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以3D形式呈现的人类内耳畸形类型

Human Inner-ear Malformation Types Captured in 3D.

作者信息

Dhanasingh Anandhan, Dietz Aarno, Jolly Claude, Roland Peter

机构信息

MED-EL GmbH, Implants, Innsbruck, Austria.

Department of Otolaryngology, Kuopio University Hospital, Kuopio, Finland.

出版信息

J Int Adv Otol. 2019 Apr;15(1):77-82. doi: 10.5152/iao.2019.6246.

DOI:10.5152/iao.2019.6246
PMID:31058598
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6483443/
Abstract

OBJECTIVES

Capture the human inner-ear malformation types in 3D by segmenting the inner-ear structures from clinical CT (computed tomography) and MR (magnetic resonance) image datasets. Volumetric analysis was done to find the variations in the volume of cochlear part alone from complete inner-ear followed by 3D printing from the 3D segmented models.

MATERIALS AND METHODS

Using 3D slicer freeware, the complete inner-ear structures were segmented from anonymized CT and MR image by setting a tight grey-scale threshold to avoid capturing unwanted structures followed by volumetric analysis of the cochlear part alone. 3D printing was done using Form labs desktop 3D printer.

RESULTS

We identified 2x normal anatomy (NA) cochlea, 1x enlarged vestibular aqueduct syndrome (EVAS), 3x incomplete partition (IP) type-I, 4x IP type-II, 3x IP type-III, 5x common cavity (CC) and 5x cochlear hypoplasia (CH). 3D segmented models along with the 3D printed models showed huge variation in size, shape and the anatomy among the image data-sets analyzed. Volumetric analysis showed that on average, volume of CC was above 150mm3, volume of CH fell below 80mm3, Volume of NA, EVAS and IP-I were all around 85-105mm3 whereas the volume of IP-II was around 50mm3.

CONCLUSION

Visualizing human inner-ear malformation types in 3D both as computer models and as 3D printed models is a whole-new experience as demonstrated in this study. The volumetric analysis showed a huge variation among the volume of cochlear part alone among the malformation types.

摘要

目的

通过从临床CT(计算机断层扫描)和MR(磁共振)图像数据集中分割内耳结构,以三维方式捕捉人类内耳畸形类型。进行体积分析,以找出仅耳蜗部分相对于完整内耳的体积变化,然后从三维分割模型进行3D打印。

材料与方法

使用3D Slicer免费软件,通过设置严格的灰度阈值,从匿名的CT和MR图像中分割出完整的内耳结构,以避免捕捉不需要的结构,随后仅对耳蜗部分进行体积分析。使用Formlabs桌面3D打印机进行3D打印。

结果

我们识别出2例正常解剖(NA)耳蜗、1例大前庭导水管综合征(EVAS)、3例不完全分隔(IP)I型、4例IP II型、3例IP III型、5例共同腔(CC)和5例耳蜗发育不全(CH)。三维分割模型以及3D打印模型在分析的图像数据集中显示出大小、形状和解剖结构的巨大差异。体积分析表明,平均而言,CC的体积超过150mm³,CH的体积低于80mm³,NA、EVAS和IP-I的体积均在85 - 105mm³左右,而IP-II的体积约为50mm³。

结论

如本研究所示,将人类内耳畸形类型以计算机模型和3D打印模型的形式进行三维可视化是一种全新的体验。体积分析表明,在畸形类型中,仅耳蜗部分的体积就存在巨大差异。

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