正畸矫治器不同修整线设计的生物力学有限元数值分析:模拟研究

IF 2.6 Q1 DENTISTRY, ORAL SURGERY & MEDICINE
Tarek M. Elshazly , Christoph Bourauel , Philippe Chavanne , Hanaa Elattar , Ludger Keilig
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引用次数: 0

摘要

背景:采用有限元模型研究不同设计和厚度的正畸矫治器边缘对其生物力学行为的影响:采用有限元模型研究不同设计和厚度的正畸矫治器边缘对其生物力学行为的影响:将上颌的三维数据集导入 3-matic 软件。将右上中切牙(第 11 颗牙)从剩余模型中分离出来,并对其牙周韧带和周围骨质进行设计。设计了四种不同修剪线(扇形、直形、扇形扩展、直形扩展)的对齐器,每种对齐器有四种不同厚度(0.3、0.4、0.5 和 0.6 毫米)。这些模型被导入有限元软件包(Marc/Mentat)。应用了线性弹性构成材料模型。模拟了第 11 号牙齿面部 0.2 毫米的身体错位:与扇形修整设计相比,直形修整设计产生的结果力更大。增加矫治器厚度和/或将矫治器边缘延伸到龈线以外会导致结果力增加。所有的设计都显示法向接触力在牙面上的分布不均匀,主要集中在牙颈部三分之一和远端三分之一,尤其是加长的修整设计。所有设计都显示出牙齿不受控的倾斜:结论:根据目前的模型结果,我们倾向于在矫治器中使用笔直的延长修整线设计,因为这种设计对力的分布有积极的影响,从而可以控制牙齿的移动:这些发现为矫正器公司和正畸医生提供了宝贵的生物力学证据和指导,以加强对牙齿移动的控制,从而优化治疗效果。这可以通过修整矫正器的边缘,采用直线延伸设计,并选择适当的矫正器厚度来实现。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Numerical biomechanical finite element analysis of different trimming line designs of orthodontic aligners: An in silico study

Background

A finite element model was used to investigate the effect of different designs and thicknesses of orthodontic aligner margins on their biomechanical behavior.

Methods

A three-dimensional data set of an upper jaw was imported into the 3-matic software. The upper right central incisor tooth (Tooth 11) was separated from the remaining model, and its periodontal ligament and surrounding bone were designed. Aligners were designed with four different trimming lines (scalloped, straight, scalloped extended, straight extended), each with four different thicknesses (0.3, 0.4, 0.5, and 0.6 mm). The models were imported into a finite element package (Marc/Mentat). A linear elastic constitutive material model was applied. A facial 0.2 mm bodily malalignment of tooth 11 was simulated.

Results

The maximum resultant force was in the range of 1.0 N to 2.2 N. The straight trimming designs deliver higher resultant forces compared with scalloped trimming designs. Increasing the aligner thickness and/or extending the aligner edge beyond the gingival line leads to an increase in the resultant force. All designs showed an uneven distribution of the normal contact forces over the tooth surface with a predominant concentration toward the cervical third and distal third, particularly with the extended trimming designs. All designs showed uncontrolled tipping of the tooth.

Conclusions

Based on the current model outcomes, the use of a straight extended trimming line design for aligners is favored because of its positive impact on force distribution and, consequently, the control of tooth movement.

Clinical Relevance

These findings provide aligner companies and orthodontists a valuable biomechanical evidence and guidance to enhance control over tooth movement and therefore optimize treatment outcomes. This can be achieved by trimming the edges of aligners with a straight extended design and selecting the appropriate aligner thickness.

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来源期刊
Journal of the World Federation of Orthodontists
Journal of the World Federation of Orthodontists DENTISTRY, ORAL SURGERY & MEDICINE-
CiteScore
3.80
自引率
4.80%
发文量
34
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