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Journal of the Association for Research in Otolaryngology
Erschienen in: Journal of the Association for Research in Otolaryngology 4/2010

01.12.2010

The Effect of Cochlear-Implant-Mediated Electrical Stimulation on Spiral Ganglion Cells in Congenitally Deaf White Cats

verfasst von: Iris Chen, Charles J. Limb, David K. Ryugo

Erschienen in: Journal of the Association for Research in Otolaryngology | Ausgabe 4/2010

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Abstract

It has long been observed that loss of auditory receptor cells is associated with the progressive degeneration of spiral ganglion cells. Chronic electrical stimulation via cochlear implantation has been used in an attempt to slow the rate of degeneration in cats neonatally deafened by ototoxic agents but with mixed results. The present study examined this issue using white cats with a history of hereditary deafness as an alternative animal model. Nineteen cats provided new data for this study: four normal-hearing cats, seven congenitally deaf white cats, and eight congenitally deaf white cats with unilateral cochlear implants. Data from additional cats were collected from the literature. Electrical stimulation began at 3 to 4 or 6 to 7 months after birth, and cats received stimulation for approximately 7 h a day, 5 days a week for 12 weeks. Quantitative analysis of spiral ganglion cell counts, cell density, and cell body size showed no marked improvement between cochlear-implanted and congenitally deaf subjects. Average ganglion cell size from cochlear-implanted and congenitally deaf cats was statistically similar and smaller than that of normal-hearing cats. Cell density from cats with cochlear implants tended to decrease within the upper basal and middle cochlear turns in comparison to congenitally deaf cats but remained at congenitally deaf levels within the lower basal and apical cochlear turns. These results provide no evidence that chronic electrical stimulation enhances spiral ganglion cell survival, cell density, or cell size compared to that of unstimulated congenitally deaf cats. Regardless of ganglion neuron status, there is unambiguous restoration of auditory nerve synapses in the cochlear nucleus of these cats implanted at the earlier age.
Literatur
Anniko M (1985) Principles in cochlear toxicity. Arch Toxicol Suppl 8:221–239PubMed
Araki S, Kawano A, Seldon HL, Shepherd RK, Funasaka S, Clark GM (1998) Effects of chronic electrical stimulation on spiral ganglion neuron survival and size in deafened kittens. Laryngoscope 108:687–695CrossRefPubMed
Araki S, Kawano A, Seldon HL, Shepherd RK, Funasaka S, Clark GM (2000) Effects of intracochlear factors on spiral ganglion cells and auditory brain stem response after long-term electrical stimulation in deafened kittens. Otolaryngol Head Neck Surg 122:425–433CrossRefPubMed
Baker CA, Montey KL, Pongstaporn T, Ryugo DK (2010) Postnatal development of end bulbs of Held in the congenitally deaf cat. Front Neuroanat 4(19):1–14
Bergsma D, Brown K (1971) White fur, blue eyes, and deafness in the domestic cat. J Hered 62:171–185PubMed
Bosher SK, Hallpike CS (1965) Observations on the histological features, development, and pathogenesis of the inner ear degeneration of the deaf white cat. Proc R Soc Lond B Biol Sci 162:147–170CrossRefPubMed
Bredberg G (1968) Cellular pattern and nerve supply of the human organ of Corti. Acta Otolaryngol Suppl 236:1–135
