EXPERIMENTAL AND MATHEMATICAL DETERMINATION OF DEFORMATION RISKS OF DENTAL MATRICES DURING ANATOMICAL ADAPTATION TO THE PROXIMAL SURFACE OF THE TOOTH

Actual problems in dentistry Pub Date : 2023-08-21 DOI:10.18481/2077-7566-2023-19-2-44-50

V. Shefov

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Abstract

Introduction. Creating high-quality interdental contacts is the most important and difficult step in the treatment of proximal caries. In modern dentistry, most methods for restoring the proximal wall of teeth involve the use of dental matrices. The choice of matrix and the peculiarities of working with it are the determining factor in the formation of the proximal contour of the tooth and often causes difficulties, especially for young specialists. The aim of the study is to conduct an experimental-mathematical determination of the tensile strength of dental matrices to elastic deformation based on the curvature of the proximal surface of the chewing teeth. Materials and methods. The work consisted of 2 stages. Initially, a test bench was developed to assess the deformation capabilities of dental matrices, consisting of a strain gauge and a model of the proximal tooth wall with the possibility of fixing the matrix and imitating pushing. The model was created in SolidWorks software and 3D printed from light-cured polyamide. At the second stage, computer models of teeth and matrices were created, as well as an analysis of data from x-rays and other sources. Results. In the course of the work, the strength characteristics of dental matrices were obtained, the limits of their deformation capabilities were determined depending on the thickness of the material and the area of impact on it. Titanium matrices have the best strength characteristics, withstanding a force of 70 N, with an impact area of 2.25 mm2. An analysis of the curvature of the proximal surfaces of the chewing teeth revealed the best match between the matrix contour and the tooth contour on the medial surface of the first molars of the upper and lower jaws. Conclusions. To achieve high results in the restoration of the proximal walls of the teeth, in most cases it is recommended to press the matrix with an instrument with a working area of at least 2 mm2.

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在牙齿近端表面解剖适应过程中，牙基质变形风险的实验和数学测定

介绍。建立高质量的牙间接触是治疗近端龋最重要也是最困难的一步。在现代牙科中，大多数修复牙齿近端壁的方法都涉及到使用牙基质。基质的选择和工作的特殊性是牙齿近端轮廓形成的决定性因素，经常造成困难，特别是对年轻的专家。本研究的目的是对基于咀嚼牙齿近端表面曲率的牙基质弹性变形的抗拉强度进行实验-数学测定。材料和方法。这项工作分为两个阶段。最初，我们开发了一个测试台来评估牙基质的变形能力，该测试台由应变计和近端牙壁模型组成，可以固定基质并模拟推动。该模型是在SolidWorks软件中创建的，并用光固化聚酰胺进行3D打印。在第二阶段，创建牙齿和基质的计算机模型，以及对x射线和其他来源的数据进行分析。结果。在工作过程中，获得了牙基质的强度特性，根据材料的厚度和对其的冲击面积确定了其变形能力的极限。钛基具有最好的强度特性，承受70 N的力，冲击面积为2.25 mm2。通过对咀嚼牙近端表面曲率的分析，发现基质轮廓与上下颌第一磨牙内侧表面的牙齿轮廓最吻合。结论。为了获得良好的修复效果，在大多数情况下，建议使用工作面积至少为2mm2的器械按压基质。

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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Actual problems in dentistry

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