Top

Journal of the Association for Research in Otolaryngology

Published in:

Open Access 10-08-2022 | Cochlear Implant | Research Article

Changes in the Electrically Evoked Compound Action Potential over time After Implantation and Subsequent Deafening in Guinea Pigs

Authors: Dyan Ramekers, Heval Benav, Sjaak F. L. Klis, Huib Versnel

Published in: Journal of the Association for Research in Otolaryngology | Issue 6/2022

Abstract

The electrically evoked compound action potential (eCAP) is a direct measure of the responsiveness of the auditory nerve to electrical stimulation from a cochlear implant (CI). CIs offer a unique opportunity to study the auditory nerve’s electrophysiological behavior in individual human subjects over time. In order to understand exactly how the eCAP relates to the condition of the auditory nerve, it is crucial to compare changes in the eCAP over time in a controlled model of deafness-induced auditory nerve degeneration. In the present study, 10 normal-hearing young adult guinea pigs were implanted and deafened 4 weeks later, so that the effect of deafening could be monitored within-subject over time. Following implantation, but before deafening, most examined eCAP characteristics significantly changed, suggesting increasing excitation efficacy (e.g., higher maximum amplitude, lower threshold, shorter latency). Conversely, inter-phase gap (IPG) effects on these measures – within-subject difference measures that have been shown to correlate well with auditory nerve survival – did not vary for most eCAP characteristics. After deafening, we observed an initial increase in excitability (steeper slope of the eCAP amplitude growth function (AGF), lower threshold, shorter latency and peak width) which typically returned to normal-hearing levels within a week, after which a slower process, probably reflecting spiral ganglion cell loss, took place over the remaining 6 weeks (e.g., decrease in maximum amplitude, AGF slope, peak area, and IPG effect for AGF slope; increase in IPG effect for latency). Our results suggest that gradual changes in peak width and latency reflect the rate of neural degeneration, while peak area, maximum amplitude, and AGF slope reflect neural population size, which may be valuable for clinical diagnostics.

Agterberg MJH, Versnel H, de Groot JCMJ, Smoorenburg GF, Albers FWJ, Klis SFL (2008) Morphological changes in spiral ganglion cells after intracochlear application of brain-derived neurotrophic factor in deafened guinea pigs. Hear Res 244:25–34CrossRef

Agterberg MJH, Versnel H, Van Dijk LM, De Groot JCMJ, Klis SFL (2009) Enhanced survival of spiral ganglion cells after cessation of treatment with brain-derived neurotrophic factor in deafened guinea pigs. J Assoc Res Otolaryngol 10:355–367CrossRef

Brochier T, Guérit F, Deeks JM, Garcia C, Bance M, Carlyon RP (2021) Evaluating and comparing behavioural and electrophysiological estimates of neural health in cochlear implant users. J Assoc Res Otolaryngol 22:67–80CrossRef

Brown CJ, Abbas PJ, Gantz B (1990) Electrically evoked whole-nerve action potentials: data from human cochlear implant users. J Acoust Soc Am 88:1385–1391CrossRef

Carlyon RP, Deeks JM (2015) Combined neural and behavioural measures of temporal pitch perception in cochlear implant users. J Acoust Soc Am 138:2885–2905CrossRef

Cheng Y-S, Svirsky MA (2021) Meta-analysis–correlation between spiral ganglion cell counts and speech perception with a cochlear implant. Audiol Res 11:220–226CrossRef

de Groot JCMJ, Veldman JE, Huizing EH (1987) An improved fixation method for guinea pig cochlear tissues. Acta Otolaryngol 104:234–242CrossRef

DeVries L, Scheperle R, Arenberg Bierer J (2016) Assessing the electrode-neuron interface with the electrically evoked compound action potential, electrode position, and behavioral thresholds. J Assoc Res Otolaryngol 17:237–52CrossRef

Fayad JN, Linthicum FH Jr (2006) Multichannel cochlear implants: relation of histopathology to performance. Laryngoscope 116:1310–1320CrossRef

Hall RD (1990) Estimation of surviving spiral ganglion cells in the deaf rat using the electrically evoked auditory brainstem response. Hear Res 45:123–36CrossRef

Harris KC, Vaden KI Jr, McClaskey CM, Dias JW, Dubno JR (2018) Complementary metrics of human auditory nerve function derived from compound action potentials. J Neurophysiol 119:1019–1028CrossRef

