Human auditory periphery model: cochlea, IHC-AN, auditory brainstem responses (Verhulst et al 2018)


Verhulst S, Altoè A, Vasilkov V. (2018). Computational modeling of the human auditory periphery: Auditory-nerve responses, evoked potentials and hearing loss. Hearing research. 360 [PubMed]

See more from authors: Verhulst S · Altoè A · Vasilkov V

References and models cited by this paper

Allen JB, Sondhi MM. (1979). Cochlear macromechanics: time domain solutions. The Journal of the Acoustical Society of America. 66 [PubMed]

Altoè A, Pulkki V, Verhulst S. (2014). Transmission line cochlear models: improved accuracy and efficiency. The Journal of the Acoustical Society of America. 136 [PubMed]

Altoè A, Pulkki V, Verhulst S. (2017). Model-based estimation of the frequency tuning of the inner-hair-cell stereocilia from neural tuning curves. The Journal of the Acoustical Society of America. 141 [PubMed]

Altoè A, Pulkki V, Verhulst S. (2018). The effects of the activation of the inner-hair-cell basolateral K+ channels on auditory nerve responses. Hearing research. 364 [PubMed]

Beutner D, Voets T, Neher E, Moser T. (2001). Calcium dependence of exocytosis and endocytosis at the cochlear inner hair cell afferent synapse. Neuron. 29 [PubMed]

Bharadwaj HM, Masud S, Mehraei G, Verhulst S, Shinn-Cunningham BG. (2015). Individual differences reveal correlates of hidden hearing deficits. The Journal of neuroscience : the official journal of the Society for Neuroscience. 35 [PubMed]

Bharadwaj HM, Shinn-Cunningham BG. (2014). Rapid acquisition of auditory subcortical steady state responses using multichannel recordings. Clinical neurophysiology : official journal of the International Federation of Clinical Neurophysiology. 125 [PubMed]

Bharadwaj HM, Verhulst S, Shaheen L, Liberman MC, Shinn-Cunningham BG. (2014). Cochlear neuropathy and the coding of supra-threshold sound. Frontiers in systems neuroscience. 8 [PubMed]

Bidelman GM. (2015). Multichannel recordings of the human brainstem frequency-following response: scalp topography, source generators, and distinctions from the transient ABR. Hearing research. 323 [PubMed]

Bourien J et al. (2014). Contribution of auditory nerve fibers to compound action potential of the auditory nerve. Journal of neurophysiology. 112 [PubMed]

Cariani PA, Delgutte B, Hammond BM. (1998). Neural coding of the temporal envelope of speech: relation to modulation transfer functions Psychophysical and Physiological Advances in Hearing.

Carney LH, Zhang X, Heinz MG, Bruce IC. (2001). Auditory nerve model for predicting performance limits of normal and impaired listeners. Acoustics Research Letters Online. 2(3)

Chapochnikov NM et al. (2014). Uniquantal release through a dynamic fusion pore is a candidate mechanism of hair cell exocytosis. Neuron. 83 [PubMed]

Cheatham MA, Dallos P. (1999). Response phase: a view from the inner hair cell. The Journal of the Acoustical Society of America. 105 [PubMed]

Corns LF, Johnson SL, Kros CJ, Marcotti W. (2014). Calcium entry into stereocilia drives adaptation of the mechanoelectrical transducer current of mammalian cochlear hair cells. Proceedings of the National Academy of Sciences of the United States of America. 111 [PubMed]

Dau T. (2003). The importance of cochlear processing for the formation of auditory brainstem and frequency following responses. The Journal of the Acoustical Society of America. 113 [PubMed]

Dau T, Epp B, Encina-Llamas G. (2007). Estimates of peripheral compression using envelope following responses J. Assoc. Res. Otolaryngol..

Dau T, Ewert SD, Jørgensen S. (2013). A multi-resolution envelope-power based model for speech intelligibility J. Acoust. Soc. Am.. 134(1)

Dau T, Kollmeier B, Kohlrausch A. (1997). Modeling auditory processing of amplitude modulation. I. Detection and masking with narrow-band carriers. The Journal of the Acoustical Society of America. 102 [PubMed]

Dau T, Wegner O, Mellert V, Kollmeier B. (2000). Auditory brainstem responses with optimized chirp signals compensating basilar-membrane dispersion. The Journal of the Acoustical Society of America. 107 [PubMed]

Davis H. (1965). A model for transducer action in the cochlea. Cold Spring Harbor symposia on quantitative biology. 30 [PubMed]

Dolphin WF. (1996). Auditory evoked responses to amplitude modulated stimuli consisting of multiple envelope components J. Comp. Physiol.. 179(1)

Dolphin WF, Mountain DC. (1992). The envelope following response: scalp potentials elicited in the Mongolian gerbil using sinusoidally AM acoustic signals. Hearing research. 58 [PubMed]

Don M, Eggermont JJ. (1978). Analysis of the click-evoked brainstem potentials in man unsing high-pass noise masking. The Journal of the Acoustical Society of America. 63 [PubMed]

Duifhuis H. (2012). Springer Science & Business Media Cochlear Mechanics: Introduction to a Time Domain Analysis of the Nonlinear Cochlea.

Elberling C, Callø J, Don M. (2010). Evaluating auditory brainstem responses to different chirp stimuli at three levels of stimulation. The Journal of the Acoustical Society of America. 128 [PubMed]

Elliott SJ, Ku EM, Lineton B. (2007). A state space model for cochlear mechanics. The Journal of the Acoustical Society of America. 122 [PubMed]

Ewert SD, Dau T. (2000). Characterizing frequency selectivity for envelope fluctuations. The Journal of the Acoustical Society of America. 108 [PubMed]

Fay RR, Manley GA. (2007). Active Processes and Otoacoustic Emissions in Hearing. 30

Frank T, Khimich D, Neef A, Moser T. (2009). Mechanisms contributing to synaptic Ca2+ signals and their heterogeneity in hair cells. Proceedings of the National Academy of Sciences of the United States of America. 106 [PubMed]

Frisina RD, Smith RL, Chamberlain SC. (1990). Encoding of amplitude modulation in the gerbil cochlear nucleus: I. A hierarchy of enhancement. Hearing research. 44 [PubMed]

