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Cochlear structure
Known as:
EAR, COCHLEA
, Cochleas
, Cochlear part of bony labyrinth
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The part of the inner ear (LABYRINTH) that is concerned with hearing. It forms the anterior part of the labyrinth, as a snail-like structure that is…
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National Institutes of Health
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Related topics
Related topics
28 relations
Narrower (8)
Apex of cochlea
Basilar Membrane
Cochlear Diseases
Entire basis modioli
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Blood supply aspects
CDISC SEND Biospecimens Terminology
Cadherin-23
Clinical Data Interchange Standards Consortium Terminology
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Broader (2)
Bony labyrinth structure
Diseases of inner ear
Papers overview
Semantic Scholar uses AI to extract papers important to this topic.
Review
1999
Review
1999
Rescue and Regrowth of Sensory Nerves Following Deafferentation by Neurotrophic Factors
R. Altschuler
,
R. Altschuler
,
+5 authors
Josef M. Miller
Annals of the New York Academy of Sciences
1999
Corpus ID: 16417778
ABSTRACT: Trauma and loss of cochlear inner hair cells causes a series of events that result first in the retraction of the…
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Review
1998
Review
1998
The nitric oxide/cyclic GMP pathway: A potential major regulator of cochlear physiology
J. Fessenden
,
J. Schacht
Hearing Research
1998
Corpus ID: 24298214
Highly Cited
1997
Highly Cited
1997
Response of the primary auditory cortex to electrical stimulation of the auditory nerve in the congenitally deaf white cat
R. Hartmann
,
R. K. Shepherd
,
S. Heid
,
R. Klinke
Hearing Research
1997
Corpus ID: 4764389
Highly Cited
1993
Highly Cited
1993
Measuring human cochlear traveling wave delay using distortion product emission phase responses.
B. Kimberley
,
D. Brown
,
J. Eggermont
Journal of the Acoustical Society of America
1993
Corpus ID: 24311537
A method is presented here in which cochlear traveling wave delays are estimated through the measurement of distortion product…
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Highly Cited
1987
Highly Cited
1987
Acoustic distortion products in rabbit ear canal. I. Basic features and physiological vulnerability
B. Lonsbury-Martin
,
G. Martin
,
R. Probst
,
A. Coats
Hearing Research
1987
Corpus ID: 4703246
Highly Cited
1981
Highly Cited
1981
Relation of psychophysical data to histopathology in monkeys with cochlear implants.
B. Pfingst
,
D. Sutton
,
J. Miller
,
B. Bohne
Acta Oto-Laryngologica
1981
Corpus ID: 34926913
Psychophysical measures of threshold and dynamic range for electrical stimulation were made in macaque monkeys that had…
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Highly Cited
1981
Highly Cited
1981
Non‐linearities in the responses of turtle hair cells
A. Crawford
,
R. Fettiplace
Journal of Physiology
1981
Corpus ID: 26093175
1. Intracellular recordings were made from single cochlear hair cells in the isolated half‐head of the turtle. Receptor…
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Highly Cited
1980
Highly Cited
1980
Model for cochlear echoes and tinnitus based on an observed electrical correlate
J. P. Wilson
Hearing Research
1980
Corpus ID: 10981071
Highly Cited
1979
Highly Cited
1979
Cochlear action potential threshold and single unit thresholds.
J. R. Johnstone
,
V. Alder
,
Brian M. Johnstone
,
Donald Robertson
,
Graeme K. Yates
Journal of the Acoustical Society of America
1979
Corpus ID: 40985135
There is a close correlation between the sound pressure of tone burst required to affect a primary auditory neuron at its…
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Highly Cited
1975
Highly Cited
1975
The sharpening of cochlear frequency selectivity in the normal and abnormal cochlea.
E. Evans
Audiology
1975
Corpus ID: 38253695
In the normal (anaesthetized) animal cochlea, the frequency threshold curves for single primary fibres are up to an order of…
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