大腭动脉位置与生理学的三维图谱。

Three-dimensional mapping of the greater palatine artery location and physiology.

机构信息

Materials Science and Engineering Program, University of California San Diego, La Jolla, California, United States.

StyloSonic LLC, Lake Forest, California, United States.

出版信息

Dentomaxillofac Radiol. 2023 Nov;52(8):20230066. doi: 10.1259/dmfr.20230066. Epub 2023 Oct 24.

DOI:10.1259/dmfr.20230066

PMID:37641889

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10968761/

Abstract

OBJECTIVE

To develop a novel technique for localizing and reconstructing the greater palatine artery (GPA) using three-dimensional (3D) technology.

METHODS

A miniaturized intraoral ultrasound transducer was used to imaging landmarks including the GPA, gingival margin (GM), and palatal masticatory mucosa (PMM). A 5-mm-thick solid hydrogel couplant was integrated to replace traditional ultrasound gel and avoid bubbles when moving the transducer.

RESULTS

A panorama image provided the relative localization of landmarks including the GPA, PMM, and hard palate. Short- and long-axis imaging of GPA was performed in five subjects including 3D mapping of GPA branches and surrounding tissues in a volume of 10 mm × 8 mm × 10 mm. Full-mouth Doppler imaging was also demonstrated on both the dorsal and ventral tongue as well as buccal mucosa and sublingual region on two subjects.

CONCLUSIONS

This study can measure the vertical distance from the GM to the GPA and depth from PMM to GPA and visualize the GPA localization in a 3D manner, which is critical to evaluate the available volume of palatal donor tissues and avoid sectioning of GPA during surgical harvesting of the tissues. Finally, the transducer's small size facilitates full-mouth Doppler imaging with the potential to improve the assessment, diagnosis, and management of oral mucosa.

摘要

目的

开发一种使用三维（3D）技术定位和重建腭大动脉（GPA）的新方法。

方法

使用微型口腔内超声换能器对包括 GPA、牙龈缘（GM）和腭咀嚼黏膜（PMM）在内的解剖标志进行成像。整合了 5 毫米厚的固体水凝胶耦联体以替代传统的超声凝胶，并在移动换能器时避免气泡。

结果

全景图像提供了包括 GPA、PMM 和硬腭在内的解剖标志的相对定位。在五名受试者中进行了 GPA 的短轴和长轴成像，包括在 10 mm×8 mm×10 mm 的体积中对 GPA 分支和周围组织进行 3D 映射。在两名受试者中，还对舌背和舌腹、颊黏膜和舌下区域进行了全口多普勒成像。

结论

本研究可以测量 GM 到 GPA 的垂直距离以及 PMM 到 GPA 的深度，并以 3D 方式可视化 GPA 的定位，这对于评估腭部供体组织的可用体积以及在组织采集过程中避免 GPA 切断至关重要。最后，换能器的小尺寸便于进行全口多普勒成像，有可能改善口腔黏膜的评估、诊断和管理。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/a28e/10968761/5e35a673d1e3/dmfr.20230066.g001.jpg

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大腭动脉位置与生理学的三维图谱。

Three-dimensional mapping of the greater palatine artery location and physiology.

机构信息

出版信息

OBJECTIVE

METHODS

RESULTS

CONCLUSIONS

目的

方法

结果

结论

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