Furman AC, Kujawa SG, Liberman MC. (2013). Noise-induced cochlear neuropathy is selective for fibers with low spontaneous rates. Journal of neurophysiology. 110 [PubMed]

Goldberg JM, Brown PB. (1969). Response of binaural neurons of dog superior olivary complex to dichotic tonal stimuli: some physiological mechanisms of sound localization. Journal of neurophysiology. 32 [PubMed]

Gorga MP, Neely ST, Kopun J, Tan H. (2011). Growth of suppression in humans based on distortion-product otoacoustic emission measurements. The Journal of the Acoustical Society of America. 129 [PubMed]

Gorga MP, Neely ST, Tan H, Kopun J. (2011). Distortion-product otoacoustic emission suppression tuning curves in humans J. Acoust. Soc. Am.. 129(2)

Gorga MP, Worthington DW, Reiland JK, Beauchaine KA, Goldgar DE. (1985). Some comparisons between auditory brain stem response thresholds, latencies, and the pure-tone audiogram. Ear and hearing. 6 [PubMed]

Goutman JD, Glowatzki E. (2007). Time course and calcium dependence of transmitter release at a single ribbon synapse. Proceedings of the National Academy of Sciences of the United States of America. 104 [PubMed]

Grant L, Yi E, Glowatzki E. (2010). Two modes of release shape the postsynaptic response at the inner hair cell ribbon synapse. The Journal of neuroscience : the official journal of the Society for Neuroscience. 30 [PubMed]

Greenwood DD. (1990). A cochlear frequency-position function for several species--29 years later. The Journal of the Acoustical Society of America. 87 [PubMed]

Han LA, Poulsen T. (1998). Equivalent threshold sound pressure levels for Sennheiser HDA 200 earphone and Etymotic Research ER-2 insert earphone in the frequency range 125 Hz to 16 kHz. Scandinavian audiology. 27 [PubMed]

Harris DM, Dallos P. (1979). Forward masking of auditory nerve fiber responses. Journal of neurophysiology. 42 [PubMed]

Heil P, Neubauer H. (2010). Summing Across Different Active Zones can Explain the Quasi-Linear Ca-Dependencies of Exocytosis by Receptor Cells. Frontiers in synaptic neuroscience. 2 [PubMed]

Hudspeth AJ, Lewis RS. (1988). A model for electrical resonance and frequency tuning in saccular hair cells of the bull-frog, Rana catesbeiana. The Journal of physiology. 400 [PubMed]

Huet A et al. (2016). Sound coding in the auditory nerve of gerbils. Hearing research. 338 [PubMed]

Jepsen ML, Dau T. (2011). Characterizing auditory processing and perception in individual listeners with sensorineural hearing loss. The Journal of the Acoustical Society of America. 129 [PubMed]

Jepsen ML, Ewert SD, Dau T. (2008). A computational model of human auditory signal processing and perception. The Journal of the Acoustical Society of America. 124 [PubMed]

Jia S, Dallos P, He DZ. (2007). Mechanoelectric transduction of adult inner hair cells. The Journal of neuroscience : the official journal of the Society for Neuroscience. 27 [PubMed]

Jiang ZD, Zheng MS, Sun DK, Liu XY. (1991). Brainstem auditory evoked responses from birth to adulthood: normative data of latency and interval. Hearing research. 54 [PubMed]

Johnson SL. (2015). Membrane properties specialize mammalian inner hair cells for frequency or intensity encoding. eLife. 4 [PubMed]

Johnson SL, Beurg M, Marcotti W, Fettiplace R. (2011). Prestin-driven cochlear amplification is not limited by the outer hair cell membrane time constant. Neuron. 70 [PubMed]

Johnson SL, Marcotti W. (2008). Biophysical properties of CaV1.3 calcium channels in gerbil inner hair cells. The Journal of physiology. 586 [PubMed]

Joris PX et al. (2011). Frequency selectivity in Old-World monkeys corroborates sharp cochlear tuning in humans. Proceedings of the National Academy of Sciences of the United States of America. 108 [PubMed]

Joris PX, Schreiner CE, Rees A. (2004). Neural processing of amplitude-modulated sounds. Physiological reviews. 84 [PubMed]

Joris PX, Yin TC. (1992). Responses to amplitude-modulated tones in the auditory nerve of the cat. The Journal of the Acoustical Society of America. 91 [PubMed]

Jürgens T, Clark NR, Lecluyse W, Meddis R. (2016). Exploration of a physiologically-inspired hearing-aid algorithm using a computer model mimicking impaired hearing. International journal of audiology. 55 [PubMed]

Kapadia S, Lutman ME. (2000). Nonlinear temporal interactions in click-evoked otoacoustic emissions. II. Experimental data. Hearing research. 146 [PubMed]

Kennedy HJ, Evans MG, Crawford AC, Fettiplace R. (2003). Fast adaptation of mechanoelectrical transducer channels in mammalian cochlear hair cells. Nature neuroscience. 6 [PubMed]

Kidd RC, Weiss TF. (1990). Mechanisms that degrade timing information in the cochlea. Hearing research. 49 [PubMed]

Kros CJ, Crawford AC. (1990). Potassium currents in inner hair cells isolated from the guinea-pig cochlea. The Journal of physiology. 421 [PubMed]

Kros CJ, Rüsch A, Richardson GP. (1992). Mechano-electrical transducer currents in hair cells of the cultured neonatal mouse cochlea. Proceedings. Biological sciences. 249 [PubMed]

Kujawa SG, Liberman MC. (2009). Adding insult to injury: cochlear nerve degeneration after "temporary" noise-induced hearing loss. The Journal of neuroscience : the official journal of the Society for Neuroscience. 29 [PubMed]

Kuwada S, Batra R, Maher VL. (1986). Scalp potentials of normal and hearing-impaired subjects in response to sinusoidally amplitude-modulated tones. Hearing research. 21 [PubMed]

Lewis JD, Neely ST. (2015). Non-invasive estimation of middle-ear input impedance and efficiency. The Journal of the Acoustical Society of America. 138 [PubMed]

Liberman LD, Wang H, Liberman MC. (2011). Opposing gradients of ribbon size and AMPA receptor expression underlie sensitivity differences among cochlear-nerve/hair-cell synapses. The Journal of neuroscience : the official journal of the Society for Neuroscience. 31 [PubMed]

