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微骨穿孔增强正畸移动的力学分析:有限元法。

Micro-osteoperforation for enhancement of orthodontic movement: A mechanical analysis using the finite element method.

机构信息

Graduate Program in Dentistry, Universidade Luterana do Brasil (ULBRA), Canoas, RS, Brazil.

School of Dentistry, Universidade Luterana do Brasil (ULBRA), Canoas, RS, Brazil.

出版信息

PLoS One. 2024 Aug 19;19(8):e0308739. doi: 10.1371/journal.pone.0308739. eCollection 2024.

DOI:10.1371/journal.pone.0308739
PMID:39159186
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11332926/
Abstract

BACKGROUND

Micro-osteoperforation is a minimally invasive technique aimed at accelerating tooth movement. The goal of this novel experimental study was to assess tooth movement and stress distribution produced by the force of orthodontic movement on the tooth structure, periodontal ligament, and maxillary bone structure, with and without micro-osteoperforation, using the finite element method.

MATERIALS AND METHODS

Cone-beam computed tomography was used to obtain a virtual model of the maxilla and simulate the extraction of right and left first premolars. Three micro-osteoperforations (1.5 x 5 mm) were made in the hemiarch on the distal and mesial surfaces of upper canines, according to the power tip geometry of the Propel device (Propel Orthodontics, Ossining, New York, USA). An isotropic model of the maxilla was fabricated according to the finite element method by insertion of mechanical properties of the tooth structures, with orthodontic force (1.5 N) simulation in the distal movement on the upper canine of a hemiarch.

RESULTS

Initial movement was larger when micro-osteoperforations were performed on the dental crown (24%) and on the periodontal ligament (29%). In addition, stress distribution was higher on the bone structure (31%) when micro-osteoperforations were used.

CONCLUSIONS

Micro-osteoperforations considerably increased the movement of both the dental crown and periodontal ligament, which highlights their importance in the improvement of orthodontic movement, as well as in stress distribution across the bone structure. Important stress absorption regions were identified within micro-osteoperforations.

摘要

背景

微骨穿孔是一种微创技术,旨在加速牙齿移动。本新型实验研究的目的是使用有限元法评估正畸力对牙齿结构、牙周韧带和上颌骨结构产生的牙齿移动和应力分布,有无微骨穿孔。

材料和方法

使用锥形束计算机断层扫描(CBCT)获得上颌虚拟模型,并模拟右上和左上第一前磨牙的拔除。根据 Propel 装置(Propel Orthodontics,Ossining,NY,USA)的功率尖端几何形状,在上颌尖牙的远中面和近中面的半弓上制作三个微骨穿孔(1.5 x 5mm)。根据有限元法制作上颌各向同性模型,插入牙齿结构的机械性能,在半弓上的上颌尖牙远中移动模拟正畸力(1.5N)。

结果

当在牙冠(24%)和牙周韧带(29%)上进行微骨穿孔时,初始移动较大。此外,当使用微骨穿孔时,骨结构上的应力分布更高(31%)。

结论

微骨穿孔显著增加了牙冠和牙周韧带的移动,这突出了它们在改善正畸运动以及在骨结构中的应力分布方面的重要性。在微骨穿孔内确定了重要的应力吸收区域。

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本文引用的文献

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