用于牙科的三点弯曲测试3D打印定制修复材料的原子力显微镜分析

AFM Analysis of a Three-Point Flexure Tested, 3D Printing Definitive Restoration Material for Dentistry.

作者信息

Sandmair Maximilian N, Kleber Christoph, Ströbele Dragan A, von See Constantin

机构信息

Research Center for Digital Technologies in Dentistry and CAD/CAM, Department of Dentistry, Faculty of Medicine and Dentistry, Danube Private University, 3500 Krems, Austria.

Department of Medicine, Faculty of Medicine and Dentistry, Danube Private University, 3500 Krems, Austria.

出版信息

J Funct Biomater. 2023 Mar 10;14(3):152. doi: 10.3390/jfb14030152.

DOI:10.3390/jfb14030152

PMID:36976076

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10056548/

Abstract

BACKGROUND

Three-dimensional printing is a rapidly developing technology across all industries. In medicine recent developments include 3D bioprinting, personalized medication and custom prosthetics and implants. To ensure safety and long-term usability in a clinical setting, it is essential to understand material specific properties. This study aims to analyze possible surface changes of a commercially available and approved DLP 3D printed definitive restoration material for dentistry after three-point flexure testing. Furthermore, this study explores whether Atomic Force Microscopy (AFM) is a feasible method for examination of 3D printed dental materials in general. This is a pilot study, as there are currently no studies that analyze 3D printed dental materials using an AFM.

METHODS

The present study consisted of a pretest followed by the main test. The resulting break force of the preliminary test was used to determine the force used in the main test. The main test consisted of atomic force microscopy (AFM) surface analysis of the test specimen followed by a three-point flexure procedure. After bending, the same specimen was analyzed with the AFM again, to observe possible surface changes.

RESULTS

The mean root mean square (RMS) roughness of the segments with the most stress was 20.27 nm (±5.16) before bending, while it was 26.48 nm (±6.67) afterward. The corresponding mean roughness (Ra) values were 16.05 nm (±4.25) and 21.19 nm (±5.71) Conclusions: Under three-point flexure testing, the surface roughness increased significantly. The -value for RMS roughness was = 0.003, while it was = 0.006 for Ra. Furthermore, this study showed that AFM surface analysis is a suitable procedure to investigate surface changes in 3D printed dental materials.

摘要

背景

三维打印是一项在所有行业中迅速发展的技术。在医学领域，最近的进展包括3D生物打印、个性化药物以及定制假体和植入物。为确保在临床环境中的安全性和长期可用性，了解材料的特定属性至关重要。本研究旨在分析一种市售且已获批准的用于牙科的DLP 3D打印最终修复材料在三点弯曲测试后的可能表面变化。此外，本研究探讨原子力显微镜（AFM）总体上是否是检查3D打印牙科材料的可行方法。这是一项初步研究，因为目前尚无使用AFM分析3D打印牙科材料的研究。

方法

本研究包括预测试，然后是主测试。预测试产生的断裂力用于确定主测试中使用的力。主测试包括对测试样本进行原子力显微镜（AFM）表面分析，然后进行三点弯曲程序。弯曲后，再次使用AFM对同一标本进行分析，以观察可能的表面变化。

结果

应力最大的部分在弯曲前的平均均方根（RMS）粗糙度为20.27 nm（±5.16），而弯曲后的平均均方根粗糙度为26.48 nm（±6.67）。相应的平均粗糙度（Ra）值分别为16.05 nm（±4.25）和21.19 nm（±5.71）。结论：在三点弯曲测试下，表面粗糙度显著增加。RMS粗糙度的p值为p = 0.003，而Ra的p值为p = 0.006。此外，本研究表明AFM表面分析是研究3D打印牙科材料表面变化的合适方法。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/335c/10056548/0a0c9efc82ab/jfb-14-00152-g001.jpg

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用于牙科的三点弯曲测试3D打印定制修复材料的原子力显微镜分析

AFM Analysis of a Three-Point Flexure Tested, 3D Printing Definitive Restoration Material for Dentistry.

作者信息

机构信息

出版信息

BACKGROUND

METHODS

RESULTS

背景

方法

结果

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