Skip to main content
Key Specialties
Cardiology Diabetology Endocrinology Gastroenterology Geriatrics and Gerontology Gynecology and Obstetrics Hematology Infectious Disease Internal Medicine Nephrology Neurology Oncology Pediatrics Respiratory Medicine Rheumatology Surgery
Congress Coverage
2024 ACC Congress 2023 ESMO Congress 2023 EASD Congress 2023 ERS Congress 2023 ESC Congress 2023 EHA Congress 2023 ASCO Annual Meeting
Clinical Collections
Advances in Alzheimer’s

At a glance: The ONWARDS insulin icodec trials

A round-up of the ONWARDS phase 3 clinical trials evaluating the novel weekly insulin icodec in people with diabetes.
ADVANCED SEARCH
Log in
Top
Journal of the Association for Research in Otolaryngology
Published in: Journal of the Association for Research in Otolaryngology 3/2015

01-06-2015 | Research Article

Tuning of SFOAEs Evoked by Low-Frequency Tones Is Not Compatible with Localized Emission Generation

Published in: Journal of the Association for Research in Otolaryngology | Issue 3/2015

Login to get access

Abstract

Stimulus-frequency otoacoustic emissions (SFOAEs) appear to be well suited for assessing frequency selectivity because, at least on theoretical grounds, they originate over a restricted region of the cochlea near the characteristic place of the evoking tone. In support of this view, we previously found good agreement between SFOAE suppression tuning curves (SF-STCs) and a control measure of frequency selectivity (compound action potential suppression tuning curves (CAP-STC)) for frequencies above 3 kHz in chinchillas. For lower frequencies, however, SF-STCs and were over five times broader than the CAP-STCs and demonstrated more high-pass rather than narrow band-pass filter characteristics. Here, we test the hypothesis that the broad tuning of low-frequency SF-STCs is because emissions originate over a broad region of the cochlea extending basal to the characteristic place of the evoking tone. We removed contributions of the hypothesized basally located SFOAE sources by either pre-suppressing them with a high-frequency interference tone (IT; 4.2, 6.2, or 9.2 kHz at 75 dB sound pressure level (SPL)) or by inducing acoustic trauma at high frequencies (exposures to 8, 5, and lastly 3-kHz tones at 110–115 dB SPL). The 1-kHz SF-STCs and CAP-STCs were measured for baseline, IT present and following the acoustic trauma conditions in anesthetized chinchillas. The IT and acoustic trauma affected SF-STCs in an almost indistinguishable way. The SF-STCs changed progressively from a broad high-pass to narrow band-pass shape as the frequency of the IT was lowered and for subsequent exposures to lower-frequency tones. Both results were in agreement with the “basal sources” hypothesis. In contrast, CAP-STCs were not changed by either manipulation, indicating that neither the IT nor acoustic trauma affected the 1-kHz characteristic place. Thus, unlike CAPs, SFOAEs cannot be considered as a place-specific measure of cochlear function at low frequencies, at least in chinchillas.
Literature
Arnold DJ, Lonsbury-Martin BL, Martin GK (1999) High-frequency hearing influences lower-frequency distortion-product otoacoustic emissions. Arch Otolaryngol Head Neck Surg 125:215–222CrossRefPubMed
Avan P, Bonfils P, Loth D, Narcy P, Trotoux J (1991) Quantitative assessment of human cochlear function by evoked otoacoustic emissions. Hear Res 52:99–112CrossRefPubMed
Avan P, Bonfils P, Loth D, Wit HP (1993) Temporal patterns of transient-evoked otoacoustic emissions in normal and impaired cochleae. Hear Res 70:109–120CrossRefPubMed
