Otosclerosis under microCT: New insights into the disease and its anatomy.

Gabriela O'Toole Bom Braga, Robert Zboray, Annapaola Parrilli, Milica Bulatović, Marco Domenico Caversaccio, Franca Wagner
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引用次数: 1

Abstract

Purpose: Otospongiotic plaques can be seen on conventional computed tomography (CT) as focal lesions around the cochlea. However, the resolution remains insufficient to enable evaluation of intracochlear damage. MicroCT technology provides resolution at the single micron level, offering an exceptional amplified view of the otosclerotic cochlea. In this study, a non-decalcified otosclerotic cochlea was analyzed and reconstructed in three dimensions for the first time, using microCT technology. The pre-clinical relevance of this study is the demonstration of extensive pro-inflammatory buildup inside the cochlea which cannot be seen with conventional cone-beam CT (CBCT) investigation.

Materials and methods: A radiological and a three-dimensional (3D) anatomical study of an otosclerotic cochlea using microCT technology is presented here for the first time. 3D-segmentation of the human cochlea was performed, providing an unprecedented view of the diseased area without the need for decalcification, sectioning, or staining.

Results: Using microCT at single micron resolution and geometric reconstructions, it was possible to visualize the disease's effects. These included intensive tissue remodeling and highly vascularized areas with dilated capillaries around the spongiotic foci seen on the pericochlear bone. The cochlea's architecture as a morphological correlate of the otosclerosis was also seen. With a sagittal cut of the 3D mesh, it was possible to visualize intense ossification of the cochlear apex, as well as the internal auditory canal, the modiolus, the spiral ligament, and a large cochleolith over the osseous spiral lamina. In addition, the oval and round windows showed intense fibrotic tissue formation and spongiotic bone with increased vascularization. Given the recently described importance of the osseous spiral lamina in hearing mechanics and that, clinically, one of the signs of otosclerosis is the Carhart notch observed on the audiogram, a tonotopic map using the osseous spiral lamina as region of interest is presented. An additional quantitative study of the porosity and width of the osseous spiral lamina is reported.

Conclusion: In this study, structural anatomical alterations of the otosclerotic cochlea were visualized in 3D for the first time. MicroCT suggested that even though the disease may not appear to be advanced in standard clinical CT scans, intense tissue remodeling is already ongoing inside the cochlea. That knowledge will have a great impact on further treatment of patients presenting with sensorineural hearing loss.

Abstract Image

Abstract Image

Abstract Image

微ct下耳硬化:对该疾病及其解剖学的新认识。
目的:耳海绵状斑块可在常规计算机断层扫描(CT)上被视为耳蜗周围的局灶性病变。然而,分辨率仍然不足以评估耳蜗内损伤。MicroCT技术提供单微米级别的分辨率,提供耳硬化耳蜗的特殊放大视图。本研究首次利用微ct技术对非脱钙耳硬化耳蜗进行三维分析和重建。这项研究的临床前相关性是证明了耳蜗内广泛的促炎积聚,这是传统的锥束CT (CBCT)检查所不能看到的。材料和方法:本文首次使用微ct技术对耳硬化耳蜗进行放射学和三维(3D)解剖研究。进行了人耳蜗的3d分割,提供了前所未有的病变区域视图,而无需脱钙,切片或染色。结果:利用微ct在单微米分辨率和几何重建,可以可视化疾病的影响。这些包括密集的组织重塑和高度血管化的区域,耳膜周围的海绵状病灶周围毛细血管扩张。耳蜗结构作为耳硬化的形态学相关也被观察到。通过三维网格的矢状切面,可以看到耳蜗尖、内耳道、小梁、螺旋韧带和骨螺旋板上的大耳蜗石的强烈骨化。此外,椭圆形和圆形窗口显示强烈的纤维化组织形成和海绵状骨,血管化增加。鉴于最近描述的骨螺旋板在听力力学中的重要性,并且在临床上,耳硬化的迹象之一是在听力图上观察到Carhart切迹,因此提出了使用骨螺旋板作为感兴趣区域的张力分布图。一个额外的定量研究的孔隙率和宽度的骨螺旋板报道。结论:本研究首次实现了耳硬化耳蜗结构解剖改变的三维可视化。MicroCT显示,尽管这种疾病在标准的临床CT扫描中可能没有进展,但耳蜗内部已经在进行强烈的组织重塑。这些知识将对感音神经性听力损失患者的进一步治疗产生重大影响。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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