He S, Teagle HFB, Buchman CA (2017) The electrically evoked compound action potential: from laboratory to clinic. Front Neurosci 11:339CrossRef

He S, Xu L, Skidmore J, Chao X, Jeng F-C, Wang R, Luo J, Wang H (2020) The effect of interphase gap on neural response of the electrically-stimulated cochlear nerve in children with cochlear nerve deficiency and children with normal-sized cochlear nerves. Ear Hear 41:918–934CrossRef

Hughes ML, Choi S, Glickman E (2018) What can stimulus polarity and interphase gap tell us about auditory nerve function in cochlear-implant recipients? Hear Res 359:50–63CrossRef

Imsiecke M, Büchner A, Lenarz T, Nogueira W (2021) Amplitude growth functions of auditory nerve responses to electric pulse stimulation with varied interphase gaps in cochlear implant users with ipsilateral residual hearing. Trends Hear 25:23312165211014136

Jahn KN, Arenberg JG (2019) Evaluating psychophysical polarity sensitivity as an indirect estimate of neural status in cochlear implant listeners. J Assoc Res Otolaryngol 20:415–430CrossRef

Joshi SN, Dau T, Epp B (2017) A model of electrically stimulated auditory nerve fiber responses with peripheral and central sites of spike generation. J Assoc Res Otolaryngol 18:323–342CrossRef

Kamakura T, Nadol JB Jr (2016) Correlation between word recognition score and intracochlear new bone and fibrous tissue after cochlear implantation in the human. Hear Res 339:132–141CrossRef

Kim JR, Abbas PJ, Brown CJ, Etler CP, O’Brien S, Kim LS (2010) The relationship between electrically evoked compound action potential and speech perception: a study in cochlear implant users with short electrode array. Otol Neurotol 31:1041–1048CrossRef

Liberman MC (1978) Auditory-nerve response from cats raised in a low-noise chamber. J Acoust Soc Am 63:442–55CrossRef

Limón A, Pérez C, Vega R, Soto E (2005) Ca²⁺-activated K⁺-current density is correlated with soma size in rat vestibular-afferent neurons in culture. J Neurophysiol 94:3751–3761CrossRef

Luque M, Schrott-Fischer A, Dudas J, Pechriggl E, Brenner E, Rask-Andersen H, Liu W, Glueckert R (2021) HCN channels in the mammalian cochlea: expression pattern, subcellular location, and age-dependent changes. J Neurosci Res 99:699–728CrossRef

Manley GA, Robertson D (1976) Analysis of spontaneous activity of auditory neurones in the spiral ganglion of the guinea-pig cochlea. J Physiol 258:323–336CrossRef

Miller JM, Chi DH, O’Keeffe LJ, Kruszka P, Raphael Y, Altschuler RA (1997) Neurotrophins can enhance spiral ganglion cell survival after inner hair cell loss. Int J Dev Neurosci 15:631–643CrossRef

Nadol JB Jr (1990) Degeneration of cochlear neurons as seen in the spiral ganglion of man. Hear Res 49:141–154CrossRef

Nadol JB Jr, Shiao JY, Burgess BJ, Ketten DR, Eddington DK, Gantz BJ, Kos I, Montandon P, Coker NJ, Roland JT Jr, Shallop JK (2001) Histopathology of cochlear implants in humans. Ann Otol Rhinol Laryngol 110:883–891CrossRef

Pfingst BE, Colesa DJ, Swiderski DL, Hughes AP, Strahl SB, Sinan M, Raphael Y (2017) Neurotrophin gene therapy in deafened ears with cochlear implants: long-term effects on nerve survival and functional measures. J Assoc Res Otolaryngol 18:731–750CrossRef

Pfingst BE, Zhou N, Colesa DJ, Watts MM, Strahl SB, Garadat SN, Schvartz-Leyzac KC, Budenz CL, Raphael Y, Zwolan TA (2015) Importance of cochlear health for implant function. Hear Res 322:77–88CrossRef

Pinyon JL, Tadros SF, Froud KE, Wong ACY, Tompson IT, Crawford EN, Ko M, Morris R, Klugmann M, Housley GD (2014) Close-field electroporation gene delivery using the cochlear implant electrode array enhances the bionic ear. Sci Transl Med 6:233ra54

Prado-Guitierrez P, Fewster LM, Heasman JM, McKay CM, Shepherd RK (2006) Effect of interphase gap and pulse duration on electrically evoked potentials is correlated with auditory nerve survival. Hear Res 215:47–55CrossRef