Liberman MC. (1978). Auditory-nerve response from cats raised in a low-noise chamber. The Journal of the Acoustical Society of America. 63 [PubMed]

Liberman MC, Epstein MJ, Cleveland SS, Wang H, Maison SF. (2016). Toward a Differential Diagnosis of Hidden Hearing Loss in Humans. PloS one. 11 [PubMed]

Lin HW, Furman AC, Kujawa SG, Liberman MC. (2011). Primary neural degeneration in the Guinea pig cochlea after reversible noise-induced threshold shift. Journal of the Association for Research in Otolaryngology : JARO. 12 [PubMed]

Liu YW, Neely ST. (2010). Distortion product emissions from a cochlear model with nonlinear mechanoelectrical transduction in outer hair cells. The Journal of the Acoustical Society of America. 127 [PubMed]

Lopez-Poveda EA, Eustaquio-Martín A. (2006). A biophysical model of the inner hair cell: the contribution of potassium currents to peripheral auditory compression. Journal of the Association for Research in Otolaryngology : JARO. 7 [PubMed]

Lynch TJ, Nedzelnitsky V, Peake WT. (1982). Input impedance of the cochlea in cat. The Journal of the Acoustical Society of America. 72 [PubMed]

Lyon RF. (2011). Cascades of two-pole-two-zero asymmetric resonators are good models of peripheral auditory function. The Journal of the Acoustical Society of America. 130 [PubMed]

Mao J, Carney LH. (2015). Tone-in-noise detection using envelope cues: comparison of signal-processing-based and physiological models. Journal of the Association for Research in Otolaryngology : JARO. 16 [PubMed]

Marcotti W, Johnson SL, Kros CJ. (2004). A transiently expressed SK current sustains and modulates action potential activity in immature mouse inner hair cells. The Journal of physiology. 560 [PubMed]

Meaud J, Grosh K. (2010). The effect of tectorial membrane and basilar membrane longitudinal coupling in cochlear mechanics. The Journal of the Acoustical Society of America. 127 [PubMed]

Meddis R. (1986). Simulation of mechanical to neural transduction in the auditory receptor. The Journal of the Acoustical Society of America. 79 [PubMed]

Meddis R. (2006). Auditory-nerve first-spike latency and auditory absolute threshold: a computer model. The Journal of the Acoustical Society of America. 119 [PubMed]

Meddis R, O'Mard L. (1997). A unitary model of pitch perception. The Journal of the Acoustical Society of America. 102 [PubMed]

Meddis R, O'Mard LP, Lopez-Poveda EA. (2001). A computational algorithm for computing nonlinear auditory frequency selectivity. The Journal of the Acoustical Society of America. 109 [PubMed]

Mehraei G et al. (2016). Auditory Brainstem Response Latency in Noise as a Marker of Cochlear Synaptopathy. The Journal of neuroscience : the official journal of the Society for Neuroscience. 36 [PubMed]

Melcher JR, Kiang NY. (1996). Generators of the brainstem auditory evoked potential in cat. III: Identified cell populations. Hearing research. 93 [PubMed]

Meyer AC et al. (2009). Tuning of synapse number, structure and function in the cochlea. Nature neuroscience. 12 [PubMed]

Miller CA, Abbas PJ, Robinson BK. (2001). Response properties of the refractory auditory nerve fiber. Journal of the Association for Research in Otolaryngology : JARO. 2 [PubMed]

Moezzi B, Iannella N, McDonnell MD. (2016). Ion channel noise can explain firing correlation in auditory nerves. Journal of computational neuroscience. 41 [PubMed]

Moleti A, Paternoster N, Bertaccini D, Sisto R, Sanjust F. (2009). Otoacoustic emissions in time-domain solutions of nonlinear non-local cochlear models. The Journal of the Acoustical Society of America. 126 [PubMed]

Möhrle D et al. (2016). Loss of auditory sensitivity from inner hair cell synaptopathy can be centrally compensated in the young but not old brain. Neurobiology of aging. 44 [PubMed]

Nedzelnitsky V. (1980). Sound pressures in the basal turn of the cat cochlea. The Journal of the Acoustical Society of America. 68 [PubMed]

Neely ST, Johnson TA, Kopun J, Dierking DM, Gorga MP. (2009). Distortion-product otoacoustic emission input/output characteristics in normal-hearing and hearing-impaired human ears. The Journal of the Acoustical Society of America. 126 [PubMed]

Neely ST, Kim DO. (1983). An active cochlear model showing sharp tuning and high sensitivity. Hearing research. 9 [PubMed]

Nelson PC, Carney LH. (2004). A phenomenological model of peripheral and central neural responses to amplitude-modulated tones. The Journal of the Acoustical Society of America. 116 [PubMed]

Oertel D. (1983). Synaptic responses and electrical properties of cells in brain slices of the mouse anteroventral cochlear nucleus. The Journal of neuroscience : the official journal of the Society for Neuroscience. 3 [PubMed]

Ohn TL et al. (2016). Hair cells use active zones with different voltage dependence of Ca2+ influx to decompose sounds into complementary neural codes. Proceedings of the National Academy of Sciences of the United States of America. 113 [PubMed]

Palmer AR, Russell IJ. (1986). Phase-locking in the cochlear nerve of the guinea-pig and its relation to the receptor potential of inner hair-cells. Hearing research. 24 [PubMed]

Pangrsic T et al. (2010). Hearing requires otoferlin-dependent efficient replenishment of synaptic vesicles in hair cells. Nature neuroscience. 13 [PubMed]

Peterson AJ, Irvine DR, Heil P. (2014). A model of synaptic vesicle-pool depletion and replenishment can account for the interspike interval distributions and nonrenewal properties of spontaneous spike trains of auditory-nerve fibers. The Journal of neuroscience : the official journal of the Society for Neuroscience. 34 [PubMed]

Picton TW. (2011). Chapter 8: Auditory brainstem responses: peaks along the way Human auditory evoked potentials.

