Achieving automated and high-precision in situ analysis of the dimensional accuracy and dynamic deformation of 3D-printed surgical templates: an in vitro study.

IF 3.1 3区医学 Q1 DENTISTRY, ORAL SURGERY & MEDICINE

International Journal of Implant Dentistry Pub Date : 2024-10-15 DOI:10.1186/s40729-024-00561-y

Lixing He, Bowen Qin, Rongrong Zhu, Yunxian Liu, Boya Xu, Zhe Li, Liangzhi Du

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引用次数: 0

Abstract

Purpose: To demonstrate the viability of a coordinate-measuring machine (CMM) for the geometric analysis of 3D printed surgical templates.

Methods: The template was designed and modified by adding 18 cylindrical landmarks for CMM test and then classified into five groups according to the slicing software and resins (opaque and transparent): Streamflow-O, Streamflow-T, Shapeware-T, Rayware-T and Polydevs-T (N = 3). Three standing times (0 w, 1 w, and 2 w) were included to observe possible deformation. All the measurements were performed automatically by the CMM through a preset program. The Euclidian distance (dxyz) was regarded as the representation of global dimension accuracy, and displacements in the x-, y-, and z-axes were also calculated.

Results: The average dxyz values of Streamflow-O, Streamflow-T, Shapeware-T, Rayware-T and Polydev-T are 32.6 μm, 31.3 μm, 56.4 μm, 96.4 μm, and 55.3 μm, respectively. Deviations were mainly induced by the upward bending of the free end region (positive direction of the z-axis). Different resins did not have a significant influence on the dimensional accuracy. Moreover, deformation appeared to be negligible after 2 weeks of storage, and the z-axis displacements were only approximately 30 μm at week 1 and 10 μm at week 2.

Conclusions: The deviations of the DLP-printed template are induced mainly by z-axis displacements and are determined by the processing accuracy. After 2 weeks, the dimensional stabilities of these templates are reliable, which is encouraging for clinicians. Moreover, the CMM is preliminarily demonstrated to be a feasible tool for achieving automated geometric analysis of surgical templates.

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实现对 3D 打印手术模板的尺寸精度和动态变形进行自动化和高精度原位分析：一项体外研究。

目的：证明坐标测量机（CMM）对三维打印手术模板进行几何分析的可行性：设计并修改模板，添加 18 个圆柱形地标进行 CMM 测试，然后根据切片软件和树脂（不透明和透明）分为五组：Streamflow-O、Streamflow-T、Shapeware-T、Rayware-T 和 Polydevs-T（N = 3）。为了观察可能出现的变形，还包括三次静置时间（0 w、1 w 和 2 w）。所有测量均由坐标测量机通过预设程序自动完成。欧几里得距离（dxyz）被视为整体尺寸精度的代表，同时还计算了 x、y 和 z 轴的位移：Streamflow-O、Streamflow-T、Shapeware-T、Rayware-T 和 Polydev-T 的平均 dxyz 值分别为 32.6 μm、31.3 μm、56.4 μm、96.4 μm 和 55.3 μm。偏差主要由自由端区域的向上弯曲（z 轴的正方向）引起。不同树脂对尺寸精度的影响不大。此外，存放 2 周后的变形似乎可以忽略不计，第 1 周和第 2 周的 Z 轴位移分别只有约 30 μm 和 10 μm：DLP 打印模板的偏差主要由 Z 轴位移引起，并由加工精度决定。两周后，这些模板的尺寸稳定性是可靠的，这对临床医生来说是令人鼓舞的。此外，坐标测量机初步证明是实现手术模板自动几何分析的可行工具。

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 Implant Dentistry DENTISTRY, ORAL SURGERY & MEDICINE-

CiteScore

1.70

自引率

7.40%

发文量

审稿时长

13 weeks

期刊介绍： The International Journal of Implant Dentistry is a peer-reviewed open access journal published under the SpringerOpen brand. The journal is dedicated to promoting the exchange and discussion of all research areas relevant to implant dentistry in the form of systematic literature or invited reviews, prospective and retrospective clinical studies, clinical case reports, basic laboratory and animal research, and articles on material research and engineering.