构信息

Natural Implant, 38 rue Jim Sevellec, Brest, France.

出版信息

J Clin Periodontol. 2010 Aug 1;37(8):750-8. doi: 10.1111/j.1600-051X.2010.01588.x. Epub 2010 Jun 9.

DOI:10.1111/j.1600-051X.2010.01588.x

PMID:20546087

Abstract

AIM

MATERIALS AND METHODS

Cells were isolated from PDL and cultured in a bioreactor on titanium pins. After the formation of multiple cellular layers, pins were implanted in enlarged dental alveolae.

MAIN OUTCOME MEASURES

Cell-covered implants integrated without adverse effects, and induced bone in their vicinity.

RESULTS

CONCLUSIONS

摘要

目的

在种植体周围构建组织工程化牙周韧带（PDL）将成为替代缺失牙齿的重要新型治疗手段。PDL 是牙齿固定的关键，它连接牙根和牙槽骨，并维持骨形成。

材料和方法

从 PDL 中分离细胞，在钛针上的生物反应器中培养。形成多层细胞后，将针植入扩大的牙槽中。

主要观察指标

细胞覆盖的植入物无不良反应地整合，并在其附近诱导骨形成。

结果

结论

植入后，牙种植体表面形成了与 PDL 一致的新组织。这一初步研究证明了韧带锚固植入物的应用，其具有优于骨整合口腔植入物的潜在优势。

组织工程化韧带：用于牙齿替代的植入物构建体。

Tissue-engineered ligament: implant constructs for tooth replacement.

机构信息

出版信息

AIM

MATERIALS AND METHODS

MAIN OUTCOME MEASURES

RESULTS

CONCLUSIONS

目的

材料和方法

主要观察指标

结果

结论

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组织工程化韧带：用于牙齿替代的植入物构建体。

Tissue-engineered ligament: implant constructs for tooth replacement.

机构信息

出版信息

AIM

MATERIALS AND METHODS

MAIN OUTCOME MEASURES

RESULTS

CONCLUSIONS

目的

材料和方法

主要观察指标

结果

结论

相似文献

引用本文的文献