Design, numerical simulation, and in vitro examination of a CAD/CAM-fabricated active orthodontic treatment element.

IF 1.8 4区医学 Q2 DENTISTRY, ORAL SURGERY & MEDICINE

International Journal of Computerized Dentistry Pub Date : 2023-05-26 DOI:10.3290/j.ijcd.b3759633

Anja Ratzmann, Mathias Christian Wessling, Karl-Friedrich Krey

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引用次数: 0

Abstract

Aim: Orthodontic treatments with custom-made active elements may lead to more efficient treatment with fewer side effects. The objective of the present in vitro study was to determine whether individually constructed, mathematically simulated, and 3D-printed power chains could generate adequate forces for orthodontic tooth movement.

Materials and methods: An individual measurement device was developed using a high-precision load cell, amplifier, and microcontroller for signal processing. Elastic chains were designed and subsequently printed from two different thermoplastic polyurethane (TPU) filaments and a thermoplastic elastomer (TPE) filament. With the CAD data, a finite element analysis (FEA) was performed to calculate the reactive forces to be expected at different activation levels. The measured force development of the test objects was compared with the results from the FEA.

Results: The results showed a high precision of the measurement device, with an intraclass correlation coefficient (ICC) of 0.999 and a Dahlberg error of 0.05 N. The measured forces ranged from 196 to 681 g. There was a significant correlation between the measured and calculated forces (R 0.91 to 0.98).

Discussion: In the present study, the fully digital workflow of producing an individualized active orthodontic treatment element, which developed almost exactly the force values calculated in the FEA, was shown. Future clinical use seems promising, in combination with fully individualized and digitally planned treatment approaches. This offers the possibility to integrate these insights from exemplary applications into patient-specific digital planning in orthodontics. The combination of CBCT root reconstruction, intraoral scans with customized brackets, and wires is the perfect starting point to add mechanical and numerical simulations. This would be the next step from shape-driven planning to force-driven planning. The goal is to reduce treatment time and negative side effects, eg, root resorption.

Conclusion: The present in vitro study is the first to show the possible individualized construction and 3D printing of elastic chains exhibiting reproducible, predefined forces.

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CAD/ cam制造的主动正畸治疗元件的设计、数值模拟和体外检查。

目的:使用定制的活性元素进行正畸治疗，可以提高治疗效率，减少副作用。目前体外研究的目的是确定单独构建，数学模拟和3d打印的动力链是否可以为正畸牙齿运动产生足够的力。材料和方法:使用高精度称重传感器、放大器和用于信号处理的微控制器开发了一个单独的测量装置。设计并随后打印了两种不同的热塑性聚氨酯(TPU)长丝和热塑性弹性体(TPE)长丝的弹性链。利用CAD数据，进行有限元分析(FEA)，计算不同激活水平下的预期反作用力。将测试对象的力发展测量结果与有限元分析结果进行了比较。结果:该测量装置具有较高的测量精度，类内相关系数(ICC)为0.999,Dahlberg误差为0.05 n，测量力范围为196 ~ 681 g。测量力与计算力之间存在显著相关性(R = 0.91 ~ 0.98)。讨论:在本研究中，显示了生产个性化主动正畸治疗元件的全数字化工作流程，该工作流程几乎完全符合FEA中计算的力值。与完全个性化和数字化计划治疗方法相结合，未来的临床应用似乎很有希望。这提供了将这些见解从示范应用整合到正畸患者特定数字规划中的可能性。结合CBCT牙根重建、定制托槽的口腔内扫描和金属丝是添加力学和数值模拟的完美起点。这将是从形状驱动规划到力驱动规划的下一步。目的是减少治疗时间和副作用，如牙根吸收。结论:目前的体外研究首次展示了弹性链的个性化构建和3D打印的可能性，这些弹性链具有可复制的、预定义的力。

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

International Journal of Computerized Dentistry Dentistry-Dentistry (miscellaneous)

CiteScore

2.90

自引率

0.00%

发文量

期刊介绍： This journal explores the myriad innovations in the emerging field of computerized dentistry and how to integrate them into clinical practice. The bulk of the journal is devoted to the science of computer-assisted dentistry, with research articles and clinical reports on all aspects of computer-based diagnostic and therapeutic applications, with special emphasis placed on CAD/CAM and image-processing systems. Articles also address the use of computer-based communication to support patient care, assess the quality of care, and enhance clinical decision making. The journal is presented in a bilingual format, with each issue offering three types of articles: science-based, application-based, and national society reports.