Three-dimensional finite element analyses of the deep wedge-shaped defective premolars restored with different methods

doi:10.7518/hxkq.2017.01.012

Abstract

Abstract:

Objective The objective of this paper is to analyze the stress distribution in the deep wedge-shaped defective mandibular first premolars restored with different methods. Methods Three-dimensional finite element models of mandibular first premolar with deep wedge-shaped defect were created. The model, which was untreated after root canal treatment, served as the control group. Then, according to different treatment designs, four experimental groups were established as follows: resin filling (A), post restoration after resin filling (B), crown restoration after resin filling (C), and post and crown restoration after resin filling (D). Four different post materials were then chosen for establishing the subgroup models: fiber post (B1, D1), AuPd post (B2, D2), pure Ti post (B3, D3), and CoCr post (B4, D4). A force of 100 N was applied at a 30° angle on the buccal-inclined surface near the top of the buccal cusp. The maximum principal stress and Von Mises stress were investigated using finite element analysis software. Results 1) For the control group, the maximum principal stress and Von Mises stress of the residual dentine were the same as those of the tip of the defect. 2) Compared with the control group, the maximum principal stress and Von Mises stress of groups A, B, C, and D decreased greatly (P<0.05). The maximum principal stress and Von Mises stress of groups C and D with crowns were similar. The maximum principal stress and Von Mises stress of the post-dentine surface of groups B and D with fiber post were less than those in the cast metal post models (P<0.05). 3) The displacement of the buccal cusp of group A was similar to that of the control group (P>0.05) and larger than those in groups B, C, and D (P<0.05). Conclusion It is necessary for deep wedge-shaped defective teeth to be treated with full crowns, but a post is not necessary. If a post is used, fiber post with elastic modulus closer to the dentine is more suitable than metal post.

Key words: wedge-shaped defect, three-dimensional finite element, post, full crown

CLC Number:

R781.2

Ling Zhao, Liyuan Yang, Cuiling Liu, Xu Gao. Three-dimensional finite element analyses of the deep wedge-shaped defective premolars restored with different methods[J]. West China Journal of Stomatology, 2017, 35(1): 77-81.

Figures/Tables 5

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材料	弹性模量/GPa	泊松比
釉质^[6]	72.7	0.33
牙本质^[6]	18.6	0.31
牙胶尖^[6]	0.000 69	0.45
纤维桩*	18	0.30
纤维桩核树脂*	10.3	0.28
光固化复合树脂^[5]	8.3	0.28
钴铬合金^[6]	211	0.42
金钯合金*	96.6	0.35
纯钛^[5]	120	0.33
氧化锆全瓷冠^[7]	320	0.31
Panavia F	18.3	0.33

三维模型	节点数	网格数
未充填（对照）	8 210	4 461
树脂充填	9 086	4 871
充填后纤维桩修复	11 192	5 956
充填后铸造桩修复	9 067	4 848
充填后冠修复	14 951	8 310
充填后纤维桩全冠修复	16 180	8 894
充填后铸造桩全冠修复	14 806	8 200

组别	位移值
对照	73.15
A	70.15
B1	27.98
B2	21.52
B3	20.67
B4	18.16
C	16.48
D1	11.35
D2	11.23
D3	10.19
D4	10.10