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三种不同机械要求下四颗牙科植入物的扫描电子显微镜分析与显微计算机断层扫描评估——体外研究

SEM Analysis and Micro-CT Evaluation of Four Dental Implants after Three Different Mechanical Requests-In Vitro Study.

作者信息

Vinhas Ana Sofia, Salazar Filomena, Mendes José Manuel, Silva António Sérgio, Ríos-Carrasco Blanca, Ríos-Santos José Vicente, Gil Javier, Herrero-Climent Mariano, Aroso Carlos

机构信息

Oral Pathology and Rehabilitation Research Unit (UNIPRO), University Institute of Health Sciences (IUCS), CESPU, Rua Central de Gandra, 4585-116 Gandra, Portugal.

Department of Periodontology, School of Dentistry, Universidad de Sevilla, C/Avicena S/N, 41009 Sevilla, Spain.

出版信息

Materials (Basel). 2024 Jan 16;17(2):434. doi: 10.3390/ma17020434.

DOI:10.3390/ma17020434
PMID:38255602
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10820107/
Abstract

STATEMENT OF PROBLEM

Implant-supported rehabilitations are an increasingly frequent practice to replace lost teeth. Before clinical application, all implant components should demonstrate suitable durability in laboratory studies, through fatigue tests.

OBJECTIVE

The purpose of this in vitro study was to evaluate the integrity and wear of implant components using SEM, and to assess the axial displacement of the implant-abutment assembly by Micro-CT, in different implant connections, after three distinct mechanical requests.

MATERIALS AND METHODS

Four KLOCKNER implants (external connection SK2 and KL; and internal connection VEGA and ESSENTIAL) were submitted to three different mechanical requests: single tightening, multiple tightening, and multiple tightening and cyclic loading (500 N × 100 cycles). A total of 16 samples were evaluated by SEM, by the X-ray Bragg-Brentano method to obtain residual stresses, and scratch tests were realized for each surface and Micro-CT (4 control samples; 4 single tightening; 4 multiple tightening; 4 multiple tightening and cyclic loading). All dental implants were fabricated with commercially pure titanium (grade 3 titanium). Surface topography and axial displacement of abutment into the implant, from each group, were evaluated by SEM and Micro-CT.

RESULTS

In the manufacturing state, implants and abutments revealed minor structural changes and minimal damage from the machining process. The application of the tightening torque and loading was decisive in the appearance and increase in contact marks on the faces of the hexagon of the abutment and the implant. Vega has the maximum compressive residual stress and, as a consequence, higher scratch force. The abutment-implant distances in SK2 and KL samples did not show statistically significant differences, for any of the mechanical demands analyzed. In contrast, statistically significant differences were observed in abutment-implant distance in the internal connection implants Vega and Essential.

CONCLUSIONS

The application of mechanical compression loads caused deformation and contact marks in all models tested. Only internal connection implants revealed an axial displacement of the abutment into the implant, but at a general level, a clear intrusion of the abutment into the implant could only be confirmed in the Essential model, which obtained its maximal axial displacement with cyclic loading.

摘要

问题陈述

种植体支持的修复是一种越来越常见的失牙替代方法。在临床应用之前,所有种植体部件都应在实验室研究中通过疲劳测试证明具有合适的耐久性。

目的

本体外研究的目的是使用扫描电子显微镜(SEM)评估种植体部件的完整性和磨损情况,并通过显微计算机断层扫描(Micro-CT)评估在三种不同机械要求下,不同种植体连接方式中种植体-基台组件的轴向位移。

材料与方法

四颗克洛克纳种植体(外部连接的SK2和KL;以及内部连接的VEGA和ESSENTIAL)接受三种不同的机械要求:单次拧紧、多次拧紧以及多次拧紧和循环加载(500 N×100次循环)。通过扫描电子显微镜(SEM)、采用X射线布拉格-布伦塔诺方法获取残余应力,对总共16个样本进行评估,并对每个表面进行划痕试验以及显微计算机断层扫描(4个对照样本;4个单次拧紧样本;4个多次拧紧样本;4个多次拧紧和循环加载样本)。所有牙科种植体均采用商业纯钛(3级钛)制造。通过扫描电子显微镜(SEM)和显微计算机断层扫描(Micro-CT)评估每组中基台进入种植体时的表面形貌和轴向位移。

结果

在制造状态下,种植体和基台显示出微小的结构变化以及加工过程造成的最小损伤。拧紧扭矩和加载的应用对基台和种植体六边形表面上接触痕迹的出现和增加起决定性作用。VEGA具有最大的压缩残余应力,因此具有更高的划痕力。对于所分析的任何机械要求,SK2和KL样本中的基台-种植体距离均未显示出统计学上的显著差异。相比之下,在内部连接种植体VEGA和ESSENTIAL中,观察到基台-种植体距离存在统计学上的显著差异。

结论

机械压缩载荷的应用在所有测试模型中均导致变形和接触痕迹。只有内部连接种植体显示出基台向种植体内的轴向位移,但总体而言,仅在ESSENTIAL模型中证实了基台明显侵入种植体,该模型在循环加载时获得了最大轴向位移。

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