Avan P, Bonfils P, Loth D, Elbez M, Erminy M (1995) Transient-evoked otoacoustic emissions and high-frequency acoustic trauma in the guinea pig. J Acoust Soc Am 97:3012–3020CrossRefPubMed
Avan P, Elbez M, Bonfils P (1997) Click-evoked otoacoustic emissions and the influence of high-frequency hearing losses in humans. J Acoust Soc Am 101:2771–2777CrossRefPubMed
Baiduc R, Charaziak KK, Siegel JH (2012) Spatial distribution of stimulus-frequency otoacoustic emissions generators in humans. Assoc Res Otolaryngol Abstr 398 35
Brass D, Kemp DT (1993) Suppression of stimulus frequency otoacoustic emissions. J Acoust Soc Am 93:920–939CrossRefPubMed
Charaziak KK, Siegel JH (2014) Estimating cochlear frequency selectivity with stimulus-frequency otoacoustic emissions in chinchillas. J Assoc Res Otolaryngol 15:883–896CrossRefPubMed
Charaziak KK, Souza P, Siegel JH (2013) Stimulus-frequency otoacoustic emission suppression tuning in humans: comparison to behavioral tuning. J Assoc Res Otolaryngol 14:843–862CrossRefPubMedCentralPubMed
Cheatham MA, Naik K, Dallos P (2011a) Using the cochlear microphonic as a tool to evaluate cochlear function in mouse models of hearing. J Assoc Res Otolaryngol 12:113–125CrossRefPubMedCentralPubMed
Cheatham MA, Katz ED, Charaziak KK, Dallos P, Siegel JH (2011b) Using stimulus frequency emissions to characterize cochlear function in mice. AIP Conf Proc 1403:383–388CrossRef
Choi YS, Lee SY, Parham K, Neely ST, Kim DO (2008) Stimulus-frequency otoacoustic emission: measurements in humans and simulations with an active cochlear model. J Acoust Soc Am 123:2651–2669CrossRefPubMedCentralPubMed
Clark WW (1991) Recent studies of temporary threshold shift (TTS) and permanent threshold shift (PTS) in animals. J Acoust Soc Am 90:155–163CrossRefPubMed
Clark WW, Kim DO, Zurek PM, Bohne BA (1984) Spontaneous otoacoustic emissions in chinchilla ear canals: correlation with histopathology and suppression by external tones. Hear Res 16:299–314CrossRefPubMed
Dallos P, Cheatham MA (1976a) Compound action potential (AP) tuning curves. J Acoust Soc Am 59:591–597CrossRefPubMed
Dallos P, Cheatham MA (1976b) Production of cochlear potentials by inner and outer hair cells. J Acoust Soc Am 60:510–512CrossRefPubMed
Davis RI, Ahroon WA, Hamernik RP (1989) The relation among hearing loss, sensory cell loss and tuning characteristics in the chinchilla. Hear Res 41:1–14CrossRefPubMed
Dhar S, Rogers A, Abdala C (2011) Breaking away: violation of distortion emission phase-frequency invariance at low frequencies. J Acoust Soc Am 129:3115–3122CrossRefPubMedCentralPubMed
Dreisbach LE, Torre P 3rd, Kramer SJ, Kopke R, Jackson R, Balough B (2008) Influence of ultrahigh-frequency hearing thresholds on distortion-product otoacoustic emission levels at conventional frequencies. J Am Acad Audiol 19:325–336CrossRefPubMed
Geisler CD, Yates GK, Patuzzi RB, Johnstone BM (1990) Saturation of outer hair cell receptor currents causes two-tone suppression. Hear Res 44:241–256CrossRefPubMed
Goodman SS, Mertes IB, Scheperle RA (2011) Delays and growth rates of multiple TEOAE components. In: Shera CA, Olson ES (eds) What fire is in mine ears: progress in auditory biomechanics. AIP Conf. Proc, pp 279–285
Guinan JJ (1990) Changes in stimulus frequency otoacoustic emissions produced by two-tone suppression and efferent stimulation in cats. In: Dallos P, Geisler CD, Matthews JW, Ruggero MA, Steele CR (eds) The mechanics and biophysics of hearing. Springer, Madison, pp 170–177CrossRef
Harding GW, Bohne BA, Ahmad M (2002) DPOAE level shifts and ABR threshold shifts compared to detailed analysis of histopathological damage from noise. Hear Res 174:158–171CrossRefPubMed
