The peripheral auditory apparatus

Johnstone, Brian M.; Sellick, P.M.

doi:10.1017/s0033583500000032

Cited by 125 publications

(27 citation statements)

References 124 publications

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“…Nearly three decades ago, Johnstone and Sellick (Johnstone and Sellick, 1972) marshalled convincing evidence against the then prevailing view (e.g., Dallos, 1973;Møller, 1963Møller, , 1965Mundie, 1963;Zwislocki, 1962Zwislocki, , 1963 that mass is the principal determinant of ossicular vibrations at high frequencies (see also Manley and Johnstone, 1974). Nevertheless, several subsequent discussions of middle-ear function have reiterated the mass-reactance hypothesis (e.g., Doan et al, 1996;Hemilä et al, 1995Hemilä et al, , 2001Nummela, 1997;Relkin, 1988;Relkin and Saunders, 1980;Shaw, 1981).…”

Section: B Does Mass Reactance Control Middle-ear Transmission Of Himentioning

confidence: 99%

Development of wide-band middle ear transmission in the Mongolian gerbil

Overstreet

Ruggero

2002

The Journal of the Acoustical Society of America

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Stapes vibrations were measured in deeply anesthetized adult and neonatal (ages: 14 to 20 days) Mongolian gerbils. In adult gerbils, the velocity magnitude of stapes responses to tones was approximately constant over the entire frequency range of measurements, 1 to 40 kHz. Response phases referred to pressure near the tympanic membrane varied approximately linearly as a function of increasing stimulus frequency, with a slope corresponding to a group delay of 30 μs. In neonatal gerbils, the sensitivity of stapes responses to tones was lower than in adults, especially at midfrequencies (e.g., by about 15 dB at 10-20 kHz in gerbils aged 14 days). The input impedance of the adult gerbil cochlea, calculated from stapes vibrations and published measurements of pressure in scala vestibuli near the oval window [E. Olson, J. Acoust. Soc. Am. 103, 3445-3463 (1998)], is principally dissipative at frequencies lower than 10 kHz. Conclusions-(a)middle-ear vibrations in adult gerbils do not limit the input to the cochlea up to at least 40 kHz, i.e., within 0.5 oct of the high-frequency cutoff of the behavioral audiogram; and (b) the results in both adult and neonatal gerbils are inconsistent with the hypothesis that mass reactance controls high-frequency ossicular vibrations and support the idea that the middle ear functions as a transmission line.

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Section: B Does Mass Reactance Control Middle-ear Transmission Of Himentioning

confidence: 99%

Development of wide-band middle ear transmission in the Mongolian gerbil

Overstreet

Ruggero

2002

The Journal of the Acoustical Society of America

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“…2A. Second, the phase response in the transverse direction is no longer shallow and becomes consistent with traveling-wave motion (41 The major problem with the isolated temporal bone preparation is that the endocochlear potential was -0 mV, meaning that the electrical drive to the hair cells was about half of its normal in vivo value (48,49). The absence of an endocochlear potential might explain the linearity of the responses (50).…”

Section: Resultsmentioning

confidence: 99%

Resonant tectorial membrane motion in the inner ear: its crucial role in frequency tuning.

Gummer

Hemmert²,

Zenner³

1996

Proc. Natl. Acad. Sci. U.S.A.

218

160

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The tectorial membrane has long been postulated as playing a role in the exquisite sensitivity of the cochlea. In particular, it has been proposed that the tectorial membrane provides a second resonant system, in addition to that of the basilar membrane, which contributes to the amplification of the motion of the cochlear partition. Until now, technical difficulties had prevented vibration measurements of the tectorial membrane and, therefore, precluded direct evidence of a mechanical resonance. In the study reported here, the vibration of the tectorial membrane was measured in two orthogonal directions by using a novel method of combining laser interferometry with a photodiode technique. It is shown experimentally that the motion of the tectorial membrane is resonant at a frequency of 0.5 octave (oct) below the resonant frequency of the basilar membrane and polarized parallel to the reticular lamina. It is concluded that the resonant motion of the tectorial membrane is due to a parallel resonance between the mass of the tectorial membrane and the compliance of the stereocilia of the outer hair cells. Moreover, in combination with the contractile force of outer hair cells, it is proposed that inertial motion of the tectorial membrane provides the necessary conditions to allow positive feedback of mechanical energy into the cochlear partition, thereby amplifying and tuning the cochlear response.Understanding the micromechanical mechanisms underlying the extraordinary sensitivity of the cochlea is a cardinal goal of auditory physiology. It is generally agreed that motion of the tectorial membrane (TM) relative to the cuticular plate of a sensory hair cell stimulates transduction channels in its stereocilia-directly through physical contact to the TM of the longest stereocilia of the outer hair cells (OHCs) and indirectly by fluid motion around the stereocilia of the inner hair cells (1-5). Moreover, because OHCs undergo somatic length changes in response to electrical (6-8) and chemical (9) stimuli, OHCs and their stereocilia are supposed to feed mechanical energy back into the cochlear partition, thereby reducing its impedance (10-12). Therefore, the TM is expected to be functionally connected not only to the input of mechanoelectrical transducers in hair-cell stereocilia, but also to the output of electromechanical transducers in the OHC membrane. Technical difficulties have prevented measurements of TM vibration. Therefore, functional information has been inferred from morphological investigations (13-15), stiffness measurements post mortem (16) and in vivo (17), a physical model (18), mathematical models (5,10,11,(19)(20)(21)(22)(23)(24), together with the frequency tuning properties of evoked otoacoustic emissions (25, 26) and cochlear microphonic potentials (17). In general, the latter models (5,10,(18)(19)(20)(21)(22)(23)(24)(25)(26) require that the TM be mechanically resonant.The aim of the present study was to experimentally characterize the vibration response of the TM. This was achieved by deve...