Prenzler NK, Weller T, Steffens M, Lesinski-Schiedat A, Büchner A, Lenarz T, Warnecke A (2020) Impedance values do not correlate with speech understanding in cochlear implant recipients. Otol Neurotol 41:e1029–e1034CrossRef

Ramekers D, Klis SFL, Versnel H (2020) Simultaneous rather than retrograde spiral ganglion cell degeneration following ototoxically induced hair cell loss in the guinea pig cochlea. Hear Res 390:107928CrossRef

Ramekers D, Versnel H, Grolman W, Klis SFL (2012) Neurotrophins and their role in the cochlea. Hear Res 288:19–33CrossRef

Ramekers D, Versnel H, Strahl SB, Klis SFL, Grolman W (2015a) Temporary neurotrophin treatment prevents deafness-induced auditory nerve degeneration and preserves function. J Neurosci 35:12331–12345CrossRef

Ramekers D, Versnel H, Strahl SB, Klis SFL, Grolman W (2015b) Recovery characteristics of the electrically stimulated auditory nerve in deafened guinea pigs: relation to neuronal status. Hear Res 321:12–24CrossRef

Ramekers D, Versnel H, Strahl SB, Smeets EM, Klis SFL, Grolman W (2014) Auditory-nerve responses to varied inter-phase gap and phase duration of the electric pulse stimulus as predictors for neuronal degeneration. J Assoc Res Otolaryngol 15:187–202CrossRef

Rattay F, Lutter P, Felix H (2001) A model of the electrically excited human cochlear neuron: I. Contribution of neural substructures to the generation and propagation of spikes. Hear Res 153:43–63CrossRef

Resnick JM, Rubinstein JT (2021) Simulated auditory fiber myelination heterogeneity desynchronizes population responses to electrical stimulation limiting inter-aural timing difference representation. J Acoust Soc Am 149:934–947CrossRef

Riggs WJ, Vaughan C, Skidmore J, Conroy S, Pellittieri A, Carter BL, Stegman CJ, He S (2021) The sensitivity of the electrically stimulated auditory nerve to amplitude modulation cues declines with advanced age. Ear Hear 42:1358–1372

Scheperle RA (2017) Suprathreshold compound action potential amplitude as a measure of auditory function in cochlear implant users. J Otol 12:18–28CrossRef

Schvartz-Leyzac KC, Colesa DJ, Buswinka CJ, Rabah AM, Swiderski DL, Raphael Y, Pfingst BE (2020) How electrically evoked compound action potentials in chronically implanted guinea pigs relate to auditory nerve health and electrode impedance. J Acoust Soc Am 148:3900CrossRef

Schvartz-Leyzac KC, Colesa DJ, Buswinka CJ, Swiderski DL, Raphael Y, Pfingst BE (2019) Changes over time in the electrically evoked compound action potential (ECAP) interphase gap (IPG) effect following cochlear implantation in guinea pigs. Hear Res 383:107809CrossRef

Schvartz-Leyzac KC, Holden TA, Zwolan TA, Arts HA, Firszt JB, Buswinka CJ, Pfingst BE (2020) Effects of electrode location on estimates of neural health in humans with cochlear implants. J Assoc Res Otolaryngol 21:259–275CrossRef

Schvartz-Leyzac KC, Pfingst BE (2016) Across-site patterns of electrically evoked compound action potential amplitude-growth functions in multichannel cochlear implant recipients and the effects of the interphase gap. Hear Res 341:50–65CrossRef

Schvartz-Leyzac KC, Pfingst BE (2018) Assessing the relationship between the electrically evoked compound action potential and speech recognition abilities in bilateral cochlear implant recipients. Ear Hear 39:344–358CrossRef

Schwieger J, Hamm A, Gepp MM, Schulz A, Hoffmann A, Lenarz T, Scheper V (2020) Alginate-encapsulated brain-derived neurotrophic factor-overexpressing mesenchymal stem cells are a promising drug delivery system for protection of auditory neurons. J Tissue Eng 11:2041731420911313CrossRef

Seyyedi M, Viana LM, Nadol JB Jr (2014) Within-subject comparison of word recognition and spiral ganglion cell count in bilateral cochlear implant recipients. Otol Neurotol 35:1545–1551CrossRef