He W, Porsov E, Kemp D, Nuttall AL, Ren T (2012) The group delay and suppression pattern of the cochlear microphonic potential recorded at the round window. PLoS One 7:e34356CrossRefPubMedCentralPubMed
Heitmann J, Waldmann B, Schnitzler H-U, Plinkert PK, Zenner H-P (1998) Suppression of distortion product otoacoustic emissions (DPOAE) near 2f1−f2 removes DP-gram fine structure—evidence for a secondary generator. J Acoust Soc Am 103:1527–1531CrossRef
Jedrzejczak WW, Kochanek K, Trzaskowski B, Pilka E, Skarzynski PH, Skarzynski H (2012) Tone-burst and click-evoked otoacoustic emissions in subjects with hearing loss above 0.25, 0.5, and 1 kHz. Ear Hear 33:757–767CrossRefPubMed
Kalluri R, Shera CA (2007) Comparing stimulus-frequency otoacoustic emissions measured by compression, suppression, and spectral smoothing. J Acoust Soc Am 122:3562–3575CrossRefPubMed
Keefe DH, Ellison JC, Fitzpatrick DF, Gorga MP (2008) Two-tone suppression of stimulus frequency otoacoustic emissions. J Acoust Soc Am 123:1479–1494CrossRefPubMedCentralPubMed
Kemp DT (2007) Otoacoustic Emissions: the basics, the science and the future potential. In: Robinette MS, Glattke TJ (eds) Otoacoustic emissions: clinical applications. Theime, New York, pp 7–42
Kemp DT, Chum RA (1980) Observations on the generator mechanism of stimulus frequency acoustic emissions–two tone suppression. In: deBoer E, Viergever MA (eds) Psychophysical, physiological and behavioral studies in hearing. Delft University Press, Delft, pp 34–41CrossRef
Killan EC, Lutman ME, Montelpare WJ, Thyer NJ (2012) A mechanism for simultaneous suppression of tone burst-evoked otoacoustic emissions. Hear Res 285:58–64CrossRefPubMed
Lewis J, Goodman S (2014) The origin of short-latency transient-evoked otoacoustic emissions. J Assoc Res Otolaryngol 37:72, Abstr: 126
Liberman MC (1978) Auditory-nerve response from cats raised in a low-noise chamber. J Acoust Soc Am 63:442–455CrossRefPubMed
Liberman MC, Dodds LW (1987) Acute ultrastructural changes in acoustic trauma: serial-section reconstruction of stereocilia and cuticular plates. Hear Res 26:45–64CrossRefPubMed
Martin GK, Stagner BB, Jassir D, Telischi FF, Lonsbury-Martin BL (1999) Suppression and enhancement of distortion-product otoacoustic emissions by interference tones above f(2). I. Basic findings in rabbits. Hear Res 136:105–123CrossRefPubMed
Martin GK, Villasuso EI, Stagner BB, Lonsbury-Martin BL (2003) Suppression and enhancement of distortion-product otoacoustic emissions by interference tones above f(2). II. Findings in humans. Hear Res 177:111–122CrossRefPubMed
Martin GK, Stagner BB, Fahey PF, Lonsbury-Martin BL (2009) Steep and shallow phase gradient distortion product otoacoustic emissions arising basal to the primary tones. J Acoust Soc Am 125:El85–El92PubMed
Martin GK, Stagner BB, Lonsbury-Martin BL (2010) Evidence for basal distortion-product otoacoustic emission components. J Acoust Soc Am 127:2955–2972CrossRefPubMedCentralPubMed
Martin GK, Stagner BB, Chung YS, Lonsbury-Martin BL (2011) Characterizing distortion-product otoacoustic emission components across four species. J Acoust Soc Am 129:3090–3103CrossRefPubMedCentralPubMed
Mertes IB, Goodman SS (2013) Short-latency transient-evoked otoacoustic emissions as predictors of hearing status and thresholdsa). J Acoust Soc Am 134:2127–2135CrossRefPubMed
Mills DM (2000) Frequency responses of two- and three-tone distortion product otoacoustic emissions in Mongolian gerbils. J Acoust Soc Am 107:2586–2602CrossRefPubMed