Picton TW, Stapells DR, Campbell KB. (1981). Auditory evoked potentials from the human cochlea and brainstem. The Journal of otolaryngology. Supplement. 9 [PubMed]

Pieper I, Mauermann M, Kollmeier B, Ewert SD. (2016). Physiological motivated transmission-lines as front end for loudness models. The Journal of the Acoustical Society of America. 139 [PubMed]

Plack CJ, Barker D, Prendergast G. (2014). Perceptual consequences of "hidden" hearing loss. Trends in hearing. 18 [PubMed]

Prosser S, Arslan E. (1987). Prediction of auditory brainstem wave V latency as a diagnostic tool of sensorineural hearing loss. Audiology : official organ of the International Society of Audiology. 26 [PubMed]

Puria S. (2003). Measurements of human middle ear forward and reverse acoustics: implications for otoacoustic emissions. The Journal of the Acoustical Society of America. 113 [PubMed]

Puria S, Allen JB. (1991). A parametric study of cochlear input impedance. The Journal of the Acoustical Society of America. 89 [PubMed]

Raufer S, Verhulst S. (2016). Otoacoustic emission estimates of human basilar membrane impulse response duration and cochlear filter tuning. Hearing research. 342 [PubMed]

Recio A, Rhode WS. (2000). Basilar membrane responses to broadband stimuli. The Journal of the Acoustical Society of America. 108 [PubMed]

Relkin EM, Doucet JR. (1991). Recovery from prior stimulation. I: Relationship to spontaneous firing rates of primary auditory neurons. Hearing research. 55 [PubMed]

Rhode WS. (2007). Basilar membrane mechanics in the 6e9 kHz region of sensitive chinchilla cochleae J. Acoust. Soc. Am.. 121(5)

Rhode WS, Smith PH. (1985). Characteristics of tone-pip response patterns in relationship to spontaneous rate in cat auditory nerve fibers. Hearing research. 18 [PubMed]

Robles L, Ruggero MA. (2001). Mechanics of the mammalian cochlea. Physiological reviews. 81 [PubMed]

Rosen S, Baker RJ. (1994). Characterising auditory filter nonlinearity. Hearing research. 73 [PubMed]

Ruggero MA, Rich NC, Recio A, Narayan SS, Robles L. (1997). Basilar-membrane responses to tones at the base of the chinchilla cochlea. The Journal of the Acoustical Society of America. 101 [PubMed]

Ruggero MA, Robles L, Rich NC. (1992). Two-tone suppression in the basilar membrane of the cochlea: mechanical basis of auditory-nerve rate suppression. Journal of neurophysiology. 68 [PubMed]

Russell IJ, Cody AR, Richardson GP. (1986). The responses of inner and outer hair cells in the basal turn of the guinea-pig cochlea and in the mouse cochlea grown in vitro. Hearing research. 22 [PubMed]

Russell IJ, Sellick PM. (1983). Low-frequency characteristics of intracellularly recorded receptor potentials in guinea-pig cochlear hair cells. The Journal of physiology. 338 [PubMed]

Rønne FM, Dau T, Harte J, Elberling C. (2012). Modeling auditory evoked brainstem responses to transient stimuli. The Journal of the Acoustical Society of America. 131 [PubMed]

Sachs MB, Abbas PJ. (1974). Rate versus level functions for auditory-nerve fibers in cats: tone-burst stimuli. The Journal of the Acoustical Society of America. 56 [PubMed]

Saremi A et al. (2016). A comparative study of seven human cochlear filter models. The Journal of the Acoustical Society of America. 140 [PubMed]

Schaette R, McAlpine D. (2011). Tinnitus with a normal audiogram: physiological evidence for hidden hearing loss and computational model. The Journal of neuroscience : the official journal of the Society for Neuroscience. 31 [PubMed]

Schmiedt RA. (2010). The physiology of cochlear presbycusis The Aging Auditory System.

Sellick PM, Russell IJ. (1980). The responses of inner hair cells to basilar membrane velocity during low frequency auditory stimulation in the guinea pig cochlea. Hearing research. 2 [PubMed]

Serpanos YC, O'Malley H, Gravel JS. (1997). The relationship between loudness intensity functions and the click-ABR wave V latency. Ear and hearing. 18 [PubMed]

Shaheen LA, Valero MD, Liberman MC. (2015). Towards a Diagnosis of Cochlear Neuropathy with Envelope Following Responses. Journal of the Association for Research in Otolaryngology : JARO. 16 [PubMed]

Shamma SA, Chadwick RS, Wilbur WJ, Morrish KA, Rinzel J. (1986). A biophysical model of cochlear processing: intensity dependence of pure tone responses. The Journal of the Acoustical Society of America. 80 [PubMed]

Shera CA. (2001). Frequency glides in click responses of the basilar membrane and auditory nerve: their scaling behavior and origin in traveling-wave dispersion. The Journal of the Acoustical Society of America. 109 [PubMed]

Shera CA, Guinan JJ, Oxenham AJ. (2010). Otoacoustic estimation of cochlear tuning: validation in the chinchilla. Journal of the Association for Research in Otolaryngology : JARO. 11 [PubMed]

Shera CA, Shinn-Cunningham BG, Verhulst S, Bharadwaj HM, Mehraei G. (2015). Functional modeling of the human auditory brainstem response to broadband stimulation J. Acoust. Soc. Am.. 138(3)

Shera CA, Zweig G. (1991). A symmetry suppresses the cochlear catastrophe. The Journal of the Acoustical Society of America. 89 [PubMed]

Strelcyk O, Christoforidis D, Dau T. (2009). Relation between derived-band auditory brainstem response latencies and behavioral frequency selectivity. The Journal of the Acoustical Society of America. 126 [PubMed]

Sumner CJ, Lopez-Poveda EA, O'Mard LP, Meddis R. (2002). A revised model of the inner-hair cell and auditory-nerve complex. The Journal of the Acoustical Society of America. 111 [PubMed]

Sumner CJ, Lopez-Poveda EA, O'Mard LP, Meddis R. (2003). Adaptation in a revised inner-hair cell model. The Journal of the Acoustical Society of America. 113 [PubMed]

Taberner AM, Liberman MC. (2005). Response properties of single auditory nerve fibers in the mouse. Journal of neurophysiology. 93 [PubMed]

Takanen M, Santala O, Pulkki V. (2014). Visualization of functional count-comparison-based binaural auditory model output. Hearing research. 309 [PubMed]

