种植体-基台连接设计对基台与基台螺丝受力影响的三维有限元分析

doi:10.19439/j.sjos.2021.05.007

上海口腔医学 ›› 2021, Vol. 30 ›› Issue (5): 481-487.doi: 10.19439/j.sjos.2021.05.007

种植体-基台连接设计对基台与基台螺丝受力影响的三维有限元分析

高远^1,2, 陈杰³, 王高琦⁴, 李云凯¹, 卞翠荣¹

1.山东大学齐鲁医院口腔修复科,山东济南 250012;
2.北京大学口腔医学院·口腔医院修复科,国家口腔医学中心,国家口腔疾病临床医学研究中心,北京 100081;
3.上海新力动力设备研究所,上海 200125;
4.济南大学机械工程学院, 山东济南 250022

收稿日期:2019-12-03 修回日期:2020-03-15 出版日期:2021-10-25 发布日期:2021-11-08
通讯作者: 卞翠荣,E-mail:cuirong_b88@163.com
作者简介:高远(1993-),女,硕士,住院医师,E-mail:18606436076@163.com
基金资助:
山东省自然科学基金（ZR2018MH023）

Three-dimensional finite element analysis of the influence of different implant-abutment joint design on abutment and abutment screw stress

GAO Yuan^1,2, CHEN Jie³, WANG Gao-qi⁴, LI Yun-kai¹, BIAN Cui-rong¹

1. Department of Prosthodontics, Qilu Hospital of Shandong University. Jinan 250012, Shandong Province;
2. Department of Prosthodontics, Peking University School and Hospital of Stomatology, National Center of Stomatology, National Clinical Research Center for Oral Diseases. Beijing 100081;
3. Shanghai Xinli Power Equipment Research Institute. Shanghai 200125;
4. School of Mechanical Engineering, Jinan University. Jinan 250022, Shandong Province, China

Received:2019-12-03 Revised:2020-03-15 Online:2021-10-25 Published:2021-11-08

摘要/Abstract

摘要： 目的: 研究锥形固位、平台转移种植体的不同连接设计对基台及基台螺丝受力情况的影响。方法: 建立平台转移量分别为0.2、0.4、0.6、0.8、1.0 mm并对应基台锥度分别为6°、8°、10°的种植体模型,分析各组模型受不同载荷时,基台及基台螺丝von-Mises应力及应变情况。结果: 随着平台转移量增大,基台与基台螺丝峰值von-Mises应力及应变增大,且平台转移量≥0.8 mm的模型在水平向力作用下,其峰值von-Mises应力高于690 MPa。水平向加力时,应力与应变随平台转移量增大的幅度最大,斜向加力时次之,垂直向加力时最小。81.67%的模型基台应力集中于基台颈部;所有模型基台螺丝应力均集中于基台螺丝头部与体部转折处。结论: 平台转移量增大使基台与基台螺丝在咬合过程中受力增大。为了减少种植修复后机械并发症的发生,建议在一定范围内选用平台转移量小的种植体。当平台转移量≥0.8 mm时,基台与基台螺丝最大应力超过纯钛的屈服强度,临床上应慎用该设计。

关键词: 平台转移, 锥度, 基台, 种植体, 有限元分析

Abstract: PURPOSE: This experiment studied the influence of different connection designs of the tapered retention and platform transfer implant on the stress of the abutments and abutment screws. METHODS: Implant models (Platform-switching: 0.2, 0.4, 0.6, 0.8, 1.0 mm; Taper:6°,8°,10°) were established, and Von-mises stress and strain of abutment and abutment screw under different loads were analyzed. RESULTS: With the increase of the platform-switching amount, the peak von-Mises stress and strain of abutment and abutment screw increased. The peak von-Mises stress of the model with platform transfer≥0.8 mm was higher than 690 MPa. In addition, the variation amplitude was horizontal loading>oblique loading>vertical loading. The maximum stress of the abutment was concentrated at the neck of the abutment in 81.67% models. The stress of the abutment screw was concentrated at the turning point of the head and body of abutment screw in all models. CONCLUSIONS: The increase of the amount of platform switching makes the abutment and the abutment screws bear more force in the occlusion process. Therefore, in order to reduce the occurrence of mechanical complications after implantation and restoration, the implant system with the minimum amount of platform transfer should be selected within a certain range. The maximum stress on the abutments and screws exceeds the yield strength of pure titanium in implants with platform-switching amount greater than 0.8 mm, indicating that this design should be selected prudently in clinical practice.

