Large endolymphatic potentials from low-frequency and infrasonic tones in the guinea pig

Salt, Alec N.; Lichtenhan, Jeffery T.; Gill, Ruth; Hartsock, Jared J.

doi:10.1121/1.4789005

Cited by 35 publications

(45 citation statements)

References 41 publications

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“…Note that pre-injection CR dif,mid (pCM) amplitudes from inside scala media were much larger than from the round window: mean scala media 50 dB SPL = 478±90 1 μV from 15 measurements in three ears (five pre-injection measures from three ears) and mean round window 50 dB SPL =16±3 μV from 20 measurements in four ears. The large scala media/round window difference is consistent with Salt et al (2013). The consistency during TTX administration of CR dif,mid (pCM) from inside the scala media (Fig.…”

Section: The Stability Of a Variety Of Nonneural Measures Indicates Tsupporting

confidence: 58%

“…The average of B and C yields a waveform that oscillates at twice the frequency (D). This result is caused by the asymmetry of the response waveforms, seen as more saturation at negative potentials compared to positive in B and C. Lower: E is a Boltzmann inputoutput function (for equations, see Salt et al 2013) with parameters derived from fitting the measured response.…”

Section: On the Frequency Place Specificity Of The Ttx Injection Techmentioning

confidence: 99%

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The Auditory Nerve Overlapped Waveform (ANOW) Originates in the Cochlear Apex

Lichtenhan¹,

Hartsock²,

Gill³

et al. 2014

JARO

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Measurements of cochlear function with compound action potentials (CAPs), auditory brainstem responses, and otoacoustic emissions work well with high-frequency sounds but are problematic at low frequencies. We have recently shown that the auditory nerve overlapped waveform (ANOW) can objectively quantify low-frequency (G1 kHz) auditory sensitivity, as thresholds for ANOW at low frequencies and for CAP at high frequencies relate similarly to single auditory nerve fiber thresholds. This favorable relationship, however, does not necessarily mean that ANOW originates from auditory nerve fibers innervating low-frequency regions of the cochlear apex. In the present study, we recorded the cochlear response to tone bursts of low frequency (353, 500, and 707 Hz) and high frequency (2 to 16 kHz) during administration of tetrodotoxin (TTX) to block neural function. TTX was injected using a novel method of slow administration from a pipette sealed into the cochlear apex, allowing real-time measurements of systematic neural blocking from apex to base. The amplitude of phase-locked (ANOW) and onset (CAP) neural firing to moderate-level, low-frequency sounds were markedly suppressed before thresholds and responses to moderate-level, high-frequency sounds were affected. These results demonstrate that the ANOW originates from responses of auditory nerve fibers innervating cochlear apex, confirming that ANOW provides a valid physiological measure of low-frequency auditory nerve function.

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Section: The Stability Of a Variety Of Nonneural Measures Indicates Tsupporting

confidence: 58%

Section: On the Frequency Place Specificity Of The Ttx Injection Techmentioning

confidence: 99%

The Auditory Nerve Overlapped Waveform (ANOW) Originates in the Cochlear Apex

Lichtenhan¹,

Hartsock²,

Gill³

et al. 2014

JARO

View full text Add to dashboard Cite

show abstract

“…No data for human subjects are available, but, considering the higher sensitivity of humans for LF sounds, similar results can be expected (Salt et al 2013). Hirsh and Ward (1952) observed temporary deteriorations of human absolute thresholds about 2 min after presenting subjects with an intense, non-traumatic LF tone.…”

Section: Introductionsupporting

confidence: 63%

“…sound with frequencies lower than 250 Hz (Berglund et al 1996), has been considered to largely bypass the inner ear even at intense levels, simply because human hearing thresholds for frequencies below 250 Hz are relatively high. Recent evidence from animal models shows that physiological cochlear responses to LF sound are even larger than those evoked by equallevel, higher frequencies in the more sensitive range of hearing (Salt et al 2013).…”

Section: Introductionmentioning

confidence: 99%

Physiology, Psychoacoustics and Cognition in Normal and Impaired Hearing

Dijk¹,

Başkent²,

Gaudrain

et al. 2016

Advances in Experimental Medicine and Biology

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“…Therefore, several simultaneous inputs from many outer hair cells are required for type II-fiber firing, suggesting that the most effective stimulus would be that which maximally excites a broad cochlear length. Large outer-haircell potentials and broad cochlear displacement in response to infrasound and low-frequencies within the range of audibility (Salt et al 2013) suggest that type II fibers would fire most efficiently by such stimuli. While type II firing may be subconscious if evoked by sound from wind turbines, type II fibers innervate a region of the central auditory nervous system that extends to innervate regions responsible for, among other things, regulating attention, arousal, and pain/stress (Salt & Kaltenbach 2011;Kaltenbach & Godfrey 2008;Benson & Brown 2004;Brown et al 1988).…”

Section: Introductionmentioning

confidence: 99%