隐形矫治器序列远中移动下颌磨牙的有限元分析

doi:10.19439/j.sjos.2025.01.004

摘要/Abstract

摘要： 目的: 构建隐形矫治器序列远移下颌磨牙的有限元模型,探讨不同第二、第一磨牙起始位置进行远移时的牙列移动特点。方法: 使用CBCT及口扫数据构建下颌骨、牙、牙周膜及隐形矫治器模型,依据第二及第一磨牙起始位置共分为8组工况。工况1~4—第二磨牙距第一磨牙分别为0、1、2、3 mm;工况5~8—第二磨牙远移至3.2 mm目标位,第一磨牙距第二前磨牙分别为0、1、2、3 mm。使用“两步法”模拟隐形矫治器加载并设定远移步距为0.2 mm,分析各工况牙列位移及矫治器形变特点。结果: 各工况下,拟远移磨牙表现为牙冠向远中倾斜移动趋势,其余牙表现为反方向倾斜移动。随着拟远移磨牙的起始位置向远中改变,拟远移磨牙的远中移动量增加。工况4中,第二磨牙的远移量最大为0.11 mm。工况8中,第一磨牙远移量最大为0.10 mm。拟远移牙牙周膜等效应力值变化趋势表现为与位移类似的变化趋势。结论: 隐形矫治器能够完成磨牙远中移动,但移动量无法达到预期值。随着拟远移磨牙起始位置向远中改变,远移量随之增加。

关键词: 有限元分析, 无托槽隐形矫治器, 磨牙远移, 下颌骨

Abstract: PURPOSE: To construct a finite element model of the mandibular molars distalization with clear aligner, and to explore the characteristics of dentition movement and aligner deformation. METHODS: The models of mandible, teeth, periodontal membrane and clear aligne were constructed using CBCT and oral scan data, and were divided into 8 groups according to the starting position of the second and first molar teeth. Working condition 1-4: the distance between the second molar and the first molar was 0, 1, 2, 3 mm, respectively. Working condition 5-8: the second molar had moved far to the target position of 3.2 mm, and the distance between the first molar and the second premolar was 0, 1, 2 and 3 mm, respectively. "Two-step method" was used to simulate the loading of the clear aligner and set the distance of the step to 0.2 mm, the characteristics of dental displacement and appliance shape change in each working condition were analyzed. RESULTS: Under each working condition, the molar with pseudo-remote displacement showed tilt movement of the crown to the far, and the other teeth showed reverse tilt movement. As the initial position of the pseudo-distant molar changed to the distal, the distal movement of the pseudo-distant molar increased. In working condition 4, the maximum displacement of the second molar was 0.11 mm, and in working condition 8, the maximum displacement of the first molar was 0.10 mm. The change trend of the Von Mises equivalent stress value of the periodontal membrane of the pretended distalization teeth was similar to that of the displacement. CONCLUSIONS: Clear aligner can complete distal movement of molar teeth, but the amount of movement cannot reach the expected value. As the initial position of the molars changed to the distal, the distance displacement will increase.

Key words: Finite element analysis, Clear aligner, Molar distalization, Mandible

中图分类号:

R783.5

康芙嘉, 崔宇琛, 王宋庆, 吴聿淼, 余磊, 朱宪春. 隐形矫治器序列远中移动下颌磨牙的有限元分析[J]. 上海口腔医学, 2025, 34(1): 19-24.

KANG Fu-jia, CUI Yu-chen, WANG Song-qing, WU Yu-miao, YU Lei, ZHU Xian-chun. Finite element simulation of distally moving mandibular molars by sequence with clear aligner[J]. Shanghai Journal of Stomatology, 2025, 34(1): 19-24.

