固定功能矫治器对颅面结构的生物力学影响。

Biomechanical effects of fixed functional appliance on craniofacial structures.

作者信息

Panigrahi Priyankar, Vineeth Varadarajan

机构信息

Department of General and Specialist Dental Practice, College of Dentistry, University of Sharjah, United Arab Emirates.

出版信息

Angle Orthod. 2009 Jul;79(4):668-75. doi: 10.2319/052708-281.1.

DOI:10.2319/052708-281.1

PMID:19537856

Abstract

OBJECTIVE

To evaluate displacement and stress distribution on craniofacial structures associated with fixed functional therapy.

MATERIALS AND METHODS

A finite element model of the human skull was constructed from sequential computed tomography images at 2-mm intervals using a dry adult human skull. In this study, linear, four-nodal, tetramesh and triangular shell elements were used with six degrees of freedom at each of their unstrained nodes: three translations (x, y, and z) and three rotations (around the x-, y-, and z-axes).

RESULTS

The entire mandible moved anteroinferiorly. Maximum displacement was observed in the parasymphyseal and midsymphyseal regions. The pterygoid plate was displaced in a posterosuperior direction. The anteroinferior displacement of the mandibular dentition was most pronounced in the incisor region, while the maxillary dentition was displaced posterosuperiorly. The entire dentition experienced tensile stress except for the maxillary posterior teeth. Tensile stress was also demonstrated at point A, the pterygoid plates, and the mandible, and minimal compressive stress was demonstrated at anterior nasal spine. Maximum tensile stress and von Mises stresses occurred in the condylar neck and head.

CONCLUSION

Fixed functional therapy causes a posterosuperior displacement of the maxillary dentition and pterygoid plate and thus can contribute to the correction of Class II malocclusion. The displacement was more pronounced in the dentoalveolar region as compared to the skeletal displacement. All dentoalveolar structures experienced tensile stress, except for anterior nasal spine and the maxillary posterior teeth.

摘要

目的

评估与固定功能矫治相关的颅面部结构的位移和应力分布。

材料与方法

使用一具干燥的成人人类颅骨，以2毫米间隔的连续计算机断层扫描图像构建人类颅骨的有限元模型。在本研究中，使用线性、四节点、四面体网格和三角形壳单元，其每个未变形节点具有六个自由度：三个平移（x、y和z）和三个旋转（绕x、y和z轴）。

结果

整个下颌骨向前下方移动。在双侧下颌中切牙区和下颌中切牙区观察到最大位移。翼突板向后上方移位。下颌牙列的向前下位移在切牙区最为明显，而上颌牙列向后上方移位。除上颌后牙外，整个牙列均承受拉应力。在A点、翼突板和下颌骨处也显示有拉应力，在前鼻棘处显示有最小压应力。最大拉应力和冯·米塞斯应力出现在髁突颈部和头部。

结论

固定功能矫治导致上颌牙列和翼突板向后上方移位，因此有助于矫治安氏II类错牙合。与骨骼位移相比，牙牙槽骨区域的位移更为明显。除前鼻棘和上颌后牙外，所有牙牙槽骨结构均承受拉应力。

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固定功能矫治器对颅面结构的生物力学影响。

Biomechanical effects of fixed functional appliance on craniofacial structures.

作者信息

机构信息

出版信息

OBJECTIVE

MATERIALS AND METHODS

RESULTS

CONCLUSION

目的

材料与方法

结果

结论

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