Published in Front Neurosci on July 18, 2017
Otoacoustic estimation of cochlear tuning: validation in the chinchilla. J Assoc Res Otolaryngol (2010) 2.32
Stimulus-frequency-emission group delay: a test of coherent reflection filtering and a window on cochlear tuning. J Acoust Soc Am (2003) 2.24
Intracellular labeling of auditory nerve fibers in guinea pig: central and peripheral projections. J Comp Neurol (1997) 1.91
Pathophysiology of Meniere's syndrome: are symptoms caused by endolymphatic hydrops? Otol Neurotol (2005) 1.74
Otoacoustic emissions, travelling waves and cochlear mechanisms. Hear Res (1986) 1.53
Measurement of the mechanical compliance of the endolymphatic compartments in the guinea pig. Hear Res (2000) 1.24
Calcium gradients in inner ear endolymph. Am J Otolaryngol (1990) 1.22
A new auditory threshold estimation technique for low frequencies: proof of concept. Ear Hear (2012) 1.22
Auditory nerve neurophonic recorded from the round window of the Mongolian gerbil. Hear Res (1995) 1.15
Distortion product otoacoustic emission phase and component analysis in human newborns. J Acoust Soc Am (2010) 1.10
Changes in Ca++ activity and DC potential in experimentally induced endolymphatic hydrops. Arch Otorhinolaryngol (1986) 1.09
Maturation and aging of the human cochlea: a view through the DPOAE looking glass. J Assoc Res Otolaryngol (2012) 1.07
Phase-locked responses to tones of chinchilla auditory nerve fibers: implications for apical cochlear mechanics. J Assoc Res Otolaryngol (2009) 1.06
The auditory nerve overlapped waveform (ANOW) originates in the cochlear apex. J Assoc Res Otolaryngol (2014) 1.05
Intraoperative round window recordings to acoustic stimuli from cochlear implant patients. Otol Neurotol (2012) 1.00
Effect of artificial endolymph injection into the cochlear duct on the endocochlear potential. Hear Res (1998) 0.99
Distinguishing hair cell from neural potentials recorded at the round window. J Neurophysiol (2013) 0.98
Variation in the phase of response to low-frequency pure tones in the guinea pig auditory nerve as functions of stimulus level and frequency. J Assoc Res Otolaryngol (2008) 0.98
Breaking away: violation of distortion emission phase-frequency invariance at low frequencies. J Acoust Soc Am (2011) 0.98
The influence of transducer operating point on distortion generation in the cochlea. J Acoust Soc Am (2004) 0.96
Effects of low-frequency biasing on otoacoustic and neural measures suggest that stimulus-frequency otoacoustic emissions originate near the peak region of the traveling wave. J Assoc Res Otolaryngol (2011) 0.93
Transient changes in cochlear potentials and DPOAEs after low-frequency tones: the 'two-minute bounce' revisited. Hear Res (1997) 0.92
Displacements of the organ of Corti by gel injections into the cochlear apex. Hear Res (2009) 0.91
Acute endolymphatic hydrops generated by exposure of the ear to nontraumatic low-frequency tones. J Assoc Res Otolaryngol (2004) 0.91
Endolymphatic hydrops and blood-labyrinth barrier in Ménière's disease. Acta Otolaryngol (2011) 0.90
Endolymph calcium increases with time after surgical induction of hydrops in guinea-pigs. Hear Res (1994) 0.90
Longitudinal endolymph flow associated with acute volume increase in the guinea pig cochlea. Hear Res (1997) 0.89
Electrocochleography in Cochlear Implant Recipients With Residual Hearing: Comparison With Audiometric Thresholds. Ear Hear (2016) 0.86
Quantification of the relation between electrophysiologic and morphologic changes in experimental endolymphatic hydrops. Ann Otol Rhinol Laryngol (1990) 0.84
Multiple indices of the 'bounce' phenomenon obtained from the same human ears. J Assoc Res Otolaryngol (2013) 0.84
Hydrops in the cochlea can be induced by sound as well as by static pressure. Hear Res (2000) 0.83
An analysis of cochlear response harmonics: Contribution of neural excitation. J Acoust Soc Am (2015) 0.83
Estimation of neural phase locking from stimulus-evoked potentials. J Assoc Res Otolaryngol (2014) 0.82
Cochlear potentials and their modulation by low-frequency sound in early endolymphatic hydrops. Hear Res (1988) 0.82
Low-frequency sound affects active micromechanics in the human inner ear. R Soc Open Sci (2014) 0.82
Calcium modulates the frequency and amplitude of spontaneous otoacoustic emissions in the bobtail skink. J Neurophysiol (2004) 0.82
Drug delivery into the cochlear apex: Improved control to sequentially affect finely spaced regions along the entire length of the cochlear spiral. J Neurosci Methods (2016) 0.81
Changes in cochlear function during acute endolymphatic hydrops development in guinea pigs. Hear Res (2012) 0.81
Auditory nerve frequency tuning measured with forward-masked compound action potentials. J Assoc Res Otolaryngol (2012) 0.80
Concurrent Acoustic Activation of the Medial Olivocochlear System Modifies the After-Effects of Intense Low-Frequency Sound on the Human Inner Ear. J Assoc Res Otolaryngol (2015) 0.79
Comparison of endolymph cross-sectional area measured histologically with that measured in vivo with an ionic volume marker. Ann Otol Rhinol Laryngol (1995) 0.79
Does BAPTA leave outer hair cell transduction channels closed? Hear Res (2007) 0.78
BAPTA induces frequency shifts in vivo of spontaneous otoacoustic emissions of the bobtail lizard. Audiol Neurootol (2005) 0.78
The effect of BAPTA and 4AP in scala media on transduction and cochlear gain. Hear Res (2005) 0.77
Endolymphatic hydrops in patients with tinnitus as the major symptom. Eur Arch Otorhinolaryngol (2013) 0.77
The effect of systemic administration of desmopressin on cochlear function in guinea pigs. Acta Otolaryngol (2013) 0.76
Low-frequency sound exposure causes reversible long-term changes of cochlear transfer characteristics. Hear Res (2015) 0.76
Long term effects of BAPTA in scala media on cochlear function. Hear Res (2007) 0.76
A new aspect in pathogenesis of experimental hydrops: role of calcium. Aviat Space Environ Med (1987) 0.76
Time course of endolymph volume increase in experimental hydrops measured in vivo with an ionic volume marker. Hear Res (1994) 0.76
Evidence for apical-basal transition in the delay of the reflection components of otoacoustic emissions. J Acoust Soc Am (2017) 0.76
Aftereffects of Intense Low-Frequency Sound on Spontaneous Otoacoustic Emissions: Effect of Frequency and Level. J Assoc Res Otolaryngol (2016) 0.75