参考文献

[1] 任亚男, 宋保龙, 封颖丽, 等. 无托槽隐形矫治器结合微种植体支抗远移上颌磨牙效率的三维重叠研究[J]. 中华口腔正畸学杂志, 2018, 25(2): 92-97.
[2] 吴晓雪. 下颌骨外斜线区微种植钉远移下牙列的研究[D]. 西安: 中国人民解放军空军军医大学, 2018.
[3] 雷鹤, 高冲, 吴冬雪, 等. 隐形矫治磨牙远移的三维有限元分析[J]. 口腔医学, 2021, 41(8): 692-698.
[4] 陈梦薇. 微种植体支抗辅助透明矫治器远移下颌磨牙的三维测量分析[D]. 福州: 福建医科大学, 2021.
[5] 石慧, 康方芳, 陆胜男, 等. 隐形矫治器远中移动上颌第一磨牙的三维有限元分析[J]. 口腔生物医学, 2022, 13(4): 246-250, 260.
[6] 徐子卿, 王特, 蒋健羽, 等. 个性化舌侧上颌前牙滑动内收三维有限元构建与分析[J]. 上海口腔医学, 2022, 31(2): 162-166.
[7] 曾红, 王超, 周建萍, 等. 无托槽隐形矫治不同控根附件对磨牙近中移动力学影响的三维有限元分析[J]. 上海口腔医学, 2018, 27(2): 139-145.
[8] 王建凯, 胡铮, 陆珮珺, 等. 附件对隐形矫治器内收上前牙影响的三维有限元分析[J]. 中国实用口腔科杂志, 2022, 15(4): 420-424.
[9] Ji L, Li B, Wu X.Evaluation of biomechanics using different traction devices in distalization of maxillary molar with clear aligners: a finite element study[J]. Comput Methods Biomech Biomed Engin, 2023, 26(5): 559-567.
[10] Jia L, Wang C, Li L, et al.The effects of lingual buttons, precision cuts, and patient-specific attachments during maxillary molar distalization with clear aligners: comparison of finite element analysis[J]. Am J Orthod Dentofacial Orthop, 2023, 163(1): e1-e12.
[11] 向彪, 徐逸晨, 王梦含, 等. 无托槽隐形矫治矩形附件对上颌磨牙远中移动力学影响的三维有限元分析[J]. 临床口腔医学杂志, 2021, 37(2): 78-82.
[12] 吴冬雪,赵云山,马萌, 等. 无托槽隐形矫治器远移下颌磨牙的疗效[J]. 中南大学学报医学版, 2021, 46(10): 1114-1121.
[13] 韩敏. 不同生长型人群下颌磨牙区牙槽骨形态的CBCT研究[D]. 济南: 山东大学, 2013.
[14] 刘玉凤, 沈银环, 李玉增, 等. 第一磨牙临床冠高度对无托槽隐形矫治效果影响的研究[J]. 中国医学创新, 2020, 17(33): 141-144.
[15] Kim SJ, Choi TH, Baik HS, et al.Mandibular posterior anatomic limit for molar distalization[J]. Am J Orthod Dentofacial Orthop, 2014, 146(2): 190-197.
[16] Chen CL, Chen CH, Pan CY, et al.Cone beam computed tomographic analysis of the spatial limitation during mandibular arch distalization[J]. BMC Med Imaging, 2020, 20(1): 39-47.
[17] 郭学强, 刘新强, 王铮, 等成人下颌磨牙后间隙与第三磨牙关系的三维研究[J]. 中华口腔正畸学杂志, 2021, 28(2): 74-79.
[18] Kim SH, Cha KS, Lee JW, et al.Mandibular skeletal posterior anatomic limit for molar distalization in patients with Class III malocclusion with different vertical facial patterns[J]. Korean J Orthod, 2021, 51(4): 250-259.
[19] Fan Z, Zhang Q, Jiang Y, et al.Mandibular retromolar space in adults with different sagittal skeletal patterns[J]. Angle Orthod, 2022, 92(5): 606-612.
[20] 王影, 李江洪, 曹瑞军, 等. 基于齿科隐形正畸材料力学性能的比较研究[J]. 塑料工业, 2018, 46(7): 84-87.
[21] 方群智. 不同矫治器膜片参数对无托槽隐形矫治技术远中移动上颌尖牙影响的三维有限元分析[D]. 杭州: 浙江中医药大学, 2022.
[22] 宋保龙. 无托槽隐形矫治器序列远移上颌牙列的三维受力分析及其影响因素研究[D]. 西安: 中国人民解放军空军军医大学, 2021.