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一种用于微型种植体支持的上颌骨扩弓数字化规划的新方法。

A New Methodology for the Digital Planning of Micro-Implant-Supported Maxillary Skeletal Expansion.

作者信息

Cantarella Daniele, Savio Gianpaolo, Grigolato Luca, Zanata Paolo, Berveglieri Chiara, Lo Giudice Antonino, Isola Gaetano, Del Fabbro Massimo, Moon Won

机构信息

Department of Biomedical, Surgical and Dental Sciences, University of Milan, Milan, Italy.

Department of Civil, Environmental and Architectural Engineering ICEA, University of Padova, Padova, Italy.

出版信息

Med Devices (Auckl). 2020 Mar 18;13:93-106. doi: 10.2147/MDER.S247751. eCollection 2020.

DOI:10.2147/MDER.S247751

PMID:32256130

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7090180/

Abstract

INTRODUCTION

Miniscrew-assisted rapid palatal expansion (MARPE) appliances utilize the skeletal anchorage to expand the maxilla. One type of MARPE device is the Maxillary Skeletal Expander (MSE), which presents four micro-implants with bicortical engagement of the palatal vault and nasal floor. MSE positioning is traditionally planned using dental stone models and 2D headfilms. This approach presents some critical issues, such as the inability to identify the MSE position relative to skeletal structures, and the potential risk of damaging anatomical structures.

METHODS

A novel methodology has been developed to plan MSE position using the digital model of dental arches and cone-beam computed tomography (CBCT). A virtual model of MSE appliance with the four micro-implants was created. After virtual planning, a positioning guide is virtually designed, 3D printed, and utilized to model and weld the MSE supporting arms to the molar bands. The expansion device is then cemented in the patient oral cavity and micro-implants inserted. A clinical case of a 12.9-year-old female patient presenting a Class III malocclusion with transverse and sagittal maxillary deficiency is reported.

RESULTS

The midpalatal suture was opened with a split of 3.06 mm and 2.8 mm at the anterior and posterior nasal spine, respectively. After facemask therapy, the sagittal skeletal relationship was improved, as shown by the increase in ANB, A-Na perpendicular and Wits cephalometric parameters, and the mandibular plane rotated 1.6° clockwise.

CONCLUSION

The proposed digital methodology represents an advancement in the planning of MSE positioning, compared to the traditional approach. By evaluating the bone morphology of the palate and midface on patient CBCT, the placement of MSE is improved regarding the biomechanics of maxillary expansion and the bone thickness at micro-implants insertion sites. In the present case report, the digital planning was associated with a positive outcome of maxillary expansion and protraction in safety conditions.

摘要

引言

微型螺钉辅助快速腭中缝扩展（MARPE）矫治器利用骨锚固来扩展上颌骨。一种MARPE装置是上颌骨骨骼扩展器（MSE），它有四个微型种植体，与腭穹窿和鼻底进行双皮质锚固。传统上，MSE的定位是使用石膏模型和二维头颅侧位片进行规划的。这种方法存在一些关键问题，例如无法确定MSE相对于骨骼结构的位置，以及损伤解剖结构的潜在风险。

方法

已经开发出一种新的方法，使用牙弓数字模型和锥形束计算机断层扫描（CBCT）来规划MSE的位置。创建了带有四个微型种植体的MSE矫治器虚拟模型。虚拟规划后，虚拟设计、3D打印一个定位导板，并用于对MSE支撑臂进行建模和焊接到磨牙带环上。然后将扩展装置粘结在患者口腔中并插入微型种植体。报告了一例12.9岁女性患者的临床病例，该患者表现为III类错牙合畸形，伴有上颌横向和矢状向发育不足。

结果

腭中缝打开，前鼻棘处分开3.06mm，后鼻棘处分开2.8mm。面罩治疗后，矢状骨关系得到改善，ANB、A-Na垂线和Wits头影测量参数增加表明了这一点，下颌平面顺时针旋转1.6°。

结论

与传统方法相比，所提出的数字方法在MSE定位规划方面是一种进步。通过评估患者CBCT上腭部和中面部的骨形态，在MSE的放置方面，上颌扩展的生物力学以及微型种植体植入部位的骨厚度都得到了改善。在本病例报告中，数字规划在安全条件下与上颌扩展和前牵引的积极结果相关。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/9c4f/7090180/ce5fc429c269/MDER-13-93-g0001.jpg

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Suppr超能文献

一种用于微型种植体支持的上颌骨扩弓数字化规划的新方法。

A New Methodology for the Digital Planning of Micro-Implant-Supported Maxillary Skeletal Expansion.

作者信息

机构信息

出版信息

INTRODUCTION

METHODS

RESULTS

CONCLUSION

引言

方法

结果

结论

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