Spoendlin H (1975) Retrograde degeneration of the cochlear nerve. Acta Otolaryngol 79:266–275CrossRef

Strahl SB, Ramekers D, Nagelkerke MMB, Schwarz KE, Spitzer P, Klis SFL, Grolman W, Versnel H (2016) Assessing the firing properties of the electrically stimulated auditory nerve using a convolution model. Adv Exp Med Biol 894:143–153CrossRef

Su GL, Colesa DJ, Pfingst BE (2008) Effects of deafening and cochlear implantation procedures on postimplantation psychophysical electrical detection thresholds. Hear Res 241:64–72CrossRef

Swiderski DL, Colesa DJ, Hughes AP, Raphael Y, Pfingst BE (2020) Relationships between intrascalar tissue, neuron survival, and cochlear implant function. J Assoc Res Otolaryngol 21:337–352CrossRef

Tisi A, Rovers J, Vink HA, Ramekers D, Maccarone R, Versnel H (2022) No protective effects of hair cells or supporting cells in ototoxically deafened guinea pigs upon administration of BDNF. Brain Sci 12:2CrossRef

Undurraga JA, van Wieringen A, Carlyon RP, Macherey O, Wouters J (2010) Polarity effects on neural responses of the electrically stimulated auditory nerve at different cochlear sites. Hear Res 269:146–161CrossRef

van Loon MC, Ramekers D, Agterberg MJH, de Groot JCMJ, Grolman W, Klis SFL, Versnel H (2013) Spiral ganglion cell morphology in guinea pigs after deafening and neurotrophic treatment. Hear Res 298:17–26CrossRef

Versnel H, Prijs VF, Schoonhoven R (1990) Single-fibre responses to clicks in relationship to the compound action potential in the guinea pig. Hear Res 46:147–160CrossRef

Versnel H, Agterberg MJH, de Groot JCMJ, Smoorenburg GF, Klis SFL (2007) Time course of cochlear electrophysiology and morphology after combined administration of kanamycin and furosemide. Hear Res 231:1–12CrossRef

Vink HA, van Dorp WC, Thomeer HGXM, Versnel H, Ramekers D (2020) BDNF outperforms TrkB agonist 7,8,3′-THF in preserving the auditory nerve in deafened guinea pigs. Brain Sci 10:787CrossRef

Webster M, Webster DB (1981) Spiral ganglion neuron loss following organ of Corti loss: a quantitative study. Brain Res 212:17–30CrossRef

Wise AK, Fallon JB, Neil AJ, Pettingill LN, Geaney MS, Skinner SJ, Shepherd RK (2011) Combining cell-based therapies and neural prostheses to promote neural survival. Neurotherapeutics 8:774–787CrossRef

Ylikoski J, Wersall J, Bjorkroth B (1974) Degeneration of neural elements in the cochlea of the guinea-pig after damage to the organ of corti by ototoxic antibiotics. Acta Otolaryngol Suppl 326:23–41CrossRef

Title: Changes in the Electrically Evoked Compound Action Potential over time After Implantation and Subsequent Deafening in Guinea Pigs
Authors: Dyan Ramekers
Heval Benav
Sjaak F. L. Klis
Huib Versnel
Publication date: 10-08-2022
Publisher: Springer US
Keyword: Cochlear Implant
Published in: Journal of the Association for Research in Otolaryngology / Issue 6/2022
Print ISSN: 1525-3961
Electronic ISSN: 1438-7573
DOI: https://doi.org/10.1007/s10162-022-00864-0

Keynote webinar | Spotlight on medication adherence

Springer Medicine

Changes in the Electrically Evoked Compound Action Potential over time After Implantation and Subsequent Deafening in Guinea Pigs

Abstract

Keynote webinar | Spotlight on medication adherence

Springer Medicine

Abstract

Please log in to get access to this content

Other articles of this Issue 6/2022

Rate Discrimination Training May Partially Restore Temporal Processing Abilities from Age-Related Deficits

Temporal Envelope Coding of the Human Auditory Nerve Inferred from Electrocochleography: Comparison with Envelope Following Responses

Tone in Noise Detection in Children with a History of Temporary Conductive Hearing Loss

The Effects of Middle-ear Stiffness on the Auditory Brainstem Neural Encoding of Phase

A Computational Model of a Single Auditory Nerve Fiber for Electric-Acoustic Stimulation

Vibration Measurements of the Gerbil Eardrum Under Quasi-static Pressure Sweeps