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Literature DB >> 21113779

Vestibular primary afferent responses to sound and vibration in the guinea pig.

Abstract

This study tested whether air-conducted sound and bone-conducted vibration activated primary vestibular afferent neurons and whether, at low levels, such stimuli are specific to particular vestibular sense organs. In response to 500 Hz bone-conducted vibration or 500 Hz air-conducted sound, primary vestibular afferent neurons in the guinea pig fall into one of two categories--some neurons show no measurable change in firing up to 2 g peak-to-peak or 140 dB SPL. These are semicircular canal neurons (regular or irregular) and regular otolith neurons. In sharp contrast, otolith irregular neurons show high sensitivity: a steep increase in firing as stimulus intensity is increased. These sensitive neurons typically, but not invariably, were activated by both bone-conducted vibration and air-conducted sound, they originate from both the utricular and saccular maculae, and their sensitivity underpins new clinical tests of otolith function.

Entities: Disease Species

Mesh：

Year: 2010 PMID： 21113779 DOI： 10.1007/s00221-010-2499-5

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

13 in total

1. Auditory brainstem responses, electrocochleograms, and cochlear microphonics in the myelin deficient mutant hamster 'bt'.

Authors: R Naito; T Murofushi; M Mizutani; K Kaga
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2. Attachment of the utricular and saccular maculae to the temporal bone.

Authors: Hilal Uzun-Coruhlu; Ian S Curthoys; Allan S Jones
Journal: Hear Res Date: 2007-08-25 Impact factor: 3.208

3. Physiological and anatomical study of click-sensitive primary vestibular afferents in the guinea pig.

Authors: T Murofushi; I S Curthoys
Journal: Acta Otolaryngol Date: 1997-01 Impact factor: 1.494

4. Three-dimensional analysis of the vestibular end organs in relation to the stapes footplate and piston placement.

Authors: Payal Mukherjee; Hilal Uzun-Coruhlu; Ian S Curthoys; Allan S Jones; Andrew P Bradshaw; David V Pohl
Journal: Otol Neurotol Date: 2011-04 Impact factor: 2.311

5. Responses of squirrel monkey vestibular neurons to audio-frequency sound and head vibration.

Authors: E D Young; C Fernández; J M Goldberg
Journal: Acta Otolaryngol Date: 1977 Nov-Dec Impact factor: 1.494

6. The vestibular nerve of the chinchilla. IV. Discharge properties of utricular afferents.

Authors: J M Goldberg; G Desmadryl; R A Baird; C Fernández
Journal: J Neurophysiol Date: 1990-04 Impact factor: 2.714

7. Acute seismic sensitivity in the bullfrog ear.

Authors: H Koyama; E R Lewis; E L Leverenz; R A Baird
Journal: Brain Res Date: 1982-10-28 Impact factor: 3.252

Review 8. A critical review of the neurophysiological evidence underlying clinical vestibular testing using sound, vibration and galvanic stimuli.

Authors: Ian S Curthoys
Journal: Clin Neurophysiol Date: 2009-11-07 Impact factor: 3.708

9. 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

10. The vertebrate ear as an exquisite seismic sensor.

Authors: P M Narins; E R Lewis
Journal: J Acoust Soc Am Date: 1984-11 Impact factor: 1.840

36 in total

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Authors: L Manzari; A M Burgess; H G Macdougall; I S Curthoys
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2. 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

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

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4. Sound-evoked vestibular stimulation affects the anticipation of gravity effects during visual self-motion.

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Journal: Exp Brain Res Date: 2015-05-24 Impact factor: 1.972

5. The quantal component of synaptic transmission from sensory hair cells to the vestibular calyx.

Authors: Stephen M Highstein; Mary Anne Mann; Gay R Holstein; Richard D Rabbitt
Journal: J Neurophysiol Date: 2015-04-15 Impact factor: 2.714

Review 6. How does high-frequency sound or vibration activate vestibular receptors?

Authors: I S Curthoys; J W Grant
Journal: Exp Brain Res Date: 2015-01-08 Impact factor: 1.972

7. Different effects of head tilt on ocular vestibular-evoked myogenic potentials in response to bone-conducted vibration and air-conducted sound.

Authors: Shinichi Iwasaki; Yasuhiro Chihara; Naoya Egami; Chisato Fujimoto; Toshihisa Murofushi; Tatsuya Yamasoba
Journal: Exp Brain Res Date: 2012-09-25 Impact factor: 1.972