基于三维同步辐射相衬成像的个体化耳蜗频率映射方法。

An Approach for Individualized Cochlear Frequency Mapping Determined From 3D Synchrotron Radiation Phase-Contrast Imaging.

出版信息

IEEE Trans Biomed Eng. 2021 Dec;68(12):3602-3611. doi: 10.1109/TBME.2021.3080116. Epub 2021 Nov 19.

DOI:10.1109/TBME.2021.3080116

Abstract

OBJECTIVE

Cochlear implants are traditionally programmed to stimulate according to a generalized frequency map, where individual anatomic variability is not considered when selecting the centre frequency of stimulation of each implant electrode. However, high variability in cochlear size and spatial frequency distributions exist among individuals. Generalized cochlear implant frequency maps can result in large pitch perception errors and reduced hearing outcomes for cochlear implant recipients. The objective of this work was to develop an individualized frequency mapping technique for the human cochlea to allow for patient-specific cochlear implant stimulation.

METHODS

Ten cadaveric human cochleae were scanned using synchrotron radiation phase-contrast imaging (SR-PCI) combined with computed tomography (CT). For each cochlea, ground truth angle-frequency measurements were obtained in three-dimensions using the SR-PCI CT data. Using an approach designed to minimize perceptual error in frequency estimation, an individualized frequency function was determined to relate angular depth to frequency within the cochlea.

RESULTS

The individualized frequency mapping function significantly reduced pitch errors in comparison to the current gold standard generalized approach.

CONCLUSION AND SIGNIFICANCE

This paper presents for the first time a cochlear frequency map which can be individualized using only the angular length of cochleae. This approach can be applied in the clinical setting and has the potential to revolutionize cochlear implant programming for patients worldwide.

摘要

目的

传统的人工耳蜗植入是根据广义频率图进行编程的，在选择每个植入电极的刺激中心频率时，不考虑个体解剖结构的差异。然而，个体之间的耳蜗大小和空间频率分布存在很大的差异。广义的人工耳蜗频率图可能导致较大的音调感知误差，并降低人工耳蜗植入者的听力效果。本研究的目的是开发一种针对人类耳蜗的个体化频率映射技术，以实现患者特异性的人工耳蜗刺激。

方法

使用同步辐射相衬成像（SR-PCI）结合计算机断层扫描（CT）对 10 个尸体人类耳蜗进行扫描。对于每个耳蜗，使用 SR-PCI-CT 数据在三维空间中获得角度-频率的真实测量值。使用旨在最小化频率估计感知误差的方法，确定了一种个体化的频率函数，以在耳蜗内将角度深度与频率相关联。

结果

与当前的金标准广义方法相比，个体化频率映射函数显著降低了音调误差。

结论和意义

本文首次提出了一种可以仅使用耳蜗的角度长度进行个体化的耳蜗频率图。这种方法可以在临床环境中应用，有可能彻底改变全球人工耳蜗植入患者的编程方式。

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基于三维同步辐射相衬成像的个体化耳蜗频率映射方法。

An Approach for Individualized Cochlear Frequency Mapping Determined From 3D Synchrotron Radiation Phase-Contrast Imaging.

出版信息

OBJECTIVE

METHODS

RESULTS

CONCLUSION AND SIGNIFICANCE

目的

方法

结果

结论和意义

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