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本文引用的文献

1
The importance of electrode location in cochlear implantation.电极位置在人工耳蜗植入中的重要性。
Laryngoscope Investig Otolaryngol. 2016 Nov 29;1(6):169-174. doi: 10.1002/lio2.42. eCollection 2016 Dec.
2
Force Perception Thresholds in Cochlear Implantation Surgery.人工耳蜗植入手术中的力感知阈值
Audiol Neurootol. 2016;21(4):244-249. doi: 10.1159/000445736. Epub 2016 Aug 30.
3
Detection of modiolar proximity through bipolar impedance measurements.通过双极阻抗测量检测蜗轴接近度。
Laryngoscope. 2017 Jun;127(6):1413-1419. doi: 10.1002/lary.26183. Epub 2016 Aug 24.
4
Electrode Location and Angular Insertion Depth Are Predictors of Audiologic Outcomes in Cochlear Implantation.电极位置和角度插入深度是人工耳蜗植入听力结果的预测因素。
Otol Neurotol. 2016 Sep;37(8):1016-23. doi: 10.1097/MAO.0000000000001125.
5
Assessing the Electrode-Neuron Interface with the Electrically Evoked Compound Action Potential, Electrode Position, and Behavioral Thresholds.通过电诱发复合动作电位、电极位置和行为阈值评估电极-神经元界面
J Assoc Res Otolaryngol. 2016 Jun;17(3):237-52. doi: 10.1007/s10162-016-0557-9. Epub 2016 Feb 29.
6
A semi-supervised Support Vector Machine model for predicting the language outcomes following cochlear implantation based on pre-implant brain fMRI imaging.一种基于植入前脑功能磁共振成像预测人工耳蜗植入后语言结果的半监督支持向量机模型。
Brain Behav. 2015 Oct 12;5(12):e00391. doi: 10.1002/brb3.391. eCollection 2015 Dec.
7
Relationship Between Electrode-to-Modiolus Distance and Current Levels for Adults With Cochlear Implants.成人人工耳蜗植入者电极与蜗轴距离和电流水平之间的关系
Otol Neurotol. 2016 Jan;37(1):31-7. doi: 10.1097/MAO.0000000000000896.
8
Round window electrocochleography before and after cochlear implant electrode insertion.人工耳蜗植入电极插入前后的圆窗电耳蜗图
Laryngoscope. 2016 May;126(5):1193-200. doi: 10.1002/lary.25602. Epub 2015 Sep 11.
9
Intraoperative Electrophysiologic Variations Caused by the Scalar Position of Cochlear Implant Electrodes.人工耳蜗电极的标量位置引起的术中电生理变化。
Otol Neurotol. 2015 Jul;36(6):1010-4. doi: 10.1097/MAO.0000000000000736.
10
Clinical evaluation of an image-guided cochlear implant programming strategy.一种图像引导的人工耳蜗编程策略的临床评估
Audiol Neurootol. 2014;19(6):400-11. doi: 10.1159/000365273. Epub 2014 Nov 7.

在体耳蜗植入过程中的阻抗测量预测了阵列的定位。

Impedance Measures During in vitro Cochlear Implantation Predict Array Positioning.

出版信息

IEEE Trans Biomed Eng. 2018 Feb;65(2):327-335. doi: 10.1109/TBME.2017.2764881.

DOI:10.1109/TBME.2017.2764881
PMID:29346102
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5929978/
Abstract

OBJECTIVE

Improper electrode placement during cochlear implant (CI) insertion can adversely affect speech perception outcomes. However, the intraoperative methods to determine positioning are limited. Because measures of electrode impedance can be made quickly, the goal of this study was to assess the relationship between CI impedance and proximity to adjacent structures.

METHODS

An Advanced Bionics CI array was inserted into a clear, plastic cochlea one electrode contact at a time in a saline bath (nine trials). At each insertion depth, response to biphasic current pulses was used to calculate access resistance (Ra), polarization resistance (Rp), and polarization capacitance (Cp). These measures were correlated to actual proximity as assessed by microscopy using linear regression models.

RESULTS

Impedance increased with insertion depth and proximity to the inner wall. Specifically, Ra increased, Cp decreased, and Rp slightly increased. Incorporating all impedance measures afforded a prediction model (r = 0.88) while optimizing for sub-mm positioning afforded a model with 78.3% specificity.

CONCLUSION

Impedance in vitro greatly changes with electrode insertion depth and proximity to adjacent structures in a predicable manner.

SIGNIFICANCE

Assessing proximity of the CI to adjacent structures is a significant first step in qualifying the electrode-neural interface. This information should aid in CI fitting, which should help maximize hearing and speech outcomes with a CI. Additionally, knowledge of the relationship between impedance and positioning could have utility in other tissue implants in the brain, retina, or spinal cord.

摘要

目的

在进行人工耳蜗植入 (CI) 手术时,如果电极放置不当,可能会对言语感知结果产生不利影响。然而,目前术中确定电极位置的方法有限。由于可以快速测量电极阻抗,因此本研究的目的是评估 CI 阻抗与邻近结构之间的关系。

方法

将 Advanced Bionics CI 阵列逐个电极触点插入到一个装有盐水的透明塑料耳蜗中(共进行了九次试验)。在每个插入深度,使用双相电流脉冲响应来计算接入电阻 (Ra)、极化电阻 (Rp) 和极化电容 (Cp)。使用显微镜评估实际接近程度,并通过线性回归模型将这些测量值与实际接近程度相关联。

结果

阻抗随插入深度和与内壁的接近程度而增加。具体来说,Ra 增加,Cp 减小,Rp 略有增加。综合所有阻抗测量值可以得到一个预测模型(r = 0.88),而优化亚毫米级定位则可以得到一个具有 78.3%特异性的模型。

结论

体外阻抗随电极插入深度和与邻近结构的接近程度呈可预测的方式发生很大变化。

意义

评估 CI 与邻近结构的接近程度是确定电极-神经界面的重要第一步。这些信息有助于 CI 适配,这有助于最大限度地提高 CI 的听力和言语效果。此外,阻抗与定位之间的关系知识可能对大脑、视网膜或脊髓中的其他组织植入物具有实用价值。