通过二维和三维放射影像数据确定单个牙齿的阻力中心。

Locating the center of resistance in individual teeth via two- and three-dimensional radiographic data.

作者信息

Geiger M E, Lapatki B G

机构信息

Department of Orthodontics, Clinic of Orthodontics, University of Ulm Dental School, Albert-Einstein-Allee 11, 89081, Ulm, Germany,

出版信息

J Orofac Orthop. 2014 Mar;75(2):96-106. doi: 10.1007/s00056-013-0198-0. Epub 2014 Mar 2.

DOI:10.1007/s00056-013-0198-0

PMID:24577014

Abstract

OBJECTIVES

The preferred reference point to describe the force-moment system exerted upon a tooth is its center of resistance (CR). Morphological data on the dentoalveolar complex can be used to locate this point either three-dimensionally (3D) with the finite element (FE) method, or two-dimensionally (2D) with a mathematical method calculating the centroid of the projected dental root. This study aimed to compare and appraise these two methods with regard to their accuracy and time requirements.

METHODS

Three radiological datasets with permanent teeth were included. Each single 3D dataset was used in each of these patients to derive both a 3D and 2D morphological model of the upper right central incisor. CR levels were evaluated in percent, indicating the relative height as measured from the (averaged levels of the mesial and distal) bony ridge margin to the tooth's apex.

RESULTS

Mean CR levels of 42.8% for distalization and 56.5% for lingual movement were obtained from the 3D FE simulations of initial tooth movement. The 2D mathematical model yielded a mean CR level of 44.5%. Compared to this mathematical approach, the 3D FE simulations were around 15 times more time-consuming, with an interactive requirement of around 15 h.

CONCLUSION

Because they contain so much more morphological information, 3D FE simulations should offer superior predictability. In addition, they are the only method offering detailed CR identification for specific directions of tooth movement. Before this method can be used in clinical practice, however, there is still a major need to reduce time requirements via further automation of process steps and to investigate how it should be applied to different tooth types.

摘要

目的

描述作用于牙齿的力-力矩系统的首选参考点是其阻力中心（CR）。牙槽复合体的形态学数据可用于通过有限元（FE）方法三维（3D）定位该点，或通过计算牙根部投影质心的数学方法二维（2D）定位该点。本研究旨在比较和评估这两种方法在准确性和时间要求方面的差异。

方法

纳入三个包含恒牙的放射学数据集。在这些患者中，每个单一的3D数据集都用于构建右上中切牙的3D和2D形态模型。CR水平以百分比评估，表示从（近中和远中平均水平的）牙槽嵴边缘到牙尖测量的相对高度。

结果

初始牙齿移动的3D FE模拟得出远中移动的平均CR水平为42.8%，舌向移动为56.5%。2D数学模型得出的平均CR水平为44.5%。与这种数学方法相比，3D FE模拟的耗时约为其15倍，交互时间约为15小时。

结论

由于3D FE模拟包含更多的形态学信息，因此应具有更高的可预测性。此外，它们是唯一能为特定牙齿移动方向提供详细CR识别的方法。然而，在该方法可应用于临床实践之前，仍有必要通过进一步自动化处理步骤来减少时间要求，并研究如何将其应用于不同的牙齿类型。

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通过二维和三维放射影像数据确定单个牙齿的阻力中心。

Locating the center of resistance in individual teeth via two- and three-dimensional radiographic data.

作者信息

机构信息

出版信息

OBJECTIVES

METHODS

RESULTS

CONCLUSION

目的

方法

结果

结论

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