Error analysis of stages involved in CBCT-guided implant placement with surgical guides when different printing technologies are used

IF 4.3 2区 医学 Q1 DENTISTRY, ORAL SURGERY & MEDICINE Journal of Prosthetic Dentistry Pub Date : 2024-11-01 DOI:10.1016/j.prosdent.2022.11.018
Brandon Yeager DMD MS , Gülce Çakmak DDS PhD , Fengyun Zheng DDS, PhD , William Michael Johnston PhD , Burak Yilmaz DDS PhD
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Abstract

Statement of problem

Digital light processing (DLP), continuous liquid interface printing (CLIP), and stereolithography (SLA) technologies enable 3-dimensional (3D) printing of surgical guides. However, how their accuracy compares and how accuracy may affect subsequent steps in guided surgery is unclear.

Purpose

The purpose of this in vitro study was to investigate the fabrication and seating accuracy of surgical guides printed by using DLP, SLA, and CLIP technologies and evaluate the positional deviation of the osteotomy site and placed implant compared with the digital implant plan.

Material and methods

Twenty-one polyurethane models were divided into 3 groups and used to plan implants and design surgical guides. The guides were fabricated by using DLP, SLA, or CLIP 3D printers (n=7) and scanned, and the scan file was compared with the digital design file to analyze the fabrication accuracy at the intaglio and overall external surfaces using root mean square (RMS) values. The triple scan protocol was used to evaluate the seating accuracy of the guides on their respective models. Osteotomies were prepared on models by using the guides followed by a microcomputed tomography image of each osteotomy. The implants were placed through the guides, the scan bodies were tightened to implants, and the models were scanned to obtain the images of placed implant position. Osteotomy and placed implant images were used to calculate the entry point, apex, and long axis deviations from the planned implant position with a software program. A 2-way repeated-measures ANOVA of the RMS data was used to analyze printing and seating trueness, and homogeneity of variance analyses were used at each surface for precision. A 3-way repeated-measures ANOVA was used to analyze distance deviations over the stages (osteotomy and final implant) and locations studied, and a 2-way repeated-measures ANOVA was used for angular deviations. Homogeneity of variance analyses were performed for precision (α=.05).

Results

The 3D printer type significantly affected the trueness of the guide at the intaglio surface (P<.001). SLA guides had the lowest mean RMS (59.04 μm) for intaglio surface, while CLIP had the highest mean RMS (117.14 μm). Guides from all 3D printers had low variability among measured deviations and therefore were similarly precise. The seating accuracy of SLA and DLP guides was not significantly different, but both had lower mean RMS values than CLIP (P=.003 for SLA, P=.014 for DLP). There were no significant interactions between the stage of surgery, the printer type, or the location of implant deviation (P=.734). Only the location of deviation (cervical versus apical) had a significant effect on distance deviations (P<.001). The printer type, stage of surgery, and their interaction did not significantly affect angular deviations (P=.41).

Conclusions

The 3D printing technology affected printing trueness. The intaglio surface trueness was higher with SLA and overall trueness was higher with the CLIP printer. The precision of all guides was similarly high. Guides from SLA and DLP printers had more accurate seating than those from CLIP. Higher deviations were observed at the apex; however, osteotomy and final implant position did not significantly differ from the digitally planned position.
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使用不同的打印技术,对 CBCT 引导下使用手术导板植入种植体的各个阶段进行误差分析。
问题陈述:数字光处理(DLP)、连续液体界面打印(CLIP)和立体光刻(SLA)技术可实现手术导板的三维(3D)打印。目的:本体外研究旨在调查使用 DLP、SLA 和 CLIP 技术打印的手术导板的制作和就位精度,并评估截骨部位和植入种植体的位置偏差与数字种植计划的比较:将 21 个聚氨酯模型分为 3 组,用于规划种植体和设计手术导板。使用 DLP、SLA 或 CLIP 3D 打印机制作导板(n=7)并进行扫描,扫描文件与数字设计文件进行比较,使用均方根(RMS)值分析凹槽和整体外表面的制作精度。三重扫描方案用于评估导板在各自模型上的就位精度。使用导板在模型上准备截骨,然后对每个截骨进行微计算机断层扫描成像。通过导板植入种植体,将扫描体紧固到种植体上,然后扫描模型以获得植入种植体位置的图像。利用截骨和植入的种植体图像,通过软件程序计算出与计划植入位置的入口点、顶点和长轴偏差。使用RMS数据的双向重复测量方差分析来分析印刷和就位的真实性,并对每个表面的精度进行同质性方差分析。采用 3 向重复测量方差分析来分析研究阶段(截骨和最终种植)和位置的距离偏差,并采用 2 向重复测量方差分析来分析角度偏差。对精度进行了同质性方差分析(α=.05):结果:3D 打印机的类型对凹版表面的导轨真实度有明显影响(PConclusions.3D 打印机的类型对凹版表面的导轨真实度有明显影响):三维打印技术会影响打印精度。SLA 打印机的凹版表面真实度更高,而 CLIP 打印机的整体真实度更高。所有导轨的精度同样很高。SLA 和 DLP 打印机的导轨比 CLIP 打印机的导轨定位更准确。在顶点观察到的偏差较大;但是,截骨和最终种植体位置与数字计划位置没有明显差异。
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
Journal of Prosthetic Dentistry
Journal of Prosthetic Dentistry 医学-牙科与口腔外科
CiteScore
7.00
自引率
13.00%
发文量
599
审稿时长
69 days
期刊介绍: The Journal of Prosthetic Dentistry is the leading professional journal devoted exclusively to prosthetic and restorative dentistry. The Journal is the official publication for 24 leading U.S. international prosthodontic organizations. The monthly publication features timely, original peer-reviewed articles on the newest techniques, dental materials, and research findings. The Journal serves prosthodontists and dentists in advanced practice, and features color photos that illustrate many step-by-step procedures. The Journal of Prosthetic Dentistry is included in Index Medicus and CINAHL.
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