Talmadge CL, Tubis A, Long GR, Piskorski P. (1998). Modeling otoacoustic emission and hearing threshold fine structures. The Journal of the Acoustical Society of America. 104 [PubMed]

Teich MC, Vannucci G. (1978). Effects of rate variation on the counting statistics of dead-time-modified Poisson processes Optic Commun.. 25(2)

Trautwein P, Hofstetter P, Wang J, Salvi R, Nostrant A. (1996). Selective inner hair cell loss does not alter distortion product otoacoustic emissions. Hearing research. 96 [PubMed]

Valero MD et al. (2017). Noise-induced cochlear synaptopathy in rhesus monkeys (Macaca mulatta). Hearing research. 353 [PubMed]

Verhey JL, Epp B, Mauermann M. (2010). Modeling cochlear dynamics: interrelation between cochlea mechanics and psychoacoustics J. Acoust. Soc. Am.. 128(4)

Verhulst S. (2010). Characterizing and Modeling Dynamic Processes in the Cochlea Using Otoacoustic Emissions. Ph.D. thesis.

Verhulst S, Dau T, Shera CA. (2012). Nonlinear time-domain cochlear model for transient stimulation and human otoacoustic emission. The Journal of the Acoustical Society of America. 132 [PubMed]

Verhulst S, Harte JM, Dau T. (2011). Temporal suppression of the click-evoked otoacoustic emission level-curve. The Journal of the Acoustical Society of America. 129 [PubMed]

Verhulst S, Jagadeesh A, Mauermann M, Ernst F. (2016). Individual Differences in Auditory Brainstem Response Wave Characteristics: Relations to Different Aspects of Peripheral Hearing Loss. Trends in hearing. 20 [PubMed]

Westerman LA, Smith RL. (1984). Rapid and short-term adaptation in auditory nerve responses. Hearing research. 15 [PubMed]

Westerman LA, Smith RL. (1988). A diffusion model of the transient response of the cochlear inner hair cell synapse. The Journal of the Acoustical Society of America. 83 [PubMed]

Winslow RL, Sachs MB. (1987). Effect of electrical stimulation of the crossed olivocochlear bundle on auditory nerve response to tones in noise. Journal of neurophysiology. 57 [PubMed]

Winter IM, Palmer AR. (1991). Intensity coding in low-frequency auditory-nerve fibers of the guinea pig. The Journal of the Acoustical Society of America. 90 [PubMed]

Zagaeski M, Cody AR, Russell IJ, Mountain DC. (1994). Transfer characteristic of the inner hair cell synapse: steady-state analysis. The Journal of the Acoustical Society of America. 95 [PubMed]

Zeddies DG, Siegel JH. (2004). A biophysical model of an inner hair cell. The Journal of the Acoustical Society of America. 116 [PubMed]

Zhang X, Carney LH. (2005). Analysis of models for the synapse between the inner hair cell and the auditory nerve. The Journal of the Acoustical Society of America. 118 [PubMed]

Zhang X, Heinz MG, Bruce IC, Carney LH. (2001). A phenomenological model for the responses of auditory-nerve fibers: I. Nonlinear tuning with compression and suppression. The Journal of the Acoustical Society of America. 109 [PubMed]

Zilany MS, Bruce IC. (2006). Modeling auditory-nerve responses for high sound pressure levels in the normal and impaired auditory periphery. The Journal of the Acoustical Society of America. 120 [PubMed]

Zilany MS, Bruce IC, Carney LH. (2014). Updated parameters and expanded simulation options for a model of the auditory periphery. The Journal of the Acoustical Society of America. 135 [PubMed]

Zilany MS, Bruce IC, Nelson PC, Carney LH. (2009). A phenomenological model of the synapse between the inner hair cell and auditory nerve: long-term adaptation with power-law dynamics. The Journal of the Acoustical Society of America. 126 [PubMed]

Zweig G. (1976). Basilar membrane motion. Cold Spring Harbor symposia on quantitative biology. 40 [PubMed]

Zweig G. (1991). Finding the impedance of the organ of Corti. The Journal of the Acoustical Society of America. 89 [PubMed]

Zweig G. (2016). Nonlinear cochlear mechanics. The Journal of the Acoustical Society of America. 139 [PubMed]

van Hengel PW, Duifhuis H, van den Raadt MP. (1996). Spatial periodicity in the cochlea: the result of interaction of spontaneous emissions? The Journal of the Acoustical Society of America. 99 [PubMed]

von Békésy G. (1970). Travelling waves as frequency analysers in the cochlea. Nature. 225 [PubMed]

References and models that cite this paper

Altoè A, Pulkki V, Verhulst S. (2018). The effects of the activation of the inner-hair-cell basolateral K+ channels on auditory nerve responses. Hearing research. 364 [PubMed]

See more from authors: Altoè A · Pulkki V · Verhulst S

References and models cited by this paper

Altoè A, Charaziak KK, Shera CA. (2017). Dynamics of cochlear nonlinearity: Automatic gain control or instantaneous damping? The Journal of the Acoustical Society of America. 142 [PubMed]

Altoè A, Pulkki V, Verhulst S. (2017). Model-based estimation of the frequency tuning of the inner-hair-cell stereocilia from neural tuning curves. The Journal of the Acoustical Society of America. 141 [PubMed]

Beutner D, Voets T, Neher E, Moser T. (2001). Calcium dependence of exocytosis and endocytosis at the cochlear inner hair cell afferent synapse. Neuron. 29 [PubMed]

Corns LF, Johnson SL, Kros CJ, Marcotti W. (2014). Calcium entry into stereocilia drives adaptation of the mechanoelectrical transducer current of mammalian cochlear hair cells. Proceedings of the National Academy of Sciences of the United States of America. 111 [PubMed]

Davis H. (1965). A model for transducer action in the cochlea. Cold Spring Harbor symposia on quantitative biology. 30 [PubMed]

Frank G, Hemmert W, Gummer AW. (1999). Limiting dynamics of high-frequency electromechanical transduction of outer hair cells. Proceedings of the National Academy of Sciences of the United States of America. 96 [PubMed]

Harris DM, Dallos P. (1979). Forward masking of auditory nerve fiber responses. Journal of neurophysiology. 42 [PubMed]