Key words: Platform switching, Taper, Abutment, Implant, Finite element analysis

中图分类号:

R783.1

高远, 陈杰, 王高琦, 李云凯, 卞翠荣. 种植体-基台连接设计对基台与基台螺丝受力影响的三维有限元分析[J]. 上海口腔医学, 2021, 30(5): 481-487.

GAO Yuan, CHEN Jie, WANG Gao-qi, LI Yun-kai, BIAN Cui-rong. Three-dimensional finite element analysis of the influence of different implant-abutment joint design on abutment and abutment screw stress[J]. Shanghai Journal of Stomatology, 2021, 30(5): 481-487.

参考文献

[1] Hämmerle CHF, Tarnow D.The etiology of hard- and soft-tissue deficiencies at dental implants: a narrative review[J]. J Clin Periodontol, 2018, 89(Suppl 1): S267-S277.
[2] Schmitt CM, Nogueira-Filho G, Tenenbaum HC, et al.Performance of conical abutment (Morse Taper) connection implants: a systematic review[J]. J Biomed Mater Res A, 2014, 102(2): 552-574.
[3] Wang K, Geng J, Jones D, et al.Comparison of the fracture resistance of dental implants with different abutment taper angles[J]. Mater Sci Eng C Mater Biol Appl, 2016, 63: 164-171.
[4] Lazzara RJ, Porter SS.Platform switching: a new concept in implant dentistry for controlling postrestorativecrestal bone level[J]. Int J Periodontics Restorative Dent, 2006, 26(1): 9-17.
[5] Se-Young M, Young-Jun L, Myung-Joo K, et al.Three-dimensional finite element analysis of platform switched implant[J]. J Adv Prosthodont, 2017, 9(1): 31-37.
[6] Macedo JP, Pereira J, Vahey BR, et al.Morse taper dental implants and platform switching: The new paradigm in oral implantology[J]. Eur J Dent, 2016, 10(1): 148-154.
[7] Akça K, Cehreli MC, Iplikçioglu H.Evaluation of the mechanical characteristics of the implant-abutment complex of a reduced diameter morse-taper implant. a nonlinear finite element stress analysis[J]. Clin Oral Implants Res, 2010, 14(4): 444-454.
[8] Wu AY, Lung H, Huang HL, et al.Biomechanical investigations of the expanded platform-switching concept in immediately loaded small diameter implants[J]. J Prosthet Dent, 2016, 115(1): 20-25.
[9] Seetoh YL, Tan KB, Chua EK, et al.Load fatigue performance of conical implant-abutment connections[J]. Int J Oral Maxillofac Implants, 2011, 26(4): 797-806.
[10] 郭智舜, 郭平川. Ankylos种植系统基台机械性并发症的原因及处理方法[J]. 天津医药, 2011, 40(9): 946-947.
[11] 陈宇寰, 张智勇, 张晓, 等. 平台转换种植体基台折断病例回顾性分析[J]. 口腔医学研究, 2016, 32(10): 1092-1095.
[12] Schrotenboer J, Tsao YP, Kinariwala V, et al.Effect of microthreads and platform switching on crestal bone stress levels: a finite element analysis[J]. J Periodontol, 2008, 79(11): 2166-2172.
[13] Canullo L, Fedele GR, Iannello G, et al.Platform switching and marginal bone-level alterations: the results of a randomized-controlled trial[J]. Clin Oral Implants Res, 2010, 21(1): 115-121.
[14] Chu CM, Huang HL, Hsu JT, et al.Influences of internal tapered abutment designs on bone stresses around a dental implant: three-dimensional finite element method with statistical evaluation[J]. J Periodontol, 2012, 83(1): 111-118.
[15] Liu Y, Gao S, Han Y, et al.Bearing capacity of ceramic crowns before and after cyclic loading: an in vitro study[J]. J Mech Behav Biomed Mater, 2018, 87: 197-204.
[16] Elias CN, Fernandes DJ, Resende CR, et al.Mechanical properties, surface morphology and stability of a modified commercially pure high strength titanium alloy for dental implants[J]. Dent Mater, 2015, 31(2): e1-e13.
[17] Tsouknidas A, Lympoudi E, Michalakis K, et al.Influence of alveolar bone loss and different alloys on the biomechanical behavior of internal-and external-connection implants: a three-dimensional finite element analysis[J]. Int J Oral Maxillofac Implants, 2015, 30(3): e30-e42.
[18] Prados-Privado M, Gehrke SA, Rojo R, et al.Complete mechanical characterization of an external hexagonal implant connection: in vitro study, 3D FEM, and probabilistic fatigue[J]. Med Biol Eng Comput, 2018, 56(12): 2233-2244.
[19] D'souza KM, Aras MA. Three-dimensional finite element analysis of the stress distribution pattern in a mandibular first molar tooth restored with five different restorative materials[J]. J Indian Prosthodont Soc, 2017, 17(1): 53-60.
[20] Liu H, Qin L, Wu Y, et al.Oral physiological characteristics among Chinese subjects in the eastern region of China[J]. Arch Oral Biol, 2019, 108: 104539.
[21] Canay S, Akça K.Biomechanical aspects of bone-level diameter shifting at implant-abutment interface[J]. Implant Dent, 2009, 18(3): 239-248.
[22] Bozkaya D, Müftü S.Mechanics of the taper integrated screwed-in (TIS) abutments used in dental implants[J]. J Biomech, 2005, 38(1): 87-97.

