Literature DB >> 24606269

External and middle ear sound pressure distribution and acoustic coupling to the tympanic membrane.

Christopher Bergevin1, Elizabeth S Olson2.   

Abstract

Sound energy is conveyed to the inner ear by the diaphanous, cone-shaped tympanic membrane (TM). The TM moves in a complex manner and transmits sound signals to the inner ear with high fidelity, pressure gain, and a short delay. Miniaturized sensors allowing high spatial resolution in small spaces and sensitivity to high frequencies were used to explore how pressure drives the TM. Salient findings are: (1) A substantial pressure drop exists across the TM, and varies in frequency from ∼10 to 30 dB. It thus appears reasonable to approximate the drive to the TM as being defined solely by the pressure in the ear canal (EC) close to the TM. (2) Within the middle ear cavity (MEC), spatial variations in sound pressure could vary by more than 20 dB, and the MEC pressure at certain locations/frequencies was as large as in the EC. (3) Spatial variations in pressure along the TM surface on the EC-side were typically less than 5 dB up to 50 kHz. Larger surface variations were observed on the MEC-side.

Mesh:

Year:  2014        PMID: 24606269      PMCID: PMC3985947          DOI: 10.1121/1.4864475

Source DB:  PubMed          Journal:  J Acoust Soc Am        ISSN: 0001-4966            Impact factor:   1.840


  41 in total

1.  Middle-ear function with tympanic-membrane perforations. I. Measurements and mechanisms.

Authors:  S E Voss; J J Rosowski; S N Merchant; W T Peake
Journal:  J Acoust Soc Am       Date:  2001-09       Impact factor: 1.840

2.  Acoustic-structural coupled finite element analysis for sound transmission in human ear--pressure distributions.

Authors:  Rong Z Gan; Qunli Sun; Bin Feng; Mark W Wood
Journal:  Med Eng Phys       Date:  2005-08-24       Impact factor: 2.242

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Authors:  Michael E Ravicz; Elizabeth S Olson; John J Rosowski
Journal:  J Acoust Soc Am       Date:  2007-10       Impact factor: 1.840

4.  A hierarchy of examples illustrating the acoustic coupling of the eardrum.

Authors:  R D Rabbitt
Journal:  J Acoust Soc Am       Date:  1990-06       Impact factor: 1.840

5.  Mechanical properties of the frog ear: vibration measurements under free- and closed-field acoustic conditions.

Authors:  A C Pinder; A R Palmer
Journal:  Proc R Soc Lond B Biol Sci       Date:  1983-10-22

6.  Comparison of sound-transmission and cochlear-microphonic characteristics in Mongolian gerbil and guinea pig.

Authors:  R A Schmiedt; J J Zwislocki
Journal:  J Acoust Soc Am       Date:  1977-01       Impact factor: 1.840

7.  Forward and reverse transfer functions of the middle ear based on pressure and velocity DPOAEs with implications for differential hearing diagnosis.

Authors:  Ernst Dalhoff; Diana Turcanu; Anthony W Gummer
Journal:  Hear Res       Date:  2011-05-23       Impact factor: 3.208

8.  Ossicular motion related to middle ear transmission delay in gerbil.

Authors:  Ombeline de La Rochefoucauld; Puja Kachroo; Elizabeth S Olson
Journal:  Hear Res       Date:  2010-08-07       Impact factor: 3.208

9.  Wideband acoustic-reflex test in a test battery to predict middle-ear dysfunction.

Authors:  Douglas H Keefe; Denis Fitzpatrick; Yi-Wen Liu; Chris A Sanford; Michael P Gorga
Journal:  Hear Res       Date:  2009-09-20       Impact factor: 3.208

10.  Simultaneous 3D imaging of sound-induced motions of the tympanic membrane and middle ear ossicles.

Authors:  Ernest W Chang; Jeffrey T Cheng; Christof Röösli; James B Kobler; John J Rosowski; Seok Hyun Yun
Journal:  Hear Res       Date:  2013-06-28       Impact factor: 3.208
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  9 in total

1.  A study of sound transmission in an abstract middle ear using physical and finite element models.

Authors:  Antonio Gonzalez-Herrera; Elizabeth S Olson
Journal:  J Acoust Soc Am       Date:  2015-11       Impact factor: 1.840

2.  The path of a click stimulus from ear canal to umbo.

Authors:  Mario Milazzo; Elika Fallah; Michael Carapezza; Nina S Kumar; Jason H Lei; Elizabeth S Olson
Journal:  Hear Res       Date:  2017-01-11       Impact factor: 3.208

3.  Sound pressure distribution within natural and artificial human ear canals: forward stimulation.

Authors:  Michael E Ravicz; Jeffrey Tao Cheng; John J Rosowski
Journal:  J Acoust Soc Am       Date:  2014-12       Impact factor: 1.840

4.  Finite-Element Modelling of the Response of the Gerbil Middle Ear to Sound.

Authors:  Nima Maftoon; W Robert J Funnell; Sam J Daniel; Willem F Decraemer
Journal:  J Assoc Res Otolaryngol       Date:  2015-07-22

5.  Fluid-Structure Finite-Element Modelling and Clinical Measurement of the Wideband Acoustic Input Admittance of the Newborn Ear Canal and Middle Ear.

Authors:  Hamid Motallebzadeh; Nima Maftoon; Jacob Pitaro; W Robert J Funnell; Sam J Daniel
Journal:  J Assoc Res Otolaryngol       Date:  2017-07-18

6.  3D finite element model of the chinchilla ear for characterizing middle ear functions.

Authors:  Xuelin Wang; Rong Z Gan
Journal:  Biomech Model Mechanobiol       Date:  2016-01-19

7.  The impact of tympanic membrane perforations on middle ear transfer function.

Authors:  Michael Lauxmann; Dirk Beutner; Nicholas Bevis; Benjamin Sackmann; Thomas Effertz
Journal:  Eur Arch Otorhinolaryngol       Date:  2021-09-27       Impact factor: 3.236

8.  Forward and Reverse Middle Ear Transmission in Gerbil with a Normal or Spontaneously Healed Tympanic Membrane.

Authors:  Xiaohui Lin; Sebastiaan W F Meenderink; Glenna Stomackin; Timothy T Jung; Glen K Martin; Wei Dong
Journal:  J Assoc Res Otolaryngol       Date:  2021-02-16

9.  Influence of transient pressure changes on speech intelligibility: Implications for next-generation train travel.

Authors:  Daniel Rooney; Martin Wittkowski; Susanne Bartels; Sarah Weidenfeld; Daniel Aeschbach
Journal:  PLoS One       Date:  2020-04-23       Impact factor: 3.240
  9 in total

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