Literature DB >> 25567092

How does high-frequency sound or vibration activate vestibular receptors?

I S Curthoys1, J W Grant.   

Abstract

The mechanism by which vestibular neural phase locking occurs and how it relates to classical otolith mechanics is unclear. Here, we put forward the hypothesis that sound and vibration both cause fluid pressure waves in the inner ear and that it is these pressure waves which displace the hair bundles on vestibular receptor hair cells and result in activation of type I receptor hair cells and phase locking of the action potentials in the irregular vestibular afferents, which synapse on type I receptors. This idea has been suggested since the early neural recordings and recent results give it greater credibility.

Mesh:

Year:  2015        PMID: 25567092     DOI: 10.1007/s00221-014-4192-6

Source DB:  PubMed          Journal:  Exp Brain Res        ISSN: 0014-4819            Impact factor:   1.972


  60 in total

1.  Effect of fluid forcing on vestibular hair bundles.

Authors:  J-H Nam; J R Cotton; J W Grant
Journal:  J Vestib Res       Date:  2005       Impact factor: 2.435

2.  Ocular vestibular evoked myogenic potentials (OVEMPs) produced by air- and bone-conducted sound.

Authors:  Neil P McAngus Todd; Sally M Rosengren; Swee T Aw; James G Colebatch
Journal:  Clin Neurophysiol       Date:  2006-12-01       Impact factor: 3.708

3.  Morphology of the membrana limitans.

Authors:  M Hara; R S Kimura
Journal:  Ann Otol Rhinol Laryngol       Date:  1993-08       Impact factor: 1.547

4.  Biomechanics of hair cell kinocilia: experimental measurement of kinocilium shaft stiffness and base rotational stiffness with Euler-Bernoulli and Timoshenko beam analysis.

Authors:  Corrie Spoon; Wally Grant
Journal:  J Exp Biol       Date:  2011-03-01       Impact factor: 3.312

5.  Tuning and timing in mammalian type I hair cells and calyceal synapses.

Authors:  Jocelyn E Songer; Ruth Anne Eatock
Journal:  J Neurosci       Date:  2013-02-20       Impact factor: 6.167

6.  Physiology of peripheral neurons innervating otolith organs of the squirrel monkey. III. Response dynamics.

Authors:  C Fernández; J M Goldberg
Journal:  J Neurophysiol       Date:  1976-09       Impact factor: 2.714

7.  Physiology of peripheral neurons innervating otolith organs of the squirrel monkey. II. Directional selectivity and force-response relations.

Authors:  C Fernández; J M Goldberg
Journal:  J Neurophysiol       Date:  1976-09       Impact factor: 2.714

8.  Acoustically responsive fibers in the vestibular nerve of the cat.

Authors:  M P McCue; J J Guinan
Journal:  J Neurosci       Date:  1994-10       Impact factor: 6.167

9.  Clinical, experimental, and theoretical investigations of the effect of superior semicircular canal dehiscence on hearing mechanisms.

Authors:  John J Rosowski; Jocelyn E Songer; Hideko H Nakajima; Kelly M Brinsko; Saumil N Merchant
Journal:  Otol Neurotol       Date:  2004-05       Impact factor: 2.311

10.  Ocular vestibular evoked myogenic potentials to bone conducted vibration of the midline forehead at Fz in healthy subjects.

Authors:  S Iwasaki; Y E Smulders; A M Burgess; L A McGarvie; H G Macdougall; G M Halmagyi; I S Curthoys
Journal:  Clin Neurophysiol       Date:  2008-07-17       Impact factor: 3.708
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  18 in total

1.  Low-intensity ultrasound activates vestibular otolith organs through acoustic radiation force.

Authors:  M M Iversen; D A Christensen; D L Parker; H A Holman; J Chen; M J Frerck; R D Rabbitt
Journal:  J Acoust Soc Am       Date:  2017-06       Impact factor: 1.840

2.  Parameters of skull vibration-induced nystagmus in normal subjects.

Authors:  Enrique García Zamora; Pedro Espírito-Santo Araújo; Vanesa Pérez Guillén; María Fernanda Vargas Gamarra; Victoria Fornés Ferrer; Magdalena Courel Rauch; Herminio Pérez Garrigues
Journal:  Eur Arch Otorhinolaryngol       Date:  2018-06-01       Impact factor: 2.503

3.  Intense noise exposure alters peripheral vestibular structures and physiology.

Authors:  C E Stewart; D S Bauer; A C Kanicki; R A Altschuler; W M King
Journal:  J Neurophysiol       Date:  2019-12-25       Impact factor: 2.714

Review 4.  Multiscale modeling of mechanotransduction in the utricle.

Authors:  Jong-Hoon Nam; J W Grant; M H Rowe; E H Peterson
Journal:  J Neurophysiol       Date:  2019-04-17       Impact factor: 2.714

5.  Frequency and phase effects on cervical vestibular evoked myogenic potentials (cVEMPs) to air-conducted sound.

Authors:  Sendhil Govender; Danielle L Dennis; James G Colebatch
Journal:  Exp Brain Res       Date:  2016-05-05       Impact factor: 1.972

Review 6.  The new vestibular stimuli: sound and vibration-anatomical, physiological and clinical evidence.

Authors:  Ian S Curthoys
Journal:  Exp Brain Res       Date:  2017-01-27       Impact factor: 1.972

7.  Perception of threshold-level whole-body motion during mechanical mastoid vibration.

Authors:  Rakshatha Kabbaligere; Charles S Layne; Faisal Karmali
Journal:  J Vestib Res       Date:  2018       Impact factor: 2.435

Review 8.  The Skull Vibration-Induced Nystagmus Test of Vestibular Function-A Review.

Authors:  Georges Dumas; Ian S Curthoys; Alexis Lion; Philippe Perrin; Sébastien Schmerber
Journal:  Front Neurol       Date:  2017-03-09       Impact factor: 4.003

9.  Embodied Medicine: Mens Sana in Corpore Virtuale Sano.

Authors:  Giuseppe Riva; Silvia Serino; Daniele Di Lernia; Enea Francesco Pavone; Antonios Dakanalis
Journal:  Front Hum Neurosci       Date:  2017-03-16       Impact factor: 3.169

Review 10.  Sustained and Transient Vestibular Systems: A Physiological Basis for Interpreting Vestibular Function.

Authors:  Ian S Curthoys; Hamish G MacDougall; Pierre-Paul Vidal; Catherine de Waele
Journal:  Front Neurol       Date:  2017-03-30       Impact factor: 4.003
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