Moleti A, Al-Maamury AM, Bertaccini D, Botti T, Sisto R (2013) Generation place of the long- and short-latency components of transient-evoked otoacoustic emissions in a nonlinear cochlear model. J Acoust Soc Am 133:4098–4108CrossRefPubMed
Moleti A, Sisto R, Lucertini M (2014) Experimental evidence for the basal generation place of the short-latency transient-evoked otoacoustic emissions. J Acoust Soc Am 135:2862–2872CrossRefPubMed
Muller M, Hoidis S, Smolders JW (2010) A physiological frequency-position map of the chinchilla cochlea. Hear Res 268:184–193CrossRefPubMed
Murnane OD, Kelly JK (2003) The effects of high-frequency hearing loss on low-frequency components of the click-evoked otoacoustic emission. J Am Acad Audiol 14:525–533CrossRefPubMed
Neely S, Liu Z (2011) EMAV: otoacoustic emission averager. In: Technical Memorandum. Omaha, NE: Boys Town National Research Hospital
Nordmann AS, Bohne BA, Harding GW (2000) Histopathological differences between temporary and permanent threshold shift. Hear Res 139:13–30CrossRefPubMed
Özdamar Ö, Dallos P (1978) Synchronous responses of the primary auditory fibers to the onset of tone burst and their relation to compound action potentials. Brain Res 155:169–175CrossRefPubMed
Pickles JO, Osborne MP, Comis SD (1987) Vulnerability of tip links between stereocilia to acoustic trauma in the guinea pig. Hear Res 25:173–183CrossRefPubMed
Puel JL, Bobbin RP, Fallon M (1988) The active process is affected first by intense sound exposure. Hear Res 37:53–63CrossRefPubMed
Rasetshwane DM, Argenyi M, Neely ST, Kopun JG, Gorga MP (2013) Latency of tone-burst-evoked auditory brain stem responses and otoacoustic emissions: level, frequency, and rise-time effects. J Acoust Soc Am 133:2803–2817CrossRefPubMedCentralPubMed
Rhode WS (2007) Mutual suppression in the 6 kHz region of sensitive chinchilla cochleae. J Acoust Soc Am 121:2805–2818CrossRefPubMed
Ruggero MA, Rich NC, Recio A (1996) The effect of intense acoustic stimulation on basilar-membrane vibrations. Audit Neurosci 2:329–345
Shera CA, Guinan JJ Jr (1999) Evoked otoacoustic emissions arise by two fundamentally different mechanisms: a taxonomy for mammalian OAEs. J Acoust Soc Am 105:782–798CrossRefPubMed
Shera CA, Guinan JJ Jr (2003) Stimulus-frequency-emission group delay: a test of coherent reflection filtering and a window on cochlear tuning. J Acoust Soc Am 113:2762–2772CrossRefPubMed
Shera CA, Tubis A, Talmadge CL, Guinan JJ Jr (2004) The dual effect of “suppressor” tones on stimulus-frequency otoacoustic emissions. J Assoc Res Otolaryngol 27:538
Shera CA, Guinan JJ Jr, Oxenham AJ (2010) Otoacoustic estimation of cochlear tuning: validation in the chinchilla. J Assoc Res Otolaryngol 11:343–365CrossRefPubMedCentralPubMed
Siegel JH (2006) The biophysical origin of otoacoustic emissions. In: Nuttall AL, Ren T, Gillespe P, Grosh K, de Boer E (eds) Auditory mechanisms: processes and models. World Scientific, Singapore, pp 361–368CrossRef
Siegel JH (2007) Calibration of otoacoustic emission probes. In: Robinette MS, Glattke TJ (eds) Otoacoustic emissions: clinical applications, 3rd edn. Thieme, New York, pp 403–429
Siegel JH (2008) Species differences in low-level otoacoustic emissions may be explained by “hot regions” in the cochlea. J Acoust Soc Am 123:3852CrossRef
Siegel JH, Cerka AJ, Recio-Spinoso A, Temchin AN, van Dijk P, Ruggero MA (2005) Delays of stimulus-frequency otoacoustic emissions and cochlear vibrations contradict the theory of coherent reflection filtering. J Acoust Soc Am 118:2434–2443CrossRefPubMed
Sisto R, Sanjust F, Moleti A (2013) Input/output functions of different-latency components of transient-evoked and stimulus-frequency otoacoustic emissions. J Acoust Soc Am 133:2240–2253CrossRefPubMed