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“…They were deprived of food but not water for [11][12][13][14][15][16][17][18] hr prior to study. They were anesthetized with an intraperitoneal injection of DIAL with urethane (0.9 g/kg of body weight).…”

Section: Methodsmentioning

confidence: 99%

“…By a direct stimulatory action on adenylate cyclase [ATP pyrophosphate-lyase (cyclizing), EC 4.6.1.1], cholera toxin produces secretion of isotonic fluid by the gut (11), the action being mimicked by agents that increase cellular cyclic AMP concentrations. Although the molecular mechanisms for fluid absorption and secretion are not known, it has been demonstrated that cyclic AMP can alter membrane permeability (2, 12) as well as membrane electrolyte secretion (4, 7).The stria vascularis is assumed to be the epithelia membrane responsible for the maintenance of the endolymphatic potential (EP) and endolymph secretion into the scala media of the cochlea (13,14).The present study was performed to demonstrate the presence and possible role of cyclic AMP in the stria vascularis by stimulating intracochlear adenylate cyclase with purified cholera toxin. The toxin had a significant effect on endolymph production, although it did not alter either endolymphatic potential or electrolyte composition.…”

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confidence: 99%

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Effects of cholera toxin on cochlear endolymph production: model for endolymphatic hydrops.

Feldman¹,

Brusilow²

1976

Proc. Natl. Acad. Sci. U.S.A.

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To evaluate a possible role for adenylate cyclase [ATP pyrophosphate-lyase (cyclizing), EC 4.6.1.11 and adenosine 3':5'-cyclic monophosphate in the secretion of endolymph, we studied the effect of an intra-scala media injection of purified cholera toxin (an adenylate cyclase stimulant) on cochlear endolymph volume, endolymphatic potential, and endolymphatic, Na and K concentrations. The endolymph volumes of animals injected with either deactivated cholera toxin or 0.15 M KCI were the same, and there was no difference in the endolymphatic potential in the control and treated groups. The increased endo-ymph volume suggests the resence of an active adenylate cyclase system in the scala media which may play a role in the formation of endolymph. Adenosine 3':5'-cyclic monophosphate (cyclic AMP) has been shown to be the intracellular mediator of salt and water absorption in the toad urinary bladder (1) and renal collecting tubules (2, 3). It has also been shown to enhance secretion from the intestinal epithelium (4), salivary glands (5), pancreas (6), and renal tubule (7). Cyclic AMP production has been stimulated by biogenic amines, many hormones (8), and purified cholera exotoxin (9, 10). By a direct stimulatory action on adenylate cyclase [ATP pyrophosphate-lyase (cyclizing), EC 4.6.1.1], cholera toxin produces secretion of isotonic fluid by the gut (11), the action being mimicked by agents that increase cellular cyclic AMP concentrations. Although the molecular mechanisms for fluid absorption and secretion are not known, it has been demonstrated that cyclic AMP can alter membrane permeability (2, 12) as well as membrane electrolyte secretion (4, 7).The stria vascularis is assumed to be the epithelia membrane responsible for the maintenance of the endolymphatic potential (EP) and endolymph secretion into the scala media of the cochlea (13,14).The present study was performed to demonstrate the presence and possible role of cyclic AMP in the stria vascularis by stimulating intracochlear adenylate cyclase with purified cholera toxin. The toxin had a significant effect on endolymph production, although it did not alter either endolymphatic potential or electrolyte composition. MATERIALS AND METHODSExperiments were performed on guinea pigs (Hartley strain) weighing between 150 and 300 g that were allowed free access to food and water. They were deprived of food but not water for 11-18 hr prior to study. They were anesthetized with an intraperitoneal injection of DIAL with urethane (0.9 g/kg of body weight). A tracheostomy was performed and artificial ventilation was maintained by positive pressure ventilation. The animals were placed on a warmer and the electrocardiogram was constantly monitored. After a ventromedial incision in the neck and removal of the posterior portion of the mandible, the auditory bulla was exposed and removed. The basilar membrane of the first turn of the cochlea was exposed after removal of the round window membrane (15).An initial endolymphatic potential measurement was made using a si...

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The peripheral auditory apparatus

Cited by 125 publications

References 124 publications

Development of wide-band middle ear transmission in the Mongolian gerbil

Development of wide-band middle ear transmission in the Mongolian gerbil

Resonant tectorial membrane motion in the inner ear: its crucial role in frequency tuning.

Effects of cholera toxin on cochlear endolymph production: model for endolymphatic hydrops.

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