Impact of short implants numbers and prosthesis design on stress in the posterior mandible: FE analysis.

Q2 Dentistry

Dental Research Journal Pub Date : 2025-03-19 eCollection Date: 2025-01-01 DOI:10.4103/drj.drj_531_24

Hamid Hosseini Naghavi, Reza Amid, Douglas Deporter, Mohammad Ketabi

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引用次数: 0

Abstract

Background: This study assessed the effect of the number of short implants on stress and strain distribution in bone in the posterior mandible using finite element analysis (FEA).

Materials and methods: The study design utilized FEA, a computational technique. In FEA models, short implants (4 mm diameter and 6 mm length) were placed at the site of the mandibular first premolar to the second molar in four models: (I) two implants at the sites of teeth #4 and #7 with two pontics at the sites of teeth #5 and #6, (II) three implants at #4, #5, and #7 with one pontic at #6, (III) three implants at #4, #6, and #7 with one pontic at #5, and (IV) four implants at #4, #5, #6, and #7 with no pontic. A 100 N load was applied vertically and at a 30° angle to the occlusal surface of the crowns. Stress and strain distribution patterns in bone were evaluated using ANSYS Workbench.

Results: The highest maximum von Mises and shear stress and strain values under vertical and off-axial loadings were observed in the model with two short implants at the sites of teeth #4 and #7 with two pontics at the sites of teeth #5 and #6. In general, the highest stress and strain values were recorded following the application of off-axial loads compared to vertical loads. In all models, the highest stress was noted in the cervical part of the implants, while the maximum strain occurred in the apical part of the implants.

Conclusion: Increasing the number of short implants significantly reduces stress and strain values in peri-implant bone.

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短种植体数量和假体设计对后下颌应力的影响：有限元分析。

背景：本研究采用有限元分析（finite element analysis， FEA）评估短种植体数量对后下颌骨应力应变分布的影响。材料与方法：本研究设计采用有限元分析技术。在有限元分析模型中,短的植入物(直径4毫米和6毫米长度)被放置在现场的下颌第一前磨牙第二磨牙四个模型:(I)两个植入牙齿# 4和# 7的网站有两个网站的桥体牙# 5和# 6,(II)三个植入在# 4,# 5,并与一桥体# 6 # 7,(3)三个植入在# 4,# 6和# 7 # 5桥体,和(IV)四个植入在# 4,# 5、# 6和# 7没有桥体。在牙冠咬合面上垂直以30°角施加100 N的载荷。利用ANSYS Workbench对骨的应力应变分布模式进行了分析。结果：在4号和7号牙位置放置2个短种植体，在5号和6号牙位置放置2个支架时，模型在垂直和离轴载荷下的von Mises最大值和剪切应力应变值最高。一般来说，与垂直载荷相比，在施加离轴载荷后记录的应力和应变值最高。在所有模型中，种植体的颈椎部分应力最大，而种植体的根尖部分应变最大。结论：增加短种植体数量可显著降低种植体周围骨的应力应变值。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Dental Research Journal Dentistry-Dentistry (all)

CiteScore

1.70

自引率

0.00%

发文量

审稿时长

52 weeks

期刊介绍： Dental Research Journal, a publication of Isfahan University of Medical Sciences, is a peer-reviewed online journal with Bimonthly print on demand compilation of issues published. The journal’s full text is available online at http://www.drjjournal.net. The journal allows free access (Open Access) to its contents and permits authors to self-archive final accepted version of the articles on any OAI-compliant institutional / subject-based repository. The journal will cover technical and clinical studies related to health, ethical and social issues in field of Dentistry. Articles with clinical interest and implications will be given preference.