两种不同方法拔除下颌垂直第三磨牙的三维有限元分析

doi:10.13591/j.cnki.kqyx.2025.11.006

摘要/Abstract

摘要：

目的通过构建有限元模型比较小角度旋转脱位法与颊舌向摇晃脱位法在拔除锥形单根高位垂直阻生下颌第三磨牙(智齿)中的生物力学特性差异。方法选取一位下颌锥形单根高位垂直阻生智齿的志愿者,采集螺旋CT数据,使用MIMICS、Geomagic Wrap、Solidworks等软件构建有限元分析模型,利用ANSYS模拟两种拔牙方法,输出Von-Mises应力以及应变分布,分析比较两种施力方式的生物力学特征。结果小角度旋转脱位法中,牙、牙周膜、牙槽骨的高应力区及应变区域主要集中在牙颈部及牙根中上1/2,水平向扩散范围广于垂直向扩散范围。颊舌摇晃脱位法中,牙、牙周膜、牙槽骨的高应力区及应变区域主要集中在牙颈部及根尖1/2,尤其是根尖区域,垂直向扩散范围广于水平向扩散范围。小角度旋转脱位法的舌侧骨板及牙槽骨所受的应力远低于颊舌向摇晃脱位法,且牙周膜内部的整体应力值高于颊舌向摇晃脱位法。结论小角度旋转脱位法较颊舌向摇晃脱位法更易撕裂牙周膜,减少拔牙创伤。

关键词: 有限元, 下颌第三磨牙, 生物力学

Abstract:

Objective To compare the biomechanical characteristics of small-angle rotation force versus traditional buccal-lingual force in the extraction of vertically impacted mandibular third molars with single conical roots by a three-dimensional finite element analysis. Methods A patient with a vertical mandibular third molar featuring a conical single root was selected. Spiral CT data were acquired and three-dimensional finite element analysis models were constructed using software including MIMICS, Geomagic Wrap, and Solidworks. ANSYS was utilized to simulate both the small-angle rotation and buccal-lingual forces for tooth extraction. Comparative analyses of the biomechanical characteristics of these two forces were conducted by measuring Von-Mises stress and strain distribution. Results In the small-anglerotation force, high-stress and strain areas of tooth, periodontal ligament, and alveolar bone were predominantly concentrated at the cervical region and the upper half of the root, with a more uniform distribution and a broader horizontal diffusion range compared to the vertical diffusion range. In the buccal-lingual force, high-stress and strain areas were primarily located at the cervical region and the lower half of the root, particularly at the apical area, with a broader vertical diffusion range compared to the horizontal diffusion range. The lingual cortical plate and alveolar bone experienced significantly lower stress in the small-angle rotation force than that in the buccal-lingual force. The overall stress values within the periodontal ligament were markedly higher in the small-angle rotation force, with a more uniform distribution. Conclusion The small-angle rotation force is more likely to tear the periodontal ligament and reduce trauma associated with tooth extraction compared to the buccal-lingual force in surgical extraction of vertically impacted mandibular third molars with single conical roots.

Key words: finite element analysis, mandibular third molar, biomechanics

中图分类号:

R782.11

刘婧怡, 朱宇驰, 阳胜军, 司源, 王东苗. 两种不同方法拔除下颌垂直第三磨牙的三维有限元分析[J]. 口腔医学, 2025, 45(11): 832-838.

LIU Jingyi, ZHU Yuchi, YANG Shengjun, SI Yuan, WANG Dongmiao. Two different methods for vertical mandibular third molar extraction: A finite element analysis[J]. Stomatology, 2025, 45(11): 832-838.

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材料	杨氏模量/MPa	泊松比
皮质骨	1 370	0.30
松质骨	11 760	0.25
牙本质	18 600	0.35

时间范围/s	坐标轴	小角度旋转力/N		颊舌向摇晃力/N
时间范围/s	坐标轴	颊侧	舌侧	颊侧	舌侧
0~3	X	-3.052	3.052	34.867	34.867
	Y	-34.867	34.867	0	0
	Z	0	0	-3.052	3.052
3~6	X	-3.052	3.052	-34.867	-34.867
	Y	34.867	-34.867	0	0
	Z	0	0	3.052	-3.052
总计		35 N,旋转角度为5°(即在XY平面上与Y轴夹角为5°)		35 N,摇晃角度为5°(即在XZ平面上与X轴夹角为5°)

位置	平均应力/MPa		平均应变/mm
位置	旋转力	摇晃力	旋转力	摇晃力
牙	1.56	1.62	9.53×10^-5	1.03×10^-4
牙周膜	9.90×10^-1	3.17×10^-1	1.83×10^-1	1.36×10^-1
牙槽骨	2.76×10^-1	6.05×10^-1	3.63×10^-5	7.60×10^-5