种植体-基台连接设计对基台与基台螺丝受力影响的三维有限元分析

Three-dimensional finite element analysis of the influence of different implant-abutment joint design on abutment and abutment screw stress

PDF (PC)

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 15

编辑推荐

Metrics

本文评价

[1]	陈精诚, 赵梦丽, 程志恒, 刘昕. 隐形矫治器上前牙内收过程中侧切牙不同附件设计的三维有限元分析[J]. 上海口腔医学, 2024, 33(4): 360-366.
[2]	韩祥永, 鞠雅琼, 张琳琳, 田芝娟. 聚醚醚酮用于上颌牙列缺失种植固定修复桥架的三维有限元分析[J]. 上海口腔医学, 2024, 33(4): 367-372.
[3]	杨成栋, 向旭东. 牙龈生物型对上颌单颗后牙种植体周围骨组织、软组织健康及龈乳头美学效果的影响[J]. 上海口腔医学, 2024, 33(3): 290-294.
[4]	王彦梅, 何家才. 同期永久基台用于单颗后牙种植修复35例短期疗效观察[J]. 上海口腔医学, 2024, 33(2): 156-159.
[5]	宫汝娟, 何磊. 正畸联合骨水平种植体修复在牙列缺损中的应用效果评价[J]. 上海口腔医学, 2024, 33(1): 76-79.
[6]	谢淑娟, 王林虎, 周荣华. 口腔固定修复金属材料对MRI成像伪影及种植体周围组织健康的影响[J]. 上海口腔医学, 2023, 32(4): 428-431.
[7]	连梅菲, 张修银, 唐天弘, 忻贤贞. 数字化配准法测量种植体植入精度分析[J]. 上海口腔医学, 2023, 32(3): 287-291.
[8]	杨治洁, 唐庭, 刘堃, 张磊, 翟沁凯. 影响种植体生存时间的相关因素分析[J]. 上海口腔医学, 2023, 32(3): 292-297.
[9]	卢雨桐, 史俊宇, 赖红昌. Astra锥形种植体在上颌窦穿牙槽嵴顶提升术中的短期效果评价[J]. 上海口腔医学, 2023, 32(3): 302-307.
[10]	杨晶晶, 毛卫华, 余正荣, 魏洪武, 郭水根. 短种植体随访7~9年的临床疗效及危险因素分析[J]. 上海口腔医学, 2023, 32(2): 214-219.
[11]	谢雪梅, 张佳园, 张野, 俞晓佳, 刘李明, 王健, 于德栋. 龈沟液中sICAM-1、IL-1β和HIF-1α水平与义齿种植修复并发种植体周围炎的关系[J]. 上海口腔医学, 2023, 32(1): 47-51.
[12]	徐晓乾, 李镭. 种植义齿生物学并发症危险因素的回顾性分析[J]. 上海口腔医学, 2023, 32(1): 69-74.
[13]	胡宁, 李凤丹, 江银华. 植骨与否对上颌窦底内提升同期种植术临床疗效的影响[J]. 上海口腔医学, 2023, 32(1): 101-104.
[14]	曹伟玉, 曹捷, 刘宾益, 徐舟, 陆卫青. 2种种植修复制作工艺的Ti-base基台一体冠用于口腔种植单冠修复精度的研究[J]. 上海口腔医学, 2022, 31(4): 414-417.
[15]	涂慧娟, 李凌宇, 李医丹, 罗真兰, 俞明. Er:YAG激光联合引导骨再生治疗种植体周围炎伴骨缺损效果评价[J]. 上海口腔医学, 2022, 31(4): 418-422.