Finite-element analysis of mandibular first molar with two marginal designs of endocrown for the repair of different defects

doi:10.7518/hxkq.2019.05.005

Abstract

Abstract:

Objective This study aimed to evaluate the stress distribution of the mandibular first molar with different thicknesses and heights of the axial wall restored by the endocrown with two marginal designs and thus provide a theoretical basis for selecting clinical preparation through the finite-element method. Methods Two marginal endocrowns of the mandibular first molar with different axial-wall thicknesses (t=1, 2, 3 mm) and heights (h=2, 3, 4 mm) were established. Group A was the butt-joint design, whereas group B was the shoulder-surrounded design. After applying vertical and oblique loads , the size and distribution of the maximum principal stress and equivalent stress of residual tooth tissue were recorded. Results The maximum principal stress and equivalent stress distribution of residual tooth tissue were similar among different models. Group A showed a lower maximum principal stress and equivalent stress than group B at the same thickness and height under vertical load. Meanwhile, under oblique load, the maximum principal stress values of groups A and B decreased with increased thickness at constant height. Group A showed lower equivalent stress than group B at the same thickness and height of 2 and 3 mm. However, when the height was 4 mm, the trend was reversed. Conclusion In mastication, when bearing the vertical force, the retention of the butt-joint marginal endocrown preferred to the shoulder-surrounded one. Given the higher axial wall of the shoulder-surrounded marginal endocrown, it showed better ability to bear the oblique force than the butt-joint one.

Key words: mandibular first molar, endocrown, finite element analysis, axial wall height, equivalent stress

CLC Number:

R783

Zhai Xiaoyang,Zhang Jingya,Zhang Sanke,Jiang Chuanjing,Qiu Xiaoxia. Finite-element analysis of mandibular first molar with two marginal designs of endocrown for the repair of different defects[J]. West China Journal of Stomatology, 2019, 37(5): 480-484.

Figures/Tables 7

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References 12

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材料	弹性模量/GPa	泊松比
釉质	84.10	0.33
牙本质	18.60	0.31
皮质骨	13.70	0.30
松质骨	1.37	0.30
牙周膜	0.05	0.49
流动树脂	6.50	0.30
牙胶	6.9×10^-4	0.45
粘接剂树脂	8.30	0.35
E-max瓷块	95	0.32

缺损形式	最大主应力				等效应力
	垂直载荷		斜向载荷		垂直载荷		斜向载荷
	A组	B组	A组	B组	A组	B组	A组	B组
1a	4.08	4.26	3.92	3.92	7.87	8.85	7.26	8.57
1b	4.09	4.28	4.12	3.90	7.43	8.26	7.47	7.83
1c	4.19	5.56	4.16	3.87	7.34	8.09	18.80	7.66
2a	3.76	4.00	3.68	3.84	7.05	7.32	6.26	7.87
2b	3.88	4.01	3.84	3.73	7.04	7.31	5.87	8.11
2c	3.89	4.02	4.03	3.60	6.99	7.17	16.76	7.32
3a	3.72	3.72	3.57	3.75	6.98	7.32	5.14	7.86
3b	3.76	3.78	3.67	3.60	6.89	7.13	5.52	8.43
3c	3.77	3.81	3.94	3.53	6.05	7.11	16.49	7.22

缺损形式	垂直载荷		斜向载荷
缺损形式	A组	B组	A组	B组
1a	6.67	9.21	9.03	8.86
1b	7.34	9.20	14.54	12.70
1c	9.32	8.88	36.39	27.96
2a	5.53	10.28	9.42	9.20
2b	6.90	10.23	13.71	11.79
2c	8.05	9.85	37.20	17.75
3a	4.49	10.87	10.02	9.83
3b	5.44	10.35	11.38	10.91
3c	7.26	10.21	40.12	18.22

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