Coco A, Epp SB, Fallon JB, Xu J, Millard RE, Shepherd RK (2007) Does cochlear implantation and electrical stimulation affect residual hair cells and spiral ganglion neurons? Hear Res 225:60–70CrossRefPubMed
El-Badry MM, McFadden SL (2007) Electrophysiological correlates of progressive sensorineural pathology in carboplatin-treated chinchillas. Brain Res 1134:122–130CrossRefPubMed
Elverland HH, Mair IW (1980) Hereditary deafness in the cat. An electron microscopic study of the spiral ganglion. Acta Oto-laryngol 90:360–369CrossRef
Fallon JB, Irvine DR, Shepherd RK (2008) Cochlear implants and brain plasticity. Hear Res 238:110–117CrossRefPubMed
Fayad JN, Linthicum FH Jr (2006) Multichannel cochlear implants: relation of histopathology to performance. Laryngoscope 116:1310–1320CrossRefPubMed
Gacek RR, Rasmussen GL (1961) Fiber analysis of the statoacoustic nerve of guinea pig, cat and monkey. Anat Rec 139:455–463CrossRefPubMed
Giraud AL, Lee HJ (2007) Predicting cochlear implant outcome from brain organisation in the deaf. Restor Neurol Neurosci 25:381–390PubMed
Hardie NA, Shepherd RK (1999) Sensorineural hearing loss during development: morphological and physiological response of the cochlea and auditory brainstem. Hear Res 128:147–165CrossRefPubMed
Hartshorn DO, Miller JM, Altschuler RA (1991) Protective effect of electrical stimulation in the deafened guinea pig cochlea. Otolaryngol Head Neck Surg 104:311–319PubMed
Hawkins JE Jr (1973) Comparative otopathology: aging, noise, and ototoxic drugs. Adv Otorhinolaryngol 20:125–141PubMed
Heid S, Hartmann R, Klinke R (1998) A model for prelingual deafness, the congenitally deaf white cat—population statistics and degenerative changes. Hear Res 115(1–2):101–112CrossRefPubMed
Howe HA (1934) The reaction of the cochlear nerve to destruction of its end organs: a study on deaf albino cats. J Comp Neurol 62:73–79CrossRef
Keithley EM, Feldman ML (1983) The spiral ganglion and hair cells of Bronx waltzer mice. Hear Res 12:381–391CrossRefPubMed
Keithley EM, Schreiber RC (1987) Frequency map of the spiral ganglion in the cat. J Acoust Soc Am 81:1036–1042CrossRefPubMed
Khan AM, Whiten DM, Nadol JB Jr, Eddington DK (2005a) Histopathology of human cochlear implants: correlation of psychophysical and anatomical measures. Hear Res 205:83–93CrossRefPubMed
Khan AM, Handzel O, Burgess BJ, Daimian D, Eddington DK, Nadol JB Jr (2005b) Is word recognition correlated with the number of surviving spiral ganglion cells and electrode insertion depth in human subjects with cochlear implants? Laryngoscope 115:672–677CrossRefPubMed
Kiang NYS, Rho JM, Northrop CC, Liberman MC, Ryugo DK (1982) Hair-cell innervation by spiral ganglion cells in adult cats. Science 217:175–177CrossRefPubMed
Kretzmer EA, Meltzer NE, Haenggeli CA, Ryugo DK (2004) An animal model for cochlear implants. Arch Otolaryngol Head Neck Surg 130:499–508CrossRefPubMed
Kujawa SG, Liberman MC (2009) Adding insult to injury: cochlear nerve degeneration after “temporary” noise-induced hearing loss. J Neurosci 29:14077–14085CrossRefPubMed
Leake PA, Hradek GT (1988) Cochlear pathology of long term neomycin induced deafness in cats. Hear Res 33:11–33CrossRefPubMed
Leake PA, Hradek GT, Rebscher SJ, Snyder RL (1991) Chronic intracochlear electrical stimulation induces selective survival of spiral ganglion neurons in neonatally deafened cats. Hear Res 54:251–271CrossRefPubMed
