双矩形附件对透明矫治器磨牙近中移动的三维有限元分析

doi:10.13591/j.cnki.kqyx.2023.10.004

摘要/Abstract

摘要：

目的利用三维有限元分析法,比较透明矫治器中双矩形附件对下颌第一磨牙近中移动的力学影响。方法通过锥形束CT(CBCT)获得患者下颌骨数据,利用Mimics、Geomagic Wrap、Unigraphics Nx 和Ansys Workbench等软件建立透明矫治器推下颌第一磨牙向近中的4组有限元模型,即模型A(颊侧近中5 mm长水平矩形附件),模型B(颊侧近中、舌侧近中3 mm长水平矩形附件),模型C(颊侧近中、颊侧远中3 mm长水平矩形附件),模型D(颊侧近中、颊侧远中3 mm长垂直矩形附件),分析下颌第一磨牙的位移模式、牙周膜应力分布和牙槽骨应力分布。结果 ①4组模型中下颌第一磨牙均为近中倾斜移动。下颌第一磨牙的总位移和倾斜度均表现为模型B组>模型C组>模型D组>模型A组,附件的固位力与磨牙的位移量和磨牙的倾斜度成正比,其中模型A、C、D三组各方面差值较小;②下颌第一磨牙牙周膜近远中面应力值最大值与牙槽窝近中内表面Von Mises应力值最大值均表现为模型B组>模型C组>模型D组>模型A组,与下颌第一磨牙的位移结果相印证。结论 ①透明矫治器中磨牙近中移动时,仅添加矩形附件磨牙均发生了近中倾斜移动;②附件可以增加透明矫治器中磨牙的固位力,附件的固位力与磨牙的位移量和磨牙的倾斜度成正比;③颊侧5 mm长水平矩形附件、颊侧3 mm长双水平矩形附件与颊侧3 mm长双垂直矩形附件此三种附件的固位力适中,磨牙的位移量与倾斜度适中,实际磨牙移动更符合矫治器预期设计,矫治器不易脱套,建议透明矫治器中磨牙近中移动时在磨牙上设计以上三种附件。

关键词: 透明矫治器, 矩形附件, 近中移动, 应力, 有限元

Abstract:

Objective Three-dimensional finite element analysis was used to compare the mechanical effects of double rectangular attachments on the molar mesial movement with clear aligner. Methods Four groups of the three-dimensional finite element model on the molar mesial movement with clear aligner was derived from a cone-beam CT(CBCT)scan data and then built in the software of Mimics, Geomagic Wrap, Unigraphics Nx and Ansys Workbench: Model A with a horizontal rectangular attachment of 5 mm long on mesiobuccal side, model B with double horizontal rectangular attachments of 3 mm long on mesiobuccal and mesiolingual side, model C with double horizontal rectangular attachment of 3 mm long on mesiobuccal and distobuccal side, model D with double vertical rectangular attachments of 3 mm long on mesiobuccal and distobuccal side. Four models were used to analyze the initial tooth displacement, tension-compression pattern at the periodontal ligament and Von Mises stress in mesial alveolar fossa. Results ①In the four models, the mandibular first molars achieved mesial tipping movement. The total displacement and inclination of mandibular first molars were as follows: Model B>model C>model D>model A. The retention force of the attachment and the displacement of the molars were proportional to the inclination of molars. The differences among the three groups of model A, C and D were small. ②The maximum values of periodontal ligament stress on the mesiodistal surface of the mandibular first molar and the maximum Von Mises stress on the mesial surface of the alveolar fossa were as follows: Model B>model C>model D>model A, which was confirmed by the displacement of mandibular first molars. Conclusion ①Only rectangular attachments have mesial tipping movement on the molar mesial movement with clear aligner; ②The attachment can increase the retention force of the molars in the clear aligner. The retention force of the attachment and the displacement of molars are proportional to the inclination of molars; ③The retention force of a horizontal rectangular attachment of 5 mm long on mesiobuccal side, double horizontal rectangular attachments of 3 mm long on mesiobuccal and distobuccal side and double vertical rectangular attachments of 3 mm long on mesiobuccal and distobuccal side are moderate, and the displacement and inclination of molars are moderate. The actual molar movement is more in line with the expected design of the clear aligner, and the aligner is less likely to fall off. It is suggested that when the molars move mesially in clear aligner, the above three attachments should be designed on the molars.

Key words: clear aligner, rectangular attachment, mesial movement, stress, finite element analysis

中图分类号:

R783.5

周妍, 彭友俭. 双矩形附件对透明矫治器磨牙近中移动的三维有限元分析[J]. 口腔医学, 2023, 43(10): 883-888.

ZHOU Yan, PENG Youjian. Effects of double rectangular attachments on the molar mesial movement with clear aligner by three-dimensional finite element analysis[J]. Stomatology, 2023, 43(10): 883-888.

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结构	弹性模量/MPa	泊松比
牙齿	1.96×10⁴	0.30
附件	1.25×10⁴	0.36
透明矫治器	5.28×10²	0.36
牙周膜	0.69	0.45

参数	皮质骨	松质骨
E₁/MPa	19 400	3 000
E₂/MPa	10 800	1 000
E₃/MPa	13 300	200
G₁₂/MPa	4 120	1 150
G₁₃/MPa	4 630	77
G₂₃/MPa	3 810	380
ν₁₂	0.445	0.300
ν₁₃	0.328	0.300
ν₂₁	0.249	0.300
ν₂₃	0.309	0.300
ν₃₁	0.224	0.300
ν₃₂	0.381	0.300

模型	单元数	节点数
模型A	1 450 869	2 245 596
模型B	1 453 399	2 248 268
模型C	1 452 858	2 248 234
模型D	1 452 504	2 247 536