Hudspeth AJ, Lewis RS. (1988). Kinetic analysis of voltage- and ion-dependent conductances in saccular hair cells of the bull-frog, Rana catesbeiana. The Journal of physiology. 400 [PubMed]

Jia S, Dallos P, He DZ. (2007). Mechanoelectric transduction of adult inner hair cells. The Journal of neuroscience : the official journal of the Society for Neuroscience. 27 [PubMed]

Johnson SL. (2015). Membrane properties specialize mammalian inner hair cells for frequency or intensity encoding. eLife. 4 [PubMed]

Johnson SL, Beurg M, Marcotti W, Fettiplace R. (2011). Prestin-driven cochlear amplification is not limited by the outer hair cell membrane time constant. Neuron. 70 [PubMed]

Johnson SL, Marcotti W. (2008). Biophysical properties of CaV1.3 calcium channels in gerbil inner hair cells. The Journal of physiology. 586 [PubMed]

Joris PX, Yin TC. (1992). Responses to amplitude-modulated tones in the auditory nerve of the cat. The Journal of the Acoustical Society of America. 91 [PubMed]

Kidd RC, Weiss TF. (1990). Mechanisms that degrade timing information in the cochlea. Hearing research. 49 [PubMed]

Koch C. (2004). Biophysics of computation: information processing in single neurons.

Kros CJ, Crawford AC. (1990). Potassium currents in inner hair cells isolated from the guinea-pig cochlea. The Journal of physiology. 421 [PubMed]

Kros CJ, Ruppersberg JP, Rüsch A. (1998). Expression of a potassium current in inner hair cells during development of hearing in mice. Nature. 394 [PubMed]

Kros CJ, Rüsch A, Richardson GP. (1992). Mechano-electrical transducer currents in hair cells of the cultured neonatal mouse cochlea. Proceedings. Biological sciences. 249 [PubMed]

Kurt S et al. (2012). Critical role for cochlear hair cell BK channels for coding the temporal structure and dynamic range of auditory information for central auditory processing. FASEB journal : official publication of the Federation of American Societies for Experimental Biology. 26 [PubMed]

Lopez-Poveda EA, Eustaquio-Martín A. (2006). A biophysical model of the inner hair cell: the contribution of potassium currents to peripheral auditory compression. Journal of the Association for Research in Otolaryngology : JARO. 7 [PubMed]

Marcotti W, Johnson SL, Kros CJ. (2004). Effects of intracellular stores and extracellular Ca(2+) on Ca(2+)-activated K(+) currents in mature mouse inner hair cells. The Journal of physiology. 557 [PubMed]

Meddis R. (1986). Simulation of mechanical to neural transduction in the auditory receptor. The Journal of the Acoustical Society of America. 79 [PubMed]

Meyer AC et al. (2009). Tuning of synapse number, structure and function in the cochlea. Nature neuroscience. 12 [PubMed]

Moezzi B, Iannella N, McDonnell MD. (2016). Ion channel noise can explain firing correlation in auditory nerves. Journal of computational neuroscience. 41 [PubMed]

Mountain DC, Cody AR. (1999). Multiple modes of inner hair cell stimulation. Hearing research. 132 [PubMed]

Oliver D et al. (2006). The role of BKCa channels in electrical signal encoding in the mammalian auditory periphery. The Journal of neuroscience : the official journal of the Society for Neuroscience. 26 [PubMed]

Palmer AR, Russell IJ. (1986). Phase-locking in the cochlear nerve of the guinea-pig and its relation to the receptor potential of inner hair-cells. Hearing research. 24 [PubMed]

Pangrsic T et al. (2010). Hearing requires otoferlin-dependent efficient replenishment of synaptic vesicles in hair cells. Nature neuroscience. 13 [PubMed]

Peterson AJ, Irvine DR, Heil P. (2014). A model of synaptic vesicle-pool depletion and replenishment can account for the interspike interval distributions and nonrenewal properties of spontaneous spike trains of auditory-nerve fibers. The Journal of neuroscience : the official journal of the Society for Neuroscience. 34 [PubMed]

Robles L, Ruggero MA. (2001). Mechanics of the mammalian cochlea. Physiological reviews. 81 [PubMed]

Rutherford MA, Chapochnikov NM, Moser T. (2012). Spike encoding of neurotransmitter release timing by spiral ganglion neurons of the cochlea. The Journal of neuroscience : the official journal of the Society for Neuroscience. 32 [PubMed]

Shamma SA, Chadwick RS, Wilbur WJ, Morrish KA, Rinzel J. (1986). A biophysical model of cochlear processing: intensity dependence of pure tone responses. The Journal of the Acoustical Society of America. 80 [PubMed]

Siegel JH. (1992). Spontaneous synaptic potentials from afferent terminals in the guinea pig cochlea. Hearing research. 59 [PubMed]

Sumner CJ, Lopez-Poveda EA, O'Mard LP, Meddis R. (2002). A revised model of the inner-hair cell and auditory-nerve complex. The Journal of the Acoustical Society of America. 111 [PubMed]

Temchin AN, Rich NC, Ruggero MA. (2008). Threshold tuning curves of chinchilla auditory nerve fibers. II. Dependence on spontaneous activity and relation to cochlear nonlinearity. Journal of neurophysiology. 100 [PubMed]

Temchin AN, Ruggero MA. (2010). Phase-locked responses to tones of chinchilla auditory nerve fibers: implications for apical cochlear mechanics. Journal of the Association for Research in Otolaryngology : JARO. 11 [PubMed]

Verhulst S, Bharadwaj HM, Mehraei G, Shera CA, Shinn-Cunningham BG. (2015). Functional modeling of the human auditory brainstem response to broadband stimulation. The Journal of the Acoustical Society of America. 138 [PubMed]

Westerman LA, Smith RL. (1984). Rapid and short-term adaptation in auditory nerve responses. Hearing research. 15 [PubMed]

Westerman LA, Smith RL. (1988). A diffusion model of the transient response of the cochlear inner hair cell synapse. The Journal of the Acoustical Society of America. 83 [PubMed]

Winter IM, Robertson D, Yates GK. (1990). Diversity of characteristic frequency rate-intensity functions in guinea pig auditory nerve fibres. Hearing research. 45 [PubMed]

