[Evaluation of the accuracy of three-dimensional data acquisition from liquid- interference surfaces assisted by a scanner head with a compressed airflow system].

Q3 Medicine

北京大学学报（医学版） Pub Date : 2025-02-18

Xinkai Xu, Jianjiang Zhao, Sukun Tian, Zhongning Liu, Xiaoyi Zhao, Xiaobo Zhao, Tengfei Jiang, Xiaojun Chen, Chao Ma, Yuchun Sun

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引用次数: 0

Abstract

Objective: To quantitatively evaluate the accuracy of data obtained from liquid-interference surfaces using an intraoral 3D scanner (IOS) integrated with a compressed airflow system, so as to provide clinical proof of accuracy for the application of the compressed airflow system-based scanning head in improving data quality on liquid-interference surfaces.

Methods: The study selected a standard model as the scanning object, adhering to the "YY/T 1818-2022 Dental Science Intraoral Digital Impression Scanner" guidelines, a standard that defined parameters for intraoral scanning. To establish a baseline for accuracy, the ATOS Q 12M scanner, known for its high precision, was used to generate true reference values. These true values served as the benchmark for evaluating the IOS performance. Building on the design of an existing scanner, a new scanning head was developed to integrate with a compressed airflow system. This new design aimed to help the IOS capture high-precision data on surfaces where liquid-interference, such as saliva, might otherwise degrade scanning accuracy. The traditional scanning method, without airflow assistance, was employed as a control group for comparison. The study included five groups in total, one control group and four experimental groups, to investigate the effects of scanning lens obstruction, airflow presence, liquid media, and the use of the new scanning head on scanning process and accuracy. Each group underwent 15 scans, generating ample data for a robust statistical comparison. By evaluating trueness and precision in each group, the study assessed the impact of the compressed airflow system on the accuracy of IOS data collected from liquid-interference surfaces. Additionally, we selected Elite and Primescan scanners as references for numerical accuracy values.

Results: The scanning accuracy on liquid-interference surfaces was significantly reduced in terms of both trueness and precision [Trueness: 18.5 (6.5) vs. 38.0 (6.7), P < 0.05; Precision: 19.1 (8.5) vs. 31.7 (15.0), P < 0.05]. The use of the new scanning head assisted by the compressed airflow system significantly improved the scanning accuracy [Trueness: 22.3(7.6) vs. 38.0 (6.7), P < 0.05; Precision: 25.8 (9.6) vs. 31.7 (15.0), P < 0.05].

Conclusion: The scanning head based on the compressed airflow system can assist in improving the accuracy of data obtained from liquid-interference surfaces by the IOS.

本刊更多论文

[用带压缩气流系统的扫描头辅助液体干涉表面三维数据采集精度的评估]。

目的：定量评价集成压缩气流系统的口腔内三维扫描仪（IOS）对液体干涉面数据采集的准确性，为基于压缩气流系统的扫描头在提高液体干涉面数据质量方面的应用提供准确性的临床依据。方法：选择标准模型作为扫描对象，遵循“YY/T 1818-2022 Dental Science Intraoral Digital印模扫描仪”指南，该指南定义了口腔内扫描的参数。为了建立精度基线，以高精度而闻名的ATOS Q 12M扫描仪被用来生成真实的参考值。这些真实值是评估IOS性能的基准。在现有扫描仪设计的基础上，开发了一种新的扫描头，与压缩气流系统集成。这种新设计旨在帮助IOS捕捉表面的高精度数据，否则液体干扰（如唾液）可能会降低扫描精度。采用无气流辅助的传统扫描法作为对照组进行比较。本研究共分为5组，1个对照组和4个实验组，研究扫描透镜阻塞、气流存在、液体介质和使用新型扫描头对扫描过程和精度的影响。每组都进行了15次扫描，产生了足够的数据进行可靠的统计比较。通过评估各组的准确性和精度，本研究评估了压缩气流系统对液体干涉表面采集的IOS数据准确性的影响。此外，我们选择Elite和Primescan扫描仪作为数值精度值的参考。结果：液体干涉表面的扫描精度在真度和精密度上均显著降低[真度：18.5（6.5）比38.0 (6.7),P < 0.05；精度:19.1(8.5)和31.7 (15.0),P < 0.05)。在压缩气流系统的辅助下，使用新的扫描头可以显著提高扫描精度[准确率：22.3(7.6)vs. 38.0 (6.7), P < 0.05；精密度：25.8（9.6）比31.7 (15.0),P < 0.05。结论：基于压缩气流系统的扫描头有助于提高IOS对液体干涉面数据的准确性。

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

北京大学学报（医学版） Medicine-Medicine (all)

CiteScore

0.80

自引率

0.00%

发文量

9815

期刊介绍： Beijing Da Xue Xue Bao Yi Xue Ban / Journal of Peking University (Health Sciences), established in 1959, is a national academic journal sponsored by Peking University, and its former name is Journal of Beijing Medical University. The coverage of the Journal includes basic medical sciences, clinical medicine, oral medicine, surgery, public health and epidemiology, pharmacology and pharmacy. Over the last few years, the Journal has published articles and reports covering major topics in the different special issues (e.g. research on disease genome, theory of drug withdrawal, mechanism and prevention of cardiovascular and cerebrovascular diseases, stomatology, orthopaedic, public health, urology and reproductive medicine). All the topics involve latest advances in medical sciences, hot topics in specific specialties, and prevention and treatment of major diseases. The Journal has been indexed and abstracted by PubMed Central (PMC), MEDLINE/PubMed, EBSCO, Embase, Scopus, Chemical Abstracts (CA), Western Pacific Region Index Medicus (WPR), JSTChina, and almost all the Chinese sciences and technical index systems, including Chinese Science and Technology Paper Citation Database (CSTPCD), Chinese Science Citation Database (CSCD), China BioMedical Bibliographic Database (CBM), CMCI, Chinese Biological Abstracts, China National Academic Magazine Data-Base (CNKI), Wanfang Data (ChinaInfo), etc.