Optimal electrical properties of outer hair cells ensure cochlear amplification

The organ of Corti (OC) is the auditory epithelium of the mammalian cochlea comprising sensory hair cells and supporting cells riding on the basilar membrane. The outer hair cells (OHCs) are cellular actuators that amplify small sound-induced vibrations for transmission to the inner hair cells. We d...

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Bibliographic Details
Published in:PloS one 2012-11, Vol.7 (11), p.e50572-e50572
Main Authors: Nam, Jong-Hoon, Fettiplace, Robert
Format: Article
Language:English
Subjects:
Amplification
Animals
Basilar Membrane - physiology
Biology
Channel gating
Cochlea
Computer simulation
Contractility
Electrical properties
Engineering
Epithelium
Finite Element Analysis
Finite element method
Gerbillinae
Hair
Hair cells
Hair Cells, Auditory, Outer - physiology
Kinematics
Mechanics
Mechanics (physics)
Membrane Potentials - physiology
Membrane proteins
Microscopy
Models, Theoretical
Motility
Organ of Corti
Organ of Corti - physiology
Outer hair cells
Phase shift
Sound
Time constant
Vibration
Vibration mode
Vibrations
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Summary:The organ of Corti (OC) is the auditory epithelium of the mammalian cochlea comprising sensory hair cells and supporting cells riding on the basilar membrane. The outer hair cells (OHCs) are cellular actuators that amplify small sound-induced vibrations for transmission to the inner hair cells. We developed a finite element model of the OC that incorporates the complex OC geometry and force generation by OHCs originating from active hair bundle motion due to gating of the transducer channels and somatic contractility due to the membrane protein prestin. The model also incorporates realistic OHC electrical properties. It explains the complex vibration modes of the OC and reproduces recent measurements of the phase difference between the top and the bottom surface vibrations of the OC. Simulations of an individual OHC show that the OHC somatic motility lags the hair bundle displacement by ∼90 degrees. Prestin-driven contractions of the OHCs cause the top and bottom surfaces of the OC to move in opposite directions. Combined with the OC mechanics, this results in ∼90 degrees phase difference between the OC top and bottom surface vibration. An appropriate electrical time constant for the OHC membrane is necessary to achieve the phase relationship between OC vibrations and OHC actuations. When the OHC electrical frequency characteristics are too high or too low, the OHCs do not exert force with the correct phase to the OC mechanics so that they cannot amplify. We conclude that the components of OHC forward and reverse transduction are crucial for setting the phase relations needed for amplification.
ISSN:1932-6203
1932-6203
DOI:10.1371/journal.pone.0050572