Zagaeski M, Cody AR, Russell IJ, Mountain DC. (1994). Transfer characteristic of the inner hair cell synapse: steady-state analysis. The Journal of the Acoustical Society of America. 95 [PubMed]

Zhang X, Carney LH. (2005). Analysis of models for the synapse between the inner hair cell and the auditory nerve. The Journal of the Acoustical Society of America. 118 [PubMed]

Zhang X, Heinz MG, Bruce IC, Carney LH. (2001). A phenomenological model for the responses of auditory-nerve fibers: I. Nonlinear tuning with compression and suppression. The Journal of the Acoustical Society of America. 109 [PubMed]

Zilany MS, Bruce IC, Nelson PC, Carney LH. (2009). A phenomenological model of the synapse between the inner hair cell and auditory nerve: long-term adaptation with power-law dynamics. The Journal of the Acoustical Society of America. 126 [PubMed]

References and models that cite this paper

Verhulst S, Altoè A, Vasilkov V. (2018). Computational modeling of the human auditory periphery: Auditory-nerve responses, evoked potentials and hearing loss. Hearing research. 360 [PubMed]

Altoè A, Pulkki V, Verhulst S. (2014). Transmission line cochlear models: improved accuracy and efficiency. The Journal of the Acoustical Society of America. 136 [PubMed]

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References and models cited by this paper

Catmull E, Rom R. (1974). A class of local interpolating splines Computer Aided Geometric Design.

Cohen-Schotanus J, Reinders JJ, Agsteribbe J, Meyboom-de Jong B. (2002). [Physicians for ten years: a longitudinal survey of the career development of physicians who began their studies in Groningen, the Netherlands]. Nederlands tijdschrift voor geneeskunde. 146 [PubMed]

DeRose TD, Barsky BA. (1988). Geometric continuity, shape parameters, and geometric constructions for catmull-rom splines ACM T. Graphic. 7

Diependaal RJ, Duifhuis H, Hoogstraten HW, Viergever MA. (1987). Numerical methods for solving one-dimensional cochlear models in the time domain. The Journal of the Acoustical Society of America. 82 [PubMed]

Dormand JR, Prince PJ. (1980). A family of embedded Runge-Kuttaformulae J Comput Appl Math. 6

Elliott SJ, Ku EM, Lineton B. (2007). A state space model for cochlear mechanics. The Journal of the Acoustical Society of America. 122 [PubMed]

Epp B, Verhey JL, Mauermann M. (2010). Modeling cochlear dynamics: interrelation between cochlea mechanics and psychoacoustics. The Journal of the Acoustical Society of America. 128 [PubMed]

Greenwood DD. (1961). Critical bandwidth and the frequency coordinates of the basilar membrane J. Acoust. Soc. Am.. 33

Moleti A, Paternoster N, Bertaccini D, Sisto R, Sanjust F. (2009). Otoacoustic emissions in time-domain solutions of nonlinear non-local cochlear models. The Journal of the Acoustical Society of America. 126 [PubMed]

Rapson MJ, Tapson JC, Karpul D. (2012). Unification and extension of monolithic state space and iterative cochlear models. The Journal of the Acoustical Society of America. 131 [PubMed]

Santurette S, Dau T, Oxenham AJ. (2012). On the possibility of a place code for the low pitch of high-frequency complex tones. The Journal of the Acoustical Society of America. 132 [PubMed]

Shera CA. (2001). Intensity-invariance of fine time structure in basilar-membrane click responses: implications for cochlear mechanics. The Journal of the Acoustical Society of America. 110 [PubMed]

Søndergaard P, Majdak P. (2013). The auditory modeling toolbox The Technology of Binaural Listening.

Takanen M, Santala O, Pulkki V. (2014). Visualization of functional count-comparison-based binaural auditory model output. Hearing research. 309 [PubMed]

Verhulst S. (2010). Characterizing and Modeling Dynamic Processes in the Cochlea Using Otoacoustic Emissions. Ph.D. thesis.

Verhulst S, Dau T, Shera CA. (2012). Nonlinear time-domain cochlear model for transient stimulation and human otoacoustic emission. The Journal of the Acoustical Society of America. 132 [PubMed]

Verhulst S, Mehraei G, Bharadwaj H, Shinn-Cunningham B. (2013). Understanding hearing impairment through model predictions of brainstem responses Proc. Meet. Acoust.. 19

Zweig G. (1991). Finding the impedance of the organ of Corti. The Journal of the Acoustical Society of America. 89 [PubMed]

References and models that cite this paper

Verhulst S, Altoè A, Vasilkov V. (2018). Computational modeling of the human auditory periphery: Auditory-nerve responses, evoked potentials and hearing loss. Hearing research. 360 [PubMed]

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See more from authors: Verhulst S · Dau T · Shera CA

References and models cited by this paper

Bialek W, Duifhuis H, Hoogstraten HW, Netten SM, van Diependaal RJ. (1985). Modelling the cochlear partition with coupled Van der Pol oscillators Peripheral Auditory Mechanisms.

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. The Journal of the Acoustical Society of America. 123 [PubMed]

Cohen-Schotanus J, Reinders JJ, Agsteribbe J, Meyboom-de Jong B. (2002). [Physicians for ten years: a longitudinal survey of the career development of physicians who began their studies in Groningen, the Netherlands]. Nederlands tijdschrift voor geneeskunde. 146 [PubMed]

Culling JF et al. (2011). Towards a binaural modelling toolbox Proceedings of Forum Acousticum.

Dau T, Wegner O, Mellert V, Kollmeier B. (2000). Auditory brainstem responses with optimized chirp signals compensating basilar-membrane dispersion. The Journal of the Acoustical Society of America. 107 [PubMed]

Diependaal RJ, Duifhuis H, Hoogstraten HW, Viergever MA. (1987). Numerical methods for solving one-dimensional cochlear models in the time domain. The Journal of the Acoustical Society of America. 82 [PubMed]

Duifhuis H. (2012). Springer Science & Business Media Cochlear Mechanics: Introduction to a Time Domain Analysis of the Nonlinear Cochlea.

Duifhuis H, van Netten SM. (1983). Modelling an active, nonlinear cochlea Mechanics of Hearing.

