Accumulated biomechanical effects of mandibular molar mesialization using clear aligners with auxiliary devices: an iterative finite element analysis.

IF 4.8 2区 医学 Q1 Dentistry
Xinwei Lyu, Xing Cao, Luxian Chen, Yuyao Liu, Huilin Li, Cheng Hu, Jiali Tan
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引用次数: 1

Abstract

Background: The biomechanics generated by the clear aligner (CA) material changes continuously during orthodontic tooth movement, but this factor remains unknown during the computer-aid design process and the predictability of molars movement is not as expected. Therefore, the purpose of this study was to propose an iterative finite element method to simulate the long-term biomechanical effects of mandibular molar mesialization (MM) in CA therapy under dual-mechanical systems.

Methods: Three groups including CA alone, CA with a button, and CA with a modified lever arm (MLA) were created. Material properties of CA were obtained by in vitro mechanical experiments. MM was conducted by the rebound force exerted by CA material and the mesial elastic force (2N, 30° to the occlusal plane) applied to the auxiliary devices. Stress intensity and distribution on periodontal ligament (PDL), attachment, button and MLA, and displacement of the second molar (M2) during the iterations were recorded.

Results: There was a significant difference between the initial and cumulative long-term displacement. Specifically, compared to the beginning, the maximum stress of PDL decreased by 90% on average in the intermediate and final steps. The aligner was the main mechanical system at first, and then, the additional system exerted by the button and MLA dominated gradually. The stress of attachments and auxiliary devices is mainly concentrated on their interfaces with the tooth. Additionally, MLA provided a distal tipping and extrusive moment, which was the only group that manifested a total mesial displacement of the root.

Conclusions: The innovatively designed MLA was more effective in reducing undesigned mesial tipping and rotation of M2 than the traditional button and CA alone, which provided a therapeutic method for MM. The proposed iterative method simulated tooth movement by considering the mechanical characteristic of CA and its long-term mechanical force changes, which will facilitate better movement prediction and minimize the failure rate.

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下颌磨牙使用辅助装置的累积生物力学效应:迭代有限元分析。
背景:在正畸牙齿运动过程中,CA材料产生的生物力学是不断变化的,但在计算机辅助设计过程中,这个因素仍然是未知的,磨牙运动的可预测性也不像预期的那样。因此,本研究的目的是提出一种迭代有限元方法来模拟双力学系统下下颌磨牙中化(MM)在CA治疗中的长期生物力学效应。方法:制作单纯CA组、带按钮CA组和改良杠杆臂CA组。Material通过体外力学实验获得了CA的性能。通过CA材料施加的回弹力和辅助装置施加的中弹力(2N,咬合平面30°)进行MM。记录迭代过程中牙周韧带(PDL)、附着体、扣层和MLA的应力强度和分布以及第二磨牙(M2)的位移。结果:初始位移与累积位移有显著性差异。其中,与开始阶段相比,中间和最后阶段PDL的最大应力平均下降了90%。起初,对准器是主要的机械系统,随后,由按钮和MLA施加的附加系统逐渐占主导地位。附着物和辅助装置的应力主要集中在其与齿的界面上。此外,MLA提供了远端倾斜和挤压力矩,这是唯一一组表现出根的全近端位移。结论:创新设计的MLA比传统的按钮和CA更有效地减少了M2的非设计中端倾斜和旋转,为MM的治疗提供了一种方法。所提出的迭代方法通过考虑CA的力学特性及其长期机械力变化来模拟牙齿的运动,有助于更好地预测运动,最大限度地降低故障率。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Progress in Orthodontics
Progress in Orthodontics Dentistry-Orthodontics
CiteScore
7.30
自引率
4.20%
发文量
45
审稿时长
13 weeks
期刊介绍: Progress in Orthodontics is a fully open access, international journal owned by the Italian Society of Orthodontics and published under the brand SpringerOpen. The Society is currently covering all publication costs so there are no article processing charges for authors. It is a premier journal of international scope that fosters orthodontic research, including both basic research and development of innovative clinical techniques, with an emphasis on the following areas: • Mechanisms to improve orthodontics • Clinical studies and control animal studies • Orthodontics and genetics, genomics • Temporomandibular joint (TMJ) control clinical trials • Efficacy of orthodontic appliances and animal models • Systematic reviews and meta analyses • Mechanisms to speed orthodontic treatment Progress in Orthodontics will consider for publication only meritorious and original contributions. These may be: • Original articles reporting the findings of clinical trials, clinically relevant basic scientific investigations, or novel therapeutic or diagnostic systems • Review articles on current topics • Articles on novel techniques and clinical tools • Articles of contemporary interest
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