Stress and strain distribution in three different mini dental implant designs using in implant retained overdenture: a finite element analysis study.

ORAL and Implantology Pub Date : 2016-10-01 DOI:10.11138/orl/2016.9.4.202

W. Aunmeungtong, P. Khongkhunthian, Pimuden Rungsiyakull

{"title":"Stress and strain distribution in three different mini dental implant designs using in implant retained overdenture: a finite element analysis study.","authors":"W. Aunmeungtong, P. Khongkhunthian, Pimuden Rungsiyakull","doi":"10.11138/orl/2016.9.4.202","DOIUrl":null,"url":null,"abstract":"Finite Element Analysis (FEA) has been used for prediction of stress and strain between dental implant components and bone in the implant design process. PURPOSE Purpose of this study was to characterize and analyze stress and strain distribution occurring in bone and implants and to compare stress and strain of three different implant designs. MATERIALS AND METHODS Three different mini dental implant designs were included in this study: 1. a mini dental implant with an internal implant-abutment connection (MDIi); 2. a mini dental implant with an external implant-abutment connection (MDIe); 3. a single piece mini dental implant (MDIs). All implant designs were scanned using micro-CT scans. The imaging details of the implants were used to simulate models for FEA. An artificial bone volume of 9×9 mm in size was constructed and each implant was placed separately at the center of each bone model. All bone-implant models were simulatively loaded under an axial compressive force of 100 N and a 45-degree force of 100 N loading at the top of the implants using computer software to evaluate stress and strain distribution. RESULTS There was no difference in stress or strain between the three implant designs. The stress and strain occurring in all three mini dental implant designs were mainly localized at the cortical bone around the bone-implant interface. Oblique 45° loading caused increased deformation, magnitude and distribution of stress and strain in all implant models. CONCLUSIONS Within the limits of this study, the average stress and strain in bone and implant models with MDIi were similar to those with MDIe and MDIs. The oblique 45° load played an important role in dramatically increased average stress and strain in all bone-implant models. CLINICAL IMPLICATIONS Mini dental implants with external or internal connections have similar stress distribution to single piece mini dental implants. In clinical situations, the three types of mini dental implant should exhibit the same behavior to chewing force.","PeriodicalId":38303,"journal":{"name":"ORAL and Implantology","volume":"9 4 1","pages":"202-212"},"PeriodicalIF":0.0000,"publicationDate":"2016-10-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://sci-hub-pdf.com/10.11138/orl/2016.9.4.202","citationCount":"21","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"ORAL and Implantology","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.11138/orl/2016.9.4.202","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}

引用次数: 21

Abstract

Finite Element Analysis (FEA) has been used for prediction of stress and strain between dental implant components and bone in the implant design process. PURPOSE Purpose of this study was to characterize and analyze stress and strain distribution occurring in bone and implants and to compare stress and strain of three different implant designs. MATERIALS AND METHODS Three different mini dental implant designs were included in this study: 1. a mini dental implant with an internal implant-abutment connection (MDIi); 2. a mini dental implant with an external implant-abutment connection (MDIe); 3. a single piece mini dental implant (MDIs). All implant designs were scanned using micro-CT scans. The imaging details of the implants were used to simulate models for FEA. An artificial bone volume of 9×9 mm in size was constructed and each implant was placed separately at the center of each bone model. All bone-implant models were simulatively loaded under an axial compressive force of 100 N and a 45-degree force of 100 N loading at the top of the implants using computer software to evaluate stress and strain distribution. RESULTS There was no difference in stress or strain between the three implant designs. The stress and strain occurring in all three mini dental implant designs were mainly localized at the cortical bone around the bone-implant interface. Oblique 45° loading caused increased deformation, magnitude and distribution of stress and strain in all implant models. CONCLUSIONS Within the limits of this study, the average stress and strain in bone and implant models with MDIi were similar to those with MDIe and MDIs. The oblique 45° load played an important role in dramatically increased average stress and strain in all bone-implant models. CLINICAL IMPLICATIONS Mini dental implants with external or internal connections have similar stress distribution to single piece mini dental implants. In clinical situations, the three types of mini dental implant should exhibit the same behavior to chewing force.

查看原文本刊更多论文

三种小型种植体在种植固位覆盖义齿中的应力应变分布:有限元分析研究。

在种植体设计过程中，有限元分析(FEA)已被用于预测牙种植体构件与骨之间的应力和应变。目的本研究的目的是描述和分析骨和种植体的应力和应变分布，并比较三种不同种植体设计的应力和应变。材料与方法本研究采用三种不同的微型种植体设计:1。内置种植体-基台连接(MDIi)的迷你种植体;2. 带有外部种植体-基台连接(MDIe)的迷你牙种植体;3.单片微型牙种植体(MDIs)所有种植体设计均采用微ct扫描。利用植入物的成像细节模拟模型进行有限元分析。构建人工骨体积9×9 mm，每个种植体分别放置在每个骨模型的中心。所有骨-种植体模型在100 N的轴向压缩力和100 N 45度的种植体顶部载荷下，通过计算机软件模拟加载，评估应力应变分布。结果三种种植体的应力应变无明显差异。三种微型种植体的应力和应变主要集中在骨-种植体界面周围的皮质骨上。倾斜45°加载导致所有种植体模型的变形、大小和应力应变分布增加。结论在本研究范围内，MDIi骨和种植体模型的平均应力和应变与MDIe和mdi模型相似。在所有骨种植体模型中，倾斜45°载荷在显著增加平均应力和应变中起重要作用。临床意义外连接或内连接的微型种植体与单片微型种植体的应力分布相似。在临床应用中，三种微型种植体对咀嚼力应表现出相同的行为。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

求助全文

约1分钟内获得全文求助全文

来源期刊

ORAL and Implantology Dentistry-Dentistry (all)

自引率

0.00%

发文量