Elliott SJ, Ku EM, Lineton B. (2007). A state space model for cochlear mechanics. The Journal of the Acoustical Society of America. 122 [PubMed]

Epp B, Verhey JL, Mauermann M. (2010). Modeling cochlear dynamics: interrelation between cochlea mechanics and psychoacoustics. The Journal of the Acoustical Society of America. 128 [PubMed]

Gentle JE. (1998). Gaussian Elimination 3.1 Numerical Linear Algebra for Applications in Statistics.

Glasberg BR, Moore BC. (1990). Derivation of auditory filter shapes from notched-noise data. Hearing research. 47 [PubMed]

Greenwood DD. (1961). Critical bandwidth and the frequency coordinates of the basilar membrane J. Acoust. Soc. Am.. 33

Kalluri R, Shera CA. (2007). Near equivalence of human click-evoked and stimulus-frequency otoacoustic emissions. The Journal of the Acoustical Society of America. 121 [PubMed]

Kemp DT, Chum R. (1980). Properties of the generator of stimulated acoustic emissions. Hearing research. 2 [PubMed]

Liu YW, Neely ST. (2010). Distortion product emissions from a cochlear model with nonlinear mechanoelectrical transduction in outer hair cells. The Journal of the Acoustical Society of America. 127 [PubMed]

Moleti A, Paternoster N, Bertaccini D, Sisto R, Sanjust F. (2009). Otoacoustic emissions in time-domain solutions of nonlinear non-local cochlear models. The Journal of the Acoustical Society of America. 126 [PubMed]

Moore BC, Glasberg BR. (1983). Suggested formulae for calculating auditory-filter bandwidths and excitation patterns. The Journal of the Acoustical Society of America. 74 [PubMed]

Oxenham AJ, Shera CA. (2003). Estimates of human cochlear tuning at low levels using forward and simultaneous masking. Journal of the Association for Research in Otolaryngology : JARO. 4 [PubMed]

Pigasse G. (2008). Deriving cochlear delays in humans using otoacoustic emissions and auditory evoked potentials Ph.D. thesis,.

Prieve BA, Falter SR. (1995). COAEs and SSOAEs in adults with increased age. Ear and hearing. 16 [PubMed]

Probst R, Coats AC, Martin GK, Lonsbury-Martin BL. (1986). Spontaneous, click-, and toneburst-evoked otoacoustic emissions from normal ears. Hearing research. 21 [PubMed]

Puria S. (2003). Measurements of human middle ear forward and reverse acoustics: implications for otoacoustic emissions. The Journal of the Acoustical Society of America. 113 [PubMed]

Recio A, Rhode WS. (2000). Basilar membrane responses to broadband stimuli. The Journal of the Acoustical Society of America. 108 [PubMed]

Ren T. (2002). Longitudinal pattern of basilar membrane vibration in the sensitive cochlea. Proceedings of the National Academy of Sciences of the United States of America. 99 [PubMed]

Rhode WS, Recio A. (2000). Study of mechanical motions in the basal region of the chinchilla cochlea. The Journal of the Acoustical Society of America. 107 [PubMed]

Schairer KS, Ellison JC, Fitzpatrick D, Keefe DH. (2006). Use of stimulus-frequency otoacoustic emission latency and level to investigate cochlear mechanics in human ears. The Journal of the Acoustical Society of America. 120 [PubMed]

Shera CA. (2001). Intensity-invariance of fine time structure in basilar-membrane click responses: implications for cochlear mechanics. The Journal of the Acoustical Society of America. 110 [PubMed]

Shera CA, Dau T, Verhulst S, Harte JM. (2011). Can a static nonlinearity account for the dynamics of otoacoustic emission suppression? What Fire is in Mine Ears: Progress in Auditory Biomechanics, Proceedings of the 11th International Mechanics of Hearing Workshop.

Shera CA, Guinan JJ. (1999). Evoked otoacoustic emissions arise by two fundamentally different mechanisms: a taxonomy for mammalian OAEs. The Journal of the Acoustical Society of America. 105 [PubMed]

Shera CA, Guinan JJ. (2003). Stimulus-frequency-emission group delay: a test of coherent reflection filtering and a window on cochlear tuning. The Journal of the Acoustical Society of America. 113 [PubMed]

Shera CA, Guinan JJ, Oxenham AJ. (2002). Revised estimates of human cochlear tuning from otoacoustic and behavioral measurements. Proceedings of the National Academy of Sciences of the United States of America. 99 [PubMed]

Shera CA, Guinan JJ, Oxenham AJ. (2010). Otoacoustic estimation of cochlear tuning: validation in the chinchilla. Journal of the Association for Research in Otolaryngology : JARO. 11 [PubMed]

Shera CA, Tubis A, Talmadge CL. (2008). Testing coherent reflection in chinchilla: Auditory-nerve responses predict stimulus-frequency emissions. The Journal of the Acoustical Society of America. 124 [PubMed]

Shera CA, Zweig G. (1991). A symmetry suppresses the cochlear catastrophe. The Journal of the Acoustical Society of America. 89 [PubMed]

Talmadge CL, Tubis A, Long GR, Piskorski P. (1998). Modeling otoacoustic emission and hearing threshold fine structures. The Journal of the Acoustical Society of America. 104 [PubMed]

Verhulst S, Harte JM, Dau T. (2011). Temporal suppression of the click-evoked otoacoustic emission level-curve. The Journal of the Acoustical Society of America. 129 [PubMed]

Zweig G. (1990). The impedance of the organ of Corti Mechanics and Biophysics of Hearing, Lecture Notes in Biomathematics. 87

Zweig G. (1991). Finding the impedance of the organ of Corti. The Journal of the Acoustical Society of America. 89 [PubMed]

Zweig G, Shera CA. (1995). The origin of periodicity in the spectrum of evoked otoacoustic emissions. The Journal of the Acoustical Society of America. 98 [PubMed]

References and models that cite this paper

Altoè A, Pulkki V, Verhulst S. (2014). Transmission line cochlear models: improved accuracy and efficiency. The Journal of the Acoustical Society of America. 136 [PubMed]

Verhulst S, Altoè A, Vasilkov V. (2018). Computational modeling of the human auditory periphery: Auditory-nerve responses, evoked potentials and hearing loss. Hearing research. 360 [PubMed]

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