上颌颌板-上颌牙列扫描匹配方式对数字化转移上颌位置的影响

doi:10.13701/j.cnki.kqyxyj.2022.12.015

口腔医学研究 ›› 2022, Vol. 38 ›› Issue (12): 1177-1181.DOI: 10.13701/j.cnki.kqyxyj.2022.12.015

上颌颌板-上颌牙列扫描匹配方式对数字化转移上颌位置的影响

马腾¹, 张敏迪¹, 彭体武¹, 杨志康¹, 任光辉^2*

1.滨州医学院山东烟台 264003;
2.滨州医学院附属烟台口腔医院咬合门诊山东烟台 264001

收稿日期:2022-06-10 出版日期:2022-12-28 发布日期:2022-12-26
通讯作者: *任光辉,E-mail:yaoxue1997@sina.com
作者简介:马腾(1997~ ),男,山东菏泽人,硕士在读,研究方向:口腔数字化技术。
基金资助:
烟台市口腔医院重大项目(编号:201907)

Effect of Maxillary Plate-maxillary Arch Scanning Matching Method on Maxillary Position Transferred Digitally

MA Teng¹, ZHANG Mindi¹, PENG Tiwu¹, YANG Zhikang¹, REN Guanghui^2*

1. Binzhou Medical University, Yantai 264003, China;
2. Center for Occlusion, Yantai Stomatological Hospital Affiliated to Binzhou Medical University, Yantai 264001, China

Received:2022-06-10 Online:2022-12-28 Published:2022-12-26

摘要/Abstract

摘要： 目的: 研究在齿科设计软件中应用不同上颌颌板-上颌牙列扫描匹配方式对数字化转移上颌位置的影响。方法: 使用下颌运动分析系统对10位受试者进行下颌运动记录,通过口内扫描获得上下颌数字模型及咬合关系。本实验共涉及5种上颌颌板-上颌牙列扫描匹配方式,包括:整体扫描组(ES组)、单次扫描组(SS组)与双面扫描组(DS组)、单次扫描匹配上颌组(SSU组)、双面扫描匹配上颌组(DSU组)。将口内扫描数据、上颌颌板-上颌牙列数字模型与下颌运动数据导入至CAD软件中,以完成数字化上牙合架,测量上颌左侧第一磨牙近中颊尖至虚拟牙合架左侧髁球距离、上颌右侧第一磨牙近中颊尖至虚拟牙合架右侧髁球距离、上颌中切牙近中切点至虚拟牙合架左、右髁球距离。每种方法重复3次,所得结果取平均值后进行统计分析。结果: 通过上述5种方法转移的上颌位置,所测量的上颌左侧第一磨牙近中颊尖至虚拟牙合架左侧髁球距离、上颌右侧第一磨牙近中颊尖至虚拟牙合架右侧髁球距离、上颌中切牙近中切点至虚拟牙合架左、右髁球距离,无显著性差异(P＞0.05)。结论: 本实验选取的5种获得上颌颌板-上颌牙列数字模型的扫描匹配方式均可用于齿科设计软件中上颌位置的数字化转移。

关键词: 上颌颌板, 上颌位置, 下颌运动分析系统, 虚拟牙合架

Abstract: Objective: To study the effect of different maxillary plate-Maxillary arch scanning matching methods on the transfer of maxillary position in the dental computer-aided design software. Methods: Jaw movement analysis system was used to record the mandibular motion of 10 subjects. Maxillary and mandibular digital cast and occlusal relationship were obtained by intra-oral scanning. This study involved five methods, include: entirely scan group (ES), single scan group (SS), double-sided scan group (DS), single scan matched the upper jaw group (SSU), and double-sided scan matched the upper jaw group (DSU). Intra-oral scan data, maxillary plate-maxillary arch digital model, and mandibular motion data were imported into the CAD software to complete digital mounting. In the virtual articulator module, the distance from left maxillary first molar to left condylar element, distance from right maxillary first molar to right condylar element and the distance from right and left condylar elements to the incisal embrasure between maxillary central incisors were measured. Results: Among five kinds of maxillary position transferring methods, there was no significant difference on the distance from left maxillary first molar to left condylar element, distance from right maxillary first molar to right condylar element, and distance from right and left condylar elements to the incisal embrasure between maxillary central incisors on virtual articulator (P>0.05). Conclusion: Five scanning matching methods selected in this study to obtain maxillary plate-maxillary arch digital model can be used to transfer maxillary position in the CAD software.

Key words: maxillary plate, maxillary position, jaw movement analysis system, virtual articulator

马腾, 张敏迪, 彭体武, 杨志康, 任光辉. 上颌颌板-上颌牙列扫描匹配方式对数字化转移上颌位置的影响[J]. 口腔医学研究, 2022, 38(12): 1177-1181.

MA Teng, ZHANG Mindi, PENG Tiwu, YANG Zhikang, REN Guanghui. Effect of Maxillary Plate-maxillary Arch Scanning Matching Method on Maxillary Position Transferred Digitally[J]. Journal of Oral Science Research, 2022, 38(12): 1177-1181.

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上颌颌板-上颌牙列扫描匹配方式对数字化转移上颌位置的影响

Effect of Maxillary Plate-maxillary Arch Scanning Matching Method on Maxillary Position Transferred Digitally

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