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骨和牙种植体参数对下颌骨应力分布的影响:有限元研究。

Influence of bone and dental implant parameters on stress distribution in the mandible: a finite element study.

机构信息

Structural Engineering and Mechanics, Griffith School of Engineering, Griffith University Gold Coast Campus, Queensland, Australia.

出版信息

Int J Oral Maxillofac Implants. 2009 Sep-Oct;24(5):866-76.

PMID:19865627
Abstract

PURPOSE

The complicated relationships between mandibular bone components and dental implants have attracted the attention of structural mechanics researchers as well as dental practitioners. Using the finite element method, the present study evaluated various bone and implant parameters for their influence on the distribution of von Mises stresses within the mandible.

MATERIALS AND METHODS

Various parameters were considered, including Young's modulus of cancellous bone, which varies from 1 to 4 GPa, and that of cortical bone, which is between 7 and 20 GPa. Implant length (7, 9, 11, 13, and 15 mm), implant diameter (3.5, 4.0, 4.5, and 5.5 mm), and cortical bone thickness (0.3 to 2.1 mm) were also considered as parameters. Assumptions made in the analysis were: modeling of the complex material and geometric properties of the bone and implant using two-dimensional triangular and quadrilateral plane strain elements, 50% osseointegration between bone and implant, and linear relationships between the stress value and Young's modulus of both cancellous and cortical bone at any specific point.

RESULTS

An increase in Young's modulus and a decrease in the cortical bone thickness resulted in elevated stresses within both cancellous and cortical bone. Increases in the implant length led to greater surface contact between the bone and implant, thereby reducing the magnitude of stress.

CONCLUSIONS

The applied masticatory force was demonstrated to be the most influential, in terms of differences between minimum and maximum stress values, versus all other parameters. Therefore loading should be considered of vital importance when planning implant placement.

摘要

目的

下颌骨结构与牙种植体之间复杂的关系引起了结构力学研究人员和口腔临床医生的关注。本研究采用有限元法,评估了各种骨和种植体参数对下颌骨内 Von Mises 应力分布的影响。

材料与方法

考虑了多种参数,包括从 1 到 4 GPa 变化的松质骨杨氏模量,以及 7 到 20 GPa 之间的皮质骨杨氏模量。还考虑了种植体长度(7、9、11、13 和 15mm)、种植体直径(3.5、4.0、4.5 和 5.5mm)和皮质骨厚度(0.3 至 2.1mm)等参数。分析中的假设为:使用二维三角形和四边形平面应变单元对骨和种植体的复杂材料和几何特性进行建模,骨与种植体之间 50%的骨整合,以及在任何特定点处松质骨和皮质骨的应力值与杨氏模量之间的线性关系。

结果

杨氏模量的增加和皮质骨厚度的减少导致松质骨和皮质骨内的应力升高。种植体长度的增加导致骨与种植体之间的表面接触增加,从而降低了应力的大小。

结论

与所有其他参数相比,施加的咀嚼力在最小和最大应力值之间的差异方面被证明是最具影响力的。因此,在计划种植体植入时,应考虑到加载的重要性。

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