A phenomenological computational model of the evoked action potential fitted to human cochlear implant responses

Ramos‐de‐Miguel, Ángel; Escobar, J. M.; Greiner, David; Benítez, Domingo; Rodríguez, Eduardo; Oliver, Albert; Hernández, Marcos; Ramos‐Macías, Ángel

doi:10.1371/journal.pcbi.1010134

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PLoS Comput Biol

2022

DOI: 10.1371/journal.pcbi.1010134

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A phenomenological computational model of the evoked action potential fitted to human cochlear implant responses

Ángel Ramos‐de‐Miguel

J. M. Escobar²,

David Greiner³

et al.

Abstract: There is a growing interest in biomedical engineering in developing procedures that provide accurate simulations of the neural response to electrical stimulus produced by implants. Moreover, recent research focuses on models that take into account individual patient characteristics. We present a phenomenological computational model that is customized with the patient’s data provided by the electrically evoked compound action potential (ECAP) for simulating the neural response to electrical stimulus produced by… Show more

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2024

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A full-head model to investigate intra and extracochlear electric fields in cochlear implant stimulation

Callejón-Leblic,

Lazo-Maestre,

Fratter

et al. 2024

Phys. Med. Biol.

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Objective: Despite the widespread use and technical improvement of cochlear implant (CI) devices over past decades, further research into the bioelectric bases of CI stimulation is still needed. Various stimulation modes implemented by different CI manufacturers coexist, but their true clinical benefit remains unclear, probably due to the high inter-subject variability reported, which makes the prediction of CI outcomes and the optimal fitting of stimulation parameters challenging. A highly detailed full head model that includes a cochlea and an electrode array is developed in this study to emulate intracochlear voltages and extracochlear current pathways through the head in CI stimulation. Approach: Simulations based on the finite element method were conducted under monopolar, bipolar, tripolar, and partial tripolar modes, as well as for apical, medial, and basal electrodes. Variables simulated included: intracochlear voltages, electric field (EF) decay, electric potentials at the scalp and extracochlear currents through the head. To better understand CI side effects such as facial nerve stimulation, caused by spurious current leakage out from the cochlea, special emphasis is given to the analysis of the EF over the facial nerve. Main results: The model reasonably predicts EF magnitudes and trends previously reported in CI users. New relevant extracochlear current pathways through the head and brain tissues have been identified. Simulated results also show differences in the magnitude and distribution of the EF through different segments of the facial nerve upon different stimulation modes and electrodes, dependent on nerve and bone tissue conductivities. Significance: Full head models prove useful tools to model intra and extracochlear EFs in CI stimulation. Our findings could prove useful in the design of future experimental studies to contrast FNS mechanisms upon stimulation of different electrodes and CI modes. The full-head model developed is freely available for the CI community for further research and use.

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A full-head model to investigate intra and extracochlear electric fields in cochlear implant stimulation

Callejón-Leblic,

Lazo-Maestre,

Fratter

et al. 2024

Phys. Med. Biol.

View full text Add to dashboard Cite

show abstract

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A phenomenological computational model of the evoked action potential fitted to human cochlear implant responses

Cited by 1 publication

References 59 publications

A full-head model to investigate intra and extracochlear electric fields in cochlear implant stimulation

A full-head model to investigate intra and extracochlear electric fields in cochlear implant stimulation

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