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Insertion guidance based on impedance measurements of a Cochlear electrode array

Insertion guidance based on impedance measurements of a Cochlear electrode array
Insertion guidance based on impedance measurements of a Cochlear electrode array

The cochlear implantable neuromodulator provides substantial auditory perception to those with severe or profound impaired hearing. Correct electrode array positioning in the cochlea is one of the important factors for quality hearing, and misplacement may lead to additional injury to the cochlea. Visual inspection of the progress of electrode insertion is limited and mainly relies on the surgeon's tactile skills, and there is a need to detect in real-time the electrode array position in the cochlea during insertion. The available clinical measurement presently provides very limited information. Impedance measurement may be used to assist with the insertion of the electrode array. Using computational modeling of the cochlea, and its local tissue layers merging with the associated neuromodulator electrode array parameters, the impedance variations at different insertion depths and the proximities to the cochlea walls have been analyzed. In this study, an anatomical computational model of the temporal region of a patient is used to derive the relationship between impedance variations and the electrode proximity to the cochlea wall and electrode insertion depth. The aim was to examine whether the use of electrode impedance variations can be an effective marker of electrode proximity and electrode insertion depth. The proposed anatomical model simulates the quasi-static electrode impedance variations at different selected points but at considerable computation cost. A much less computationally intensive geometric model (~1/30) provided comparative impedance measurements with differences of <2%. Both use finite element analysis over the entire cross-section area of the scala tympani. It is shown that the magnitude of the impedance varies with both electrode insertion depth and electrode proximity to the adjacent anatomical layers (e.g., cochlea wall). In particular, there is a 1,400% increase when the electrode array is moved very close to the cochlea wall. This may help the surgeon to find the optimal electrode position within the scala tympani by observation of such impedance characteristics. The misplacement of the electrode array within the scala tympani may be eliminated by using the impedance variation metric during electrode array insertion if the results are validated with an experimental study.

cochlear implant, computational models, electrode proximity, impedance variation, parameterization
Salkim, Enver
2d38e405-c332-4fa8-8f0b-a4e06103a354
Zamani, Majid
431788cc-0702-4fa9-9709-f5777a2d0d25
Jiang, Dai
782f1637-d100-43dd-821f-6e4e156a50db
Saeed, Shakeel R.
53e694dc-465d-4669-b98f-9ddbfb6c7e9c
Demosthenous, Andreas
bed19531-d770-4f48-8464-59d225ddea8d
Salkim, Enver
2d38e405-c332-4fa8-8f0b-a4e06103a354
Zamani, Majid
431788cc-0702-4fa9-9709-f5777a2d0d25
Jiang, Dai
782f1637-d100-43dd-821f-6e4e156a50db
Saeed, Shakeel R.
53e694dc-465d-4669-b98f-9ddbfb6c7e9c
Demosthenous, Andreas
bed19531-d770-4f48-8464-59d225ddea8d

Salkim, Enver, Zamani, Majid, Jiang, Dai, Saeed, Shakeel R. and Demosthenous, Andreas (2022) Insertion guidance based on impedance measurements of a Cochlear electrode array. Frontiers in Computational Neuroscience, 16, [862126]. (doi:10.3389/fncom.2022.862126).

Record type: Article

Abstract

The cochlear implantable neuromodulator provides substantial auditory perception to those with severe or profound impaired hearing. Correct electrode array positioning in the cochlea is one of the important factors for quality hearing, and misplacement may lead to additional injury to the cochlea. Visual inspection of the progress of electrode insertion is limited and mainly relies on the surgeon's tactile skills, and there is a need to detect in real-time the electrode array position in the cochlea during insertion. The available clinical measurement presently provides very limited information. Impedance measurement may be used to assist with the insertion of the electrode array. Using computational modeling of the cochlea, and its local tissue layers merging with the associated neuromodulator electrode array parameters, the impedance variations at different insertion depths and the proximities to the cochlea walls have been analyzed. In this study, an anatomical computational model of the temporal region of a patient is used to derive the relationship between impedance variations and the electrode proximity to the cochlea wall and electrode insertion depth. The aim was to examine whether the use of electrode impedance variations can be an effective marker of electrode proximity and electrode insertion depth. The proposed anatomical model simulates the quasi-static electrode impedance variations at different selected points but at considerable computation cost. A much less computationally intensive geometric model (~1/30) provided comparative impedance measurements with differences of <2%. Both use finite element analysis over the entire cross-section area of the scala tympani. It is shown that the magnitude of the impedance varies with both electrode insertion depth and electrode proximity to the adjacent anatomical layers (e.g., cochlea wall). In particular, there is a 1,400% increase when the electrode array is moved very close to the cochlea wall. This may help the surgeon to find the optimal electrode position within the scala tympani by observation of such impedance characteristics. The misplacement of the electrode array within the scala tympani may be eliminated by using the impedance variation metric during electrode array insertion if the results are validated with an experimental study.

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More information

Accepted/In Press date: 18 May 2022
Published date: 23 June 2022
Additional Information: Publisher Copyright: Copyright © 2022 Salkim, Zamani, Jiang, Saeed and Demosthenous.
Keywords: cochlear implant, computational models, electrode proximity, impedance variation, parameterization

Identifiers

Local EPrints ID: 489172
URI: http://eprints.soton.ac.uk/id/eprint/489172
DOI: doi:10.3389/fncom.2022.862126
PURE UUID: f1495128-4aca-4a68-835d-92791be59b29
ORCID for Majid Zamani: ORCID iD orcid.org/0009-0007-0844-473X

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Date deposited: 16 Apr 2024 16:37
Last modified: 18 Apr 2024 02:09

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Contributors

Author: Enver Salkim
Author: Majid Zamani ORCID iD
Author: Dai Jiang
Author: Shakeel R. Saeed
Author: Andreas Demosthenous

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