Leake PA, Hradek GT, Snyder RL (1999) Chronic electrical stimulation by a cochlear implant promotes survival of spiral ganglion neurons after neonatal deafness. J Comp Neurol 412:543–562CrossRefPubMed
Leake PA, Rebscher S (2004) Anatomical considerations and long-term effects of electrical stimulation. In: Zeng F-G, Popper AN, Fay RR (eds) Auditory prostheses. Springer handbook of auditory research. Springer, New York, pp 101–148
Leake PA, Stakhovskaya O, Hradek GT, Hetherington AM (2008) Factors influencing neurotrophic effects of electrical stimulation in the deafened developing auditory system. Hear Res 242:86–99CrossRefPubMed
Li L, Parkins CW, Webster DB (1999) Does electrical stimulation of deaf cochleae prevent spiral ganglion degeneration? Hear Res 133:27–39CrossRefPubMed
Liberman MC, Kiang NYS (1978) Acoustic trauma in cats. Acta Otolaryngol (Suppl) 358:1–63
Liberman MC, Mulroy MJ (1982) Acute and chronic effects of acoustic trauma: cochlear pathology and auditory nerve pathophysiology. In: Hamernik RP, Henderson D, Salvi R (eds) New perspectives on noise-induced hearing loss. Raven, New York, pp 105–136
Limb CJ (2006) Cochlear implant-mediated perception of music. Curr Opin Otolaryngol Head Neck Surg 14:337–340CrossRefPubMed
Linthicum FH Jr, Fayad JN (2009) Spiral ganglion cell loss is unrelated to segmental cochlear sensory system degeneration in humans. Otol Neurotol 30:418–422CrossRefPubMed
Lousteau RJ (1987) Increased spiral ganglion cell survival in electrically stimulated, deafened guinea pig cochleae. Laryngoscope 97:836–842CrossRefPubMed
Lustig LR, Leake PA, Snyder RL, Rebscher SJ (1994) Changes in the cat cochlear nucleus following neonatal deafening and chronic intracochlear electrical stimulation. Hear Res 74:29–37CrossRefPubMed
Mair IW (1973) Hereditary deafness in the white cat. Acta Oto-Laryngol (Suppl) 314:1–48
Miller JD, Watson CS, Covell WP (1963) Deafening effects of noise on the cat. Acta Oto-laryngol (Suppl) 176:1–91
Mitchell A, Miller JM, Finger PA, Heller JW, Raphael Y, Altschuler RA (1997) Effects of chronic high-rate electrical stimulation on the cochlea and eighth nerve in the deafened guinea pig. Hear Res 105:30–43CrossRefPubMed
Moore JK, Niparko JK, Miller MR, Perazzo LM, Linthicum FH (1997) Effect of adult-onset deafness on the human central auditory system. Ann Otol Rhinol Laryngol 106:385–390PubMed
Nadol JB Jr, Young YS, Glynn RJ (1989) Survival of spiral ganglion cells in profound sensorineural hearing loss: implications for cochlear implantation. Ann Otol Rhinol Laryngol 98:411–416PubMed
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 110:883–891PubMed
O’Neil JN, Limb CJ, Baker CA, Ryugo DK (2010) Bilateral effects of unilateral cochlear implantation in congenitally deaf cats. J Comp Neurol 518:2382–2404CrossRefPubMed
Otte J, Schunknecht HF, Kerr AG (1978) Ganglion cell populations in normal and pathological human cochleae. Implications for cochlear implantation. Laryngoscope 88:1231–1246CrossRefPubMed
Puel JL, Ruel J, Gervais d’Aldin C, Pujol R (1998) Excitotoxicity and repair of cochlear synapses after noise-trauma induced hearing loss. NeuroReport 9:2109–2014CrossRefPubMed
Rasmussen GL (1940) Studies of the VIIIth cranial nerve of man. Laryngoscope 50:67–83CrossRef
Rubel EW, Hyson RL, Durham D (1990) Afferent regulation of neurons in the brain stem auditory system. J Neurobiol 21:169–196CrossRefPubMed
