冠材料对种植牙应力分布影响的有限元分析

doi:10.13591/j.cnki.kqyx.2024.12.004

Abstract

Abstract:

Objective To compare the effects of different crown materials on the stress distribution of dental implants by finite element method. Methods A three-dimensional finite element model of implant-supported crown restoration of the right mandibular first molar was established. Four kinds of crown restoration materials were used, including polymer infiltrated ceramic network Vita Enamic, resin nanoceramic Lava Ultimate, zirconia ceramic Cercon, and polyether-ether-ketone breCAM. A displacement load of 0.01 mm or 200 N was applied to the occlusal surface of the right mandibular first molar, and the analysis of reaction force, the maximum variability of shape, the maximum principal stress, the maximum equivalent stress was performed. Results The results of stress analysis under 0.01 mm displacement load showed that the maximum equivalent stress of Cercon was 937.30 MPa, and that of breCAM was 67.09 MPa. The stress concentration of crowns and implants was obvious. The maximum equivalent stress of the surrounding alveolar bone of Cercon was the highest(26.61 MPa), and that of breCAM was the lowest(3.87 MPa), which was about 1/7 of that of maximum group. The stress concentration range of resin-matrix ceramics and polyether-ether-ketone was relatively small, and the distribution was more uniform. When 200 N was applied, the maximum principal stress and the maximum equivalent stress distribution of the four models were similar, and the maximum variability of shape of breCAM was larger at the loading site. Conclusion Under the same displacement load, the stress concentration of polyether-ether-ketone and resin-matrix ceramics crown was lower than that of zirconia. There was no significant difference in stress concentration in the implant and surrounding alveolar bone among polyetheretherketone, resin-ceramic composite, and zirconia crown restorations under the same load. Further research on long-term durability of PEEK and resin-matrix ceramicsis needed through practical and clinical trials.

Key words: dental implants, resin-matrix ceramics, zirconia, polyether-ether-ketone, finite element analysis

CLC Number:

R783.4

ZHUO Yingying, LIN Jie, CHEN Ruizhen, SHEN Jiyuan, LIN Ling, CAI Pingping, ZHENG Zhiqiang. Finite element analysis of the influence of crown material on the stress distribution of dental implants[J]. Stomatology, 2024, 44(12): 899-903.

Figures/Tables 5

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References 26

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材料	弹性模量/GPa	泊松比
Cercon	205.20	0.24
Vita Enamic	37.80	0.24
Lava Ultimate	12.70	0.45
breCAM	4.10	0.40
树脂水门汀	7.50	0.30
皮质骨	10.40	0.34
种植体、基台	120.00	0.33

载荷类型	冠材料	最大形变量/mm	最大等效应力/MPa				最大主应力/MPa				支反力/N
载荷类型	冠材料	模型整体	模型整体	种植冠	基台	种植体	模型整体	种植冠	基台	种植体	模型整体
0.01 mm 位移载荷	Cercon	0.024 0	937.30	937.30	269.73	314.64	207.38	207.38	76.76	99.75	690.26
	Vita Enamic	0.017 0	377.78	377.78	173.24	204.55	104.61	102.17	91.35	104.61	387.71
	Lava Ultimate	0.013 0	171.90	171.90	105.21	123.93	69.28	68.11	59.20	69.28	229.23
	breCAM	0.011 0	67.09	67.09	40.66	47.90	27.73	20.00	23.61	27.73	87.58
200 N 载荷	Cercon	0.009 1	148.93	148.93	93.28	109.58	63.43	35.54	54.79	63.43	200.00
	Vita Enamic	0.009 6	148.55	148.55	93.34	109.63	63.46	35.03	54.79	63.46	200.00
	Lava Ultimate	0.014 6	150.26	150.26	93.33	109.52	63.69	28.18	54.83	63.69	200.00
	breCAM	0.035 6	150.04	150.04	93.34	109.53	63.71	30.00	54.85	63.71	200.00

Finite element analysis of the influence of crown material on the stress distribution of dental implants

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