多孔微结构对根类似物种植体生物力学特性的影响：动物研究与有限元分析。

Effect of Porous Microstructures on the Biomechanical Characteristics of a Root Analogue Implant: An Animal Study and a Finite Element Analysis.

机构信息

College of Stomatology, Chongqing Medical University, Chongqing 401147, China.

Chongqing Municipal Key Laboratory of Oral Biomedical Engineering of Higher Education, Chongqing 400010, China.

出版信息

ACS Biomater Sci Eng. 2020 Nov 9;6(11):6356-6367. doi: 10.1021/acsbiomaterials.0c01096. Epub 2020 Oct 2.

DOI:10.1021/acsbiomaterials.0c01096

PMID:33449664

Abstract

BACKGROUND

Full ceramic or metal custom-made root analogue implants (RAIs) are made by replicating the natural tooth geometry. However, it may lead to the stress shielding of the surrounding bone, and an RAI is unable to easily achieve primary stability. Therefore, to improve primary stability and reduce stress shielding, RAI porous structures are proposed. The purpose of this study was to evaluate the effect of porous microstructures on the biomechanical characteristics of the custom-made RAI.

METHODS

Porous and bulk titanium cylinders and porous RAI and conventional implants for in vivo tests were fabricated using a selective laser melting (SLM) technology. The elastic modulus and the compressive strength of porous titanium cylinders were evaluated. These samples were then implanted into rabbit femurs (cylinders) and beagle dog mandibles (RAI and conventional implants). A simplified three-dimensional geometry of the anterior maxilla of a patient was constructed. Then, based on the extracted standard template library (STL) data, five different RAI models were constructed: (A) smooth surface, (B) pit surface, (C) bulb surface, (D) threaded surface, and (E) porous surface. A conventional implant model was also constructed. A static load of 100 N was applied to the crown in the multivectoral direction.

RESULTS

The results of the in vivo experiment confirmed that the porous structure decreased the elastic modulus of Ti6Al4V. Additionally, the implantation of the porous custom-made RAIs resulted in increased new bone ingrowth and decreased bone resorption compared to conventional implants. Moreover, the 3D finite element analysis suggested that the bone surrounding porous custom-made RAIs was subjected to a more uniform stress distribution, and the strain values of the surrounding bone were more conducive to bone formation.

CONCLUSION

Based on these findings, a custom-made RAI with a porous surface accelerates bone formation and might reduce the stress-shielding effect.

摘要

背景

全陶瓷或金属定制根类似物植入物（RAI）通过复制天然牙齿几何形状制成。然而，这可能导致周围骨骼的应力屏蔽，并且 RAI 不易实现初始稳定性。因此，为了提高初始稳定性并减少应力屏蔽，提出了 RAI 多孔结构。本研究旨在评估多孔微观结构对定制 RAI 生物力学特性的影响。

方法

使用选择性激光熔化（SLM）技术制造多孔和整体钛圆柱体以及多孔 RAI 和常规植入物进行体内测试。评估了多孔钛圆柱体的弹性模量和压缩强度。然后将这些样品植入兔股骨（圆柱体）和比格犬下颌骨（RAI 和常规植入物）中。构建了患者上前部简化的三维几何形状。然后，基于提取的标准模板库（STL）数据，构建了五个不同的 RAI 模型：（A）光滑表面，（B）凹坑表面，（C）灯泡表面，（D）螺纹表面和（E）多孔表面。还构建了常规植入物模型。在多向向量方向上，在冠部施加 100 N 的静态负载。

结果

体内实验的结果证实，多孔结构降低了 Ti6Al4V 的弹性模量。此外，与常规植入物相比，多孔定制 RAI 的植入导致新骨向内生长增加，骨吸收减少。此外，三维有限元分析表明，多孔定制 RAI 周围的骨骼承受更均匀的应力分布，并且周围骨骼的应变值更有利于骨形成。

结论

基于这些发现，具有多孔表面的定制 RAI 可加速骨形成，并可能减少应力屏蔽效应。

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多孔微结构对根类似物种植体生物力学特性的影响：动物研究与有限元分析。

Effect of Porous Microstructures on the Biomechanical Characteristics of a Root Analogue Implant: An Animal Study and a Finite Element Analysis.

机构信息

出版信息

BACKGROUND

METHODS

RESULTS

CONCLUSION

背景

方法

结果

结论

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