隐形矫治下颌尖牙移动最佳附件位置的三维有限元分析

doi:10.13591/j.cnki.kqyx.2025.03.007

摘要/Abstract

摘要：

目的通过三维有限元分析比较不同附件以及不同放置位置对隐形矫治器矫正右侧下颌尖牙压低、伸长、扭转和扭矩移动中的影响。方法选取2022年在乌鲁木齐市口腔医院正畸科就诊的1例女性患者作为建模对象。构建三维有限元模型,模拟右侧下颌尖牙在压低、伸长、扭转和扭矩移动中,分别放置不同附件以及不同位置的21种工况,在矫治器附件对应位置施加大小为11.821 N的载荷,在Abaqus 6.14软件中模拟运算,收集各应力、位移分布云图及最大应力、位移值。结果在模拟正畸治疗的伸长组,附件位于颊侧切端时牙周膜和附件的PVMS值及尖牙位移最大。在模拟正畸治疗的压低组,可以观察到随着附件位置从切端到龈端,牙槽骨、尖牙、矫治器、附件的PVMS以及附件接触应力逐渐增大。在模拟正畸治疗的扭矩组,附件位于颊侧切端时尖牙PVMS最大。在模拟正畸治疗的扭转组,随着附件由切端向龈端移动,不论舌侧还是颊侧,尖牙位移量都在逐渐增大。结论 ①下颌尖牙分别进行伸长、压低、扭矩移动时,附件分别位于尖牙舌侧正中、尖牙颊侧正中最为适宜;下颌尖牙进行扭转移动时,附件位于尖牙颊侧中部、舌侧下部最为适宜。②牙齿舌侧的附件位置会极大地影响牙齿的移动和应力的分布。

关键词: 隐形矫治, 附件, 尖牙, 三维有限元分析

Abstract:

Objective To compare the effects of different attachments and their placement positions on the correction movements of intrusion, extrusion, rotation, and torque in the right mandibular canine using the three-dimensional finite element method. Methods A female patient treated in the Department of Orthodontics at the Urumqi City Stomatology Hospital in 2022 was chosen as the model subject. A three-dimensional finite element model was constructed to simulate various conditions of the right mandibular canine undergoing intrusion, extrusion, rotation, and torque movements with 21 different types of attachments placed at various positions. A load of 11.821 N was applied at the corresponding positions of the aligner attachments, and simulations were performed in Abaqus 6.14 software to collect stress and displacement distribution maps along with maximum stress and displacement values. Results In the simulation of orthodontic treatment for extrusion, the highest periodontal ligament Von Mises stress(PVMS)values and canine displacement occurred when the attachment was located at the upper region of buccal incisal. For the intrusion group, it was observed that PVMS values and contact stress of the alveolar bone, canine, aligner, and attachment gradually increased as the attachment position moved from the upper region to the lower region. In the torque simulation, the canine PVMS was the highest when the attachment was on the buccalupper region. In the rotation group, canine displacement incrementally increased as the attachment moved from the upper region to the lower region, regardless of whether it was on the lingual or buccal side. Conclusion ①For the extrusion, intrusion, and torque movements of the lower canine, the most suitable attachment positions are on the middle lingual side and middle buccal sideof the canine; for the rotational movement of the lower canine, the attachments should be placed on the middle buccal side, and lower lingual side. ②The lingual position of the tooth attachment greatly influences tooth movement and the distribution of stress.

Key words: invisible orthodontics, attachments, canine, three-dimensional finite element analysis

中图分类号:

R783.5

赵玺, 杨莉. 隐形矫治下颌尖牙移动最佳附件位置的三维有限元分析[J]. 口腔医学, 2025, 45(3): 197-203.

ZHAO Xi, YANG Li. Three-dimensional finite element analysis of the optimal attachment position for clear aligners of the lower canine[J]. Stomatology, 2025, 45(3): 197-203.

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材料名称	弹性模量/MPa	泊松比
下颌皮质骨	13 700	0.30
下颌松质骨	1 370	0.30
尖牙	20 000	0.30
附件	12 500	0.36
矫治器	2 050	0.30

组别	PVMS/MPa
组别	下颌骨	尖牙	牙周膜	矫治器	附件	附件接触
A1组	4.605	8.563	0.310	16.104	25.911	31.439
A2组	3.349	10.769	0.086	26.594	19.601	26.252
A3组	3.499	11.269	0.093	24.240	20.360	25.352
A4组	3.097	9.060	0.128	16.118	17.161	23.846
B1组	2.531	4.035	0.061	10.287	12.089	17.739
B2组	3.137	5.617	0.073	11.078	18.404	25.813
B3组	3.347	8.425	0.085	22.212	35.080	31.017
B4组	2.790	4.189	0.103	12.286	8.011	13.285
C1组	3.634	12.352	0.541	6.843	15.719	12.471
C2组	3.951	9.004	0.378	9.298	16.438	12.561
C3组	4.039	10.114	0.257	8.449	14.421	17.257
C4组	3.281	7.387	0.640	7.331	13.360	10.355
D1组	4.847	5.623	0.228	16.057	9.997	17.671
D2组	5.232	6.075	0.224	14.066	6.356	13.049
D3组	6.036	6.819	0.197	11.802	6.520	13.175
D4组	6.347	5.945	0.311	16.498	6.928	12.496
D5组	6.099	6.049	0.307	12.935	7.068	13.223
D6组	6.888	7.127	0.327	11.456	7.025	14.808
D7组	6.836	7.843	0.482	15.812	7.740	22.101
D8组	6.842	8.702	0.433	12.692	7.766	23.229
D9组	7.457	8.389	0.431	12.799	7.982	22.816