Professor and Head of Department, Department of Prosthodontics, Crown & Bridge, T P C T's Terna Dental College, Navi Mumbai, India.
Reader, Department of Prosthodontics, Crown & Bridge, T P C T's Terna Dental College, Navi Mumbai, India.
J Prosthet Dent. 2022 Sep;128(3):436-442. doi: 10.1016/j.prosdent.2020.12.035. Epub 2021 Feb 12.
The process of manufacturing stereolithographic surgical guides for static computer-guided implant placement involves a series of steps. Errors can be incorporated in various forms and at various stages of manufacturing these guides. Errors introduced during this process have not been fully investigated.
The purpose of this in vitro study was to assess the errors introduced during the manufacture of stereolithographic surgical guides generated from cone beam computed tomography (CBCT) and digital scans by using a virtual implant planning software.
Ten stereolithographic surgical guides with the associated standard tessellation language (STL) files of their virtual design were used in this study. The STL files of the virtual design and the scans of the stereolithographic surgical guides were superimposed. Linear deviation at the center of the sleeve top and sleeve base and the angular deviation at the center of the sleeve were measured.
The minimum and maximum linear deviation at the center of the sleeve top and the sleeve base was found to be 0 and 40 μm, with less linear deviation observed at the center of the sleeve top (mean ±standard deviation 18 ±7 μm) than at the center of the sleeve base (20 ±7 μm). The minimum and maximum angular deviation at the center of the sleeve was found to be 0 degrees and 5.9 degrees respectively, with a mean ± standard deviation of 1.36 ±0.74 degrees.
Errors were found in the sleeve position between the virtual design and the stereolithographically manufactured surgical guide. This error may introduce errors in the final implant position.
制作用于静态计算机引导种植体放置的立体光刻手术导板的过程涉及一系列步骤。在制造这些导板的各个阶段和各种形式中都可能出现误差。制造过程中引入的误差尚未得到充分研究。
本体外研究的目的是评估使用虚拟种植体规划软件从锥形束计算机断层扫描(CBCT)和数字扫描生成的立体光刻手术导板制造过程中引入的误差。
本研究使用了 10 个立体光刻手术导板及其虚拟设计的相关标准 tessellation language(STL)文件。将虚拟设计的 STL 文件与立体光刻手术导板的扫描进行叠加。测量套管顶部和底部中心的线性偏差以及套管中心的角度偏差。
套管顶部和底部中心的最小和最大线性偏差分别为 0 和 40 μm,套管顶部中心的线性偏差(平均值 ± 标准差 18 ± 7 μm)小于套管底部中心(20 ± 7 μm)。套管中心的最小和最大角度偏差分别为 0 度和 5.9 度,平均值 ± 标准差为 1.36 ± 0.74 度。
在虚拟设计和立体光刻制造的手术导板之间的套管位置发现存在误差。这种误差可能会导致最终种植体位置的误差。