用于耳蜗管长度估计、格林伍德频率映射和人工耳蜗电极阵列长度模拟的研究软件。

Research software in cochlear duct length estimation, Greenwood frequency mapping and CI electrode array length simulation.

作者信息

Dhanasingh Anandhan

机构信息

MED-EL GmbH, Fūrstenweg 77a, 6020, Innsbruck, Austria.

出版信息

World J Otorhinolaryngol Head Neck Surg. 2020 Jun 5;7(1):17-22. doi: 10.1016/j.wjorl.2018.12.002. eCollection 2021 Jan.

DOI:10.1016/j.wjorl.2018.12.002

PMID:33474539

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7801236/

Abstract

BACKGROUND AND OBJECTIVE

The size of the cochlea varies a lot among the human population bringing the necessity for electrode arrays to be available in various lengths irrespective of the cochlear implant (CI) brand. This research software helps in the estimation of the patient's cochlear duct length (CDL) which is then used for the simulation of the correct length electrode array matching the patient's cochlear size and as well in getting the patient specific cochlear frequency map.

METHODS

Visual Studio Express 2012 for Windows Desktop is used in the architecture of this research software. The basal turn diameter of the cochlea ("A" value) needs to be measured from the pre-operative computed tomography (CT) image of the patient's temporal bone. This "A" will be taken as the input for the CDL equations proposed by Alexiades et al for estimating the CDL along the basilar membrane for various insertion depths. Greenwood's equation is then used in combination with the CDL for the full length of the cochlea in getting the patient specific frequency map.

RESULTS

The research software with the help of the "A" value as input, with few button clicks, gives the patient specific CDL for various insertion depths and the Greenwood's frequency map. The users have the choice to select any electrode array of their choice and place it under the frequency map to see how good it fits to that particular patient's cochlea. Also, given the possibility to drag and move the electrode array picture to mimic the post-operative actual electrode insertion depth.

CONCLUSIONS

This research software simplifies the overall process of CDL estimation and in getting the patient specific cochlear frequency map. The clinicians get the chance to simulate placing the various electrode array lengths in patient cochlea in identifying the best fit electrode. This could help in pushing the CI field into the concept of individualized CI electrode array solution that ultimately benefits the patients.

摘要

背景与目的

人群中耳蜗大小差异很大，这就需要不论耳蜗植入（CI）品牌如何，都有不同长度的电极阵列可供使用。本研究软件有助于估算患者的耳蜗管长度（CDL），该长度随后用于模拟与患者耳蜗大小匹配的正确长度电极阵列，以及获取患者特定的耳蜗频率图。

方法

本研究软件的架构采用适用于Windows桌面的Visual Studio Express 2012。需要从患者颞骨的术前计算机断层扫描（CT）图像中测量耳蜗的基底转直径（“A”值）。这个“A”值将作为Alexiades等人提出的CDL方程的输入，用于估算不同插入深度下沿基底膜的CDL。然后将格林伍德方程与耳蜗全长的CDL结合使用，以获取患者特定的频率图。

结果

该研究软件以“A”值作为输入，只需点击几下按钮，就能给出不同插入深度下患者特定的CDL以及格林伍德频率图。用户可以选择任何他们喜欢的电极阵列，并将其放置在频率图下方，以查看其与该特定患者耳蜗的匹配程度。此外，还可以拖动和移动电极阵列图片，以模拟术后实际电极插入深度。

结论

本研究软件简化了CDL估算的整体过程，并获取患者特定的耳蜗频率图。临床医生有机会在患者耳蜗中模拟放置不同长度的电极阵列，以确定最合适的电极。这有助于将CI领域推向个性化CI电极阵列解决方案的概念，最终使患者受益。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/78c0/7801236/09d60d15d50f/gr1.jpg

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用于耳蜗管长度估计、格林伍德频率映射和人工耳蜗电极阵列长度模拟的研究软件。

Research software in cochlear duct length estimation, Greenwood frequency mapping and CI electrode array length simulation.

作者信息

机构信息

出版信息

BACKGROUND AND OBJECTIVE

METHODS

RESULTS

CONCLUSIONS

背景与目的

方法

结果

结论

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