Songer JE, Rosowski JJ (2005) The effect of superior canal dehiscence on cochlear potential in response to air-conducted stimuli in chinchilla. Hear Res 210:53–62CrossRefPubMedCentralPubMed
Souter M (1995) Stimulus frequency otoacoustic emissions from guinea pig and human subjects. Hear Res 90:1–11CrossRefPubMed
Sutton GJ (1985) Suppression effects in the spectrum of evoked oto-acoustic emissions. Acustica 58:57–63
Taberner AM, Liberman MC (2005) Response properties of single auditory nerve fibers in the mouse. J Neurophysiol 93:557–569CrossRefPubMed
Teas DC, Eldredge DH, Davis H (1962) Cochlear responses to acoustic transients: an interpretation of whole-nerve action potentials. J Acoust Soc Am 34:1438–1459CrossRef
Temchin AN, Rich NC, Ruggero MA (2008) Threshold tuning curves of chinchilla auditory-nerve fibers. I. Dependence on characteristic frequency and relation to the magnitudes of cochlear vibrations. J Neurophysiol 100:2889–2898CrossRefPubMedCentralPubMed
Temchin AN, Recio-Spinoso A, Cai H, Ruggero MA (2012) Traveling waves on the organ of Corti of the chinchilla cochlea: spatial trajectories of inner hair cell depolarization inferred from responses of auditory-nerve fibers. J Neurosci 32:10522–10529CrossRefPubMedCentralPubMed
Thorne PR, Duncan CE, Gavin JB (1986) The pathogenesis of stereocilia abnormalities in acoustic trauma. Hear Res 21:41–49CrossRefPubMed
Withnell RH, Yates GK, Kirk DL (2000) Changes to low-frequency components of the TEOAE following acoustic trauma to the base of the cochlea. Hear Res 139:1–12CrossRefPubMed
Yates GK, Withnell RH (1999) The role of intermodulation distortion in transient-evoked otoacoustic emissions. Hear Res 136:49–64CrossRefPubMed
Zettner EM, Folsom RC (2003) Transient emission suppression tuning curve attributes in relation to psychoacoustic threshold. J Acoust Soc Am 113:2031–2041CrossRefPubMed
Zurek PM, Clark WW (1981) Narrow-band acoustic-signals emitted by chinchilla ears after noise exposure. J Acoust Soc Am 70:446–450CrossRef
Zweig G, Shera CA (1995) The origin of periodicity in the spectrum of evoked otoacoustic emissions. J Acoust Soc Am 98:2018–2047CrossRefPubMed
Zwicker E, Wesel J (1990) The effect of addition in suppression of delayed evoked otoacoustic emissions and in masking. Acta Acustica 70:189–196
Metadata
Title
Tuning of SFOAEs Evoked by Low-Frequency Tones Is Not Compatible with Localized Emission Generation
Publication date
01-06-2015
Published in
Journal of the Association for Research in Otolaryngology / Issue 3/2015
Print ISSN: 1525-3961
Electronic ISSN: 1438-7573
DOI
https://doi.org/10.1007/s10162-015-0513-0

Other articles of this Issue 3/2015

Journal of the Association for Research in Otolaryngology 3/2015 Go to the issue

Research Article

A Sox10rtTA/+ Mouse Line Allows for Inducible Gene Expression in the Auditory and Balance Organs of the Inner Ear

Research Article

Acoustic Temporal Modulation Detection in Normal-Hearing and Cochlear Implanted Listeners: Effects of Hearing Mechanism and Development

Research Article

Perilymph Kinetics of FITC-Dextran Reveals Homeostasis Dominated by the Cochlear Aqueduct and Cerebrospinal Fluid

Research Article

Perceptual Interactions Between Electrodes Using Focused and Monopolar Cochlear Stimulation

Research Article

Histopathologic Changes of the Inner ear in Rhesus Monkeys After Intratympanic Gentamicin Injection and Vestibular Prosthesis Electrode Array Implantation

Research Article

Increased Sensitivity to Noise-Induced Hearing Loss by Blockade of Endogenous PI3K/Akt Signaling