Three-dimensional finite element analysis of stress distribution of mandibular condylar under indirect force

doi:10.3969/j.issn.2095-4344.2015.29.015

Abstract

Abstract:

BACKGROUND: Condylar fracture can occur under direct and indirect forces, and however, its risk and correlation with the impact site are rarely reported.
OBJECTIVE: To quickly establish normal mandible three-dimensional finite element model and to analyze the strain conditions of the condyle under force at different parts of the mandible.
METHODS: An adolescent volunteer was examined by multilayer spiral CT scans, whose mandible was normal and oral cavity was healthy. We used the reverse engineering software Mimics and large finite element software MSC.Patran to establish the three-dimensional finite element model of the mandible and to verify the feasibility of the model in the impact test at the body of the mandible, chin, mandibular angle and condyle.
RESULTS AND CONCLUSION: A rapid establishment of mandible dimensional finite element biomechanical model could reproduce the morphology of the mandible, which was able to obtain the overall visual impression of the mandibular condyle. Geometric model included 80 044 nodes and 18 441 units. The mandibular chin, one side of the body, mandibular angle and condyle were given 100 N force respectively. The maximum equivalent stress of the bone cortex appeared in condylar region. So the mandibular condylar fractures were at the greatest risk. Experimental results contribute to mechanically analyze the condylar fracture type and to judge the severity of fractures.

中国组织工程研究杂志出版内容重点：组织构建；骨细胞；软骨细胞；细胞培养；成纤维细胞；血管内皮细胞；骨质疏松；组织工程

Key words: Mandible, Finite Element Analysis;, Biomechanics

CLC Number:

R318

Wu Fu-hua, Huang Di-yan, Guo Zhen-guo, Du Mei-juan, Ma Ning, Niu Jin-cheng. Three-dimensional finite element analysis of stress distribution of mandibular condylar under indirect force [J]. Chinese Journal of Tissue Engineering Research, 2015, 19(29): 4667-4671.

Figures/Tables 3

References

[1] 殷学民,张君伟,任晓旭,等.下颌支矢状骨劈开术数字模型的建立及不同固定方式的稳定性分析[J].上海口腔医学,2013,22(3): 241-246.

[2] Murakami K,Sugiura T,Yamamoto K,et al,Biomechanical analysis of the strength of the mandible after marginal resection.J Oral Maxillofac Surg.2011;69(6):1798-1806.

[3] 曹力飞,申铁兵.三维有限元分析下颌骨生物力学的研究进展[J].中国口腔颌面外科杂志,2014,12(6):554-557.

[4] 邱蔚六.口腔颌面外科理论与实践[J].北京:人民卫生出版社, 1997: 479-479.

[5] Hart RT, Hennebel VV, Thongpreda N, et al. Modeling the biomechanlcs of the numdible. A three dimensional finite element study.J Biomecb.1992;25(3):261-286.

[6] Ashman RB, Van Buskirk WC. The elstic properties of a human mandible. Adv Dent Res. 1987;1(2):64-64.

[7] 张震康,傅民魁.颞下颌关节病[J].北京:人民卫生出版社, 1987:157-157.

[8] Meijer HT, Starmaas FJ, Bosman F. et al. A comparison of three finite element models of an edentulous mandible pirvided withimplants. J Oral Rehabil.1993;20(2):147-157.

[9] 邱蔚六.口腔颌面外科学,3版.北京:人民卫生出版社,1997:183.

[10] Cattaneo PM, Dalstra M, Frich LH. A three-dimensional finite element model from computed tomography data: a semi-automated. Proc Inst Mech Eng.2001;215(2):203-213.

[11] Gross MD, Arbel G, Hershkovitz I. Three-dimensional finite element analysis of the facial skeleton on simulated occlusal loadin. J Oral Rehabi.2001;2(87):684-946．

[12] Choi AH, Ben-Nissan B, Conway RC. Three-dimensionalmodelling and finite element analysis of the human mandibleduring clenching. Aust Dent J. 2005; 50(1):42-48.

[13] You SL Huang YL,Sun M,et al.Kouqiang Yixue Yanjiu.2008; 24(4); 381-383.

[14] Zhang J,LuoQ,Wang JP,et al.Zhongguo Meirong Yixue.2010; 19(3):344-347.

[15] Okumura N,Stegaroiu R,Nishiyama H,et al.Finite element analysis 0f implant-embedded maxilla model fromCTdata: CoMParison with the conventional model. J Prosthodont Res. 2011;55(1):24-31.

[16] Quereshy FA,Savell TA,Palomo JM.Applications of cone beam computered tomography in the practice of oral and maxillofacial surgery,J Oral Maxillofac Surg. 2008;66(4): 791-796.

[17] 殷学民,李燕,张美超,等.含完整牙列下颌骨生物力学模型的建立[J].中国口腔颌面外科杂志,2011,9(3):195-197.

[18] Carvalho Silva G,Pereira Cornacchia TM,Barbosa de Las Casas E,et al.A method fou obtaining a three-dimensional geometric model of dental implants for analysis via the finite element method.Implant Dent.2013;22(3):309-314.

[19] 白乐康,安虹,杜斌.无牙颌患者垂直距离对髁突前斜面应力分布的影响[J].口腔医学,2007,27(2):67-69.

[20] 胡凯,张晔缨,柳青明.模拟功能咬合时人颞下颌关节内的应力分布特征和位移特征[J].解放军医学杂志,2003,28(1):63-65.

[21] 孙健,张富强,王冬梅,等.三种加载方式下正常人下颌骨三维有限元应力分布分析[J].上海口腔医学,2004,13(1):41-43.

[22] 张海钟,步荣发,柳春明,等.颅面骨撞击伤的生物力学研究[J].中华创伤杂志,2004, 20(1):26-29.