Ryugo DK, Pongstaporn T, Huchton DM, Niparko JK (1997) Ultrastructural analysis of primary endings in deaf white cats: morphologic alterations in end bulbs of Held. J Comp Neurol 385:230–244CrossRefPubMed
Ryugo DK, Rosenbaum BT, Kim PJ, Niparko JK, Saada AA (1998) Single unit recordings in the auditory nerve of congenitally deaf white cats: morphological correlates in the cochlea and cochlear nucleus. J Comp Neurol 397:532–548CrossRefPubMed
Ryugo DK, Cahill HB, Rose LS, Rosenbaum BT, Schroeder ME, Wright AL (2003) Separate forms of pathology in the cochlea of congenitally deaf white cats. Hear Res 181:73–84CrossRefPubMed
Ryugo DK, Kretzmer EA, Niparko JK (2005) Restoration of auditory nerve synapses in cats by cochlear implants. Science 310:1490–1492CrossRefPubMed
Ryugo DK, Baker CA, Montey KL, Chang LY, Coco A, Fallon JB, Shepherd RK (2010) Synaptic plasticity after chemical deafening and electrical stimulation of the auditory nerve in cats. J Comp Neurol 518:1046–1063CrossRefPubMed
Scheibe A (1892) A case of deaf-mutism, with auditory atrophy and anomalies of development in the membranous labyrinth of both ears. Arch Otol 21:12–22
Schuknecht H (1993) Pathology of the ear. Harvard University Press, Cambridge
Schuknecht HF, Woellner RC (1953) Hearing losses following partial section of the cochlear nerve. Laryngoscope 63:441–465PubMed
Shepherd RK, Martin RL (1995) Onset of ototoxicity in the cat is related to onset of auditory function. Hear Res 92:131–142CrossRefPubMed
Shepherd RK, Matsushima J, Martin RL, Clark GM (1994) Cochlear pathology following chronic electrical stimulation of the auditory nerve: II. Deafened kittens. Hear Res 81:150–166CrossRefPubMed
Shepherd RK, Hardie NA (2001) Deafness-induced changes in the auditory pathway: implications for cochlear implants. Audiol Neurootol 6:305–318CrossRefPubMed
Shepherd RK, Meltzer NE, Fallon JB, Ryugo DK (2006) Consequences of deafness and electrical stimulation on the peripheral and central auditory system. In: Waltzman SB, Roland JT Jr (eds) Cochlear implants. Thieme, New York, pp 25–39
Spoendlin H (1984) Factors inducing retrograde degeneration of the cochlear nerve. Ann Otol Rhinol Laryngol (Suppl) 112:76–82
Terayama Y, Kaneko Y, Kawamoto K, Sakai N (1977) Ultrastructural changes of the nerve elements following disruption of the organ of Corti. I. Nerve elements in the organ of Corti. Acta Oto-laryngol 83:291–302CrossRef
Teufert KB, Linthicum FH Jr, Connell SS (2006) The effect of organ of corti loss on ganglion cell survival in humans. Otol Neurotol 27:1146–1151CrossRefPubMed
Waltzman SB (2006) Speech processing in children with cochlear implants. In: Waltzman SB, Roland JT Jr (eds) Cochlear implants. Thieme, New York, pp 146–152
Webster M, Webster DB (1981) Spiral ganglion neuron loss following organ of Corti loss: a quantitative study. Brain Res 212:17–30CrossRefPubMed
Wilson BS, Dorman MF (2008) Cochlear implants: a remarkable past and a brilliant future. Hear Res 242:3–21CrossRefPubMed
Metadaten
Titel
The Effect of Cochlear-Implant-Mediated Electrical Stimulation on Spiral Ganglion Cells in Congenitally Deaf White Cats
verfasst von
Iris Chen
Charles J. Limb
David K. Ryugo
Publikationsdatum
01.12.2010
Verlag
Springer-Verlag
Erschienen in
Journal of the Association for Research in Otolaryngology / Ausgabe 4/2010
Print ISSN: 1525-3961
Elektronische ISSN: 1438-7573
DOI
https://doi.org/10.1007/s10162-010-0234-3

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