Noninvasive in vivo imaging reveals differences between tectorial membrane and basilar membrane traveling waves in the mouse cochlea. - Wikidata - awgldk - TriplyDB

Noninvasive in vivo imaging reveals differences between tectorial membrane and basilar membrane traveling waves in the mouse cochlea.

Noninvasive in vivo imaging reveals differences between tectorial membrane and basilar membrane traveling waves in the mouse cochlea.

http://www.wikidata.org/entity/Q30403242

about

Cochlear Outer-Hair-Cell Power Generation and Viscous Fluid Loss.Consequences of Location-Dependent Organ of Corti Micro-Mechanics.Non-invasive biophysical measurement of travelling waves in the insect inner ear Reticular lamina and basilar membrane vibrations in living mouse cochleae Experimental Visualization of Labyrinthine Structure with Optical Coherence Tomography.Two-Dimensional Cochlear Micromechanics Measured In Vivo Demonstrate Radial Tuning within the Mouse Organ of Corti.Finite-element model of the active organ of Corti.Hair cell force generation does not amplify or tune vibrations within the chicken basilar papilla.Minimal basilar membrane motion in low-frequency hearing Activity-dependent regulation of prestin expression in mouse outer hair cells Direct Intracochlear Acoustic Stimulation Using a PZT Microactuator.Investigation of middle ear anatomy and function with combined video otoscopy-phase sensitive OCT.Reverse transduction measured in the living cochlea by low-coherence heterodyne interferometry.Longitudinal spread of mechanical excitation through tectorial membrane traveling waves.Photothermal optical lock-in optical coherence tomography for in vivo imaging Optical Coherence Tomography to Measure Sound-Induced Motions Within the Mouse Organ of Corti In Vivo.Measurement of ciliary beat frequency using Doppler optical coherence tomography.Multimodal optical coherence tomography and fluorescence lifetime imaging with interleaved excitation sources for simultaneous endogenous and exogenous fluorescence.Multifrequency-swept optical coherence microscopy for highspeed full-field tomographic vibrometry in biological tissues.Intracochlear Scala Media Pressure Measurement: Implications for Models of Cochlear Mechanics.High-speed spectral calibration by complex FIR filter in phase-sensitive optical coherence tomography Neuroplastin Isoform Np55 Is Expressed in the Stereocilia of Outer Hair Cells and Required for Normal Outer Hair Cell Function.Mechanical tuning and amplification within the apex of the guinea pig cochlea.Two passive mechanical conditions modulate power generation by the outer hair cells.Two-Tone Suppression of Simultaneous Electrical and Mechanical Responses in the Cochlea.A Dual Probe and Two Tones Reveal Dual Waves in the Cochlea.Tectorial Membrane Traveling Waves Underlie Sharp Auditory Tuning in Humans.Hair Cell Transduction, Tuning, and Synaptic Transmission in the Mammalian Cochlea.ELHnet: a convolutional neural network for classifying cochlear endolymphatic hydrops imaged with optical coherence tomography.Negative-delay sources in distortion product otoacoustic emissions.Frequency-constrained robust principal component analysis: a sparse representation approach to segmentation of dynamic features in optical coherence tomography imaging.Simulating the Chan-Hudspeth experiment on an active excised cochlear segment.Geometric Requirements for Tectorial Membrane Traveling Waves in the Presence of Cochlear Loads.Order reduction and efficient implementation of nonlinear nonlocal cochlear response models.Signal competition in optical coherence tomography and its relevance for cochlear vibrometry.Hydrostatic measurement and finite element simulation of the compliance of the organ of Corti complex.Cochlear amplification and tuning depend on the cellular arrangement within the organ of Corti.Modeling Pitch Perception With an Active Auditory Model Extended by Octopus Cells Timing of the reticular lamina and basilar membrane vibration in living gerbil cochleae Vibration hotspots reveal longitudinal funneling of sound-evoked motion in the mammalian cochlea

P2860

Q27301390-838FCC33-A814-436E-BF30-A7BA2FF42B22 Q27302305-5A7ECC08-6D53-4030-BE7D-6A222A12E126 Q30355421-C32A0B8F-FCD2-4846-BF4F-9770DACFFBDB Q30362567-C6F96A1B-561B-422D-858F-D5D143B6A451 Q30362856-DE7043B8-390B-4705-960C-A68CF887B694 Q30364167-493166A7-C772-4E3D-9E0D-25ACB23EA6BF Q30364573-54DF3F48-2E70-4CF1-8700-B5E1F9E8A20F Q30369616-366205AD-22F3-47F7-9623-AD19BB744703 Q30377202-8857A352-1E4E-4809-AB1E-8D4A2F6C0591 Q30382444-1B5F2D20-50B0-4D26-86EC-C1FA2BDA19E2 Q30383128-D4D1F9D9-1A7E-4BD4-B9A6-2F8F87510206 Q30388407-67B20539-64F3-417E-907C-C6A5F361902A Q30389174-7930F3DD-A0DD-421E-858F-A5C402D14F08 Q30400110-D1079D6A-F972-4DC9-82C8-6EEB39EBAB5C Q30408505-A6037FE5-2294-4C07-AA80-ACF21BBEB970 Q33656129-1F8E3EAB-DB86-401B-BCFA-05B30144DDD9 Q35681393-19701503-5711-46CB-A0D2-ED5BAB08AC1E Q36152289-6F40F404-6720-4661-A734-68059E60FAE5 Q36300260-A61A2CE4-DFE9-4B77-AFA2-12972D368680 Q36426512-D8AE6FBD-EE39-4DD0-8064-FBA99CF1A594 Q37057634-BD534678-61BE-4FE5-AEF2-943C9DE5C18F Q37219083-40BC50F9-AAF6-4A7D-BAEA-384C0B54414D Q38850978-AC8D6476-CA11-4CE7-8814-E227446B0E6A Q41677036-C40425FC-3B6B-4D8C-AF49-D781285AF0E1 Q42381288-163F0FD2-11A9-46EB-9C3A-7D3315E40D0F Q42381308-5C642A0E-4C6F-4BD0-BF00-4AA38CB16A3F Q42396370-5BF7FB24-5B09-4DBA-B9AD-61838D4B84B1 Q42618413-6715AF8C-766C-417E-B545-8FC5F7D704A3 Q46734229-4CE150E4-1BF1-4D38-AC85-06C064FFFA1E Q47233075-8B78C031-D463-4317-8A34-C98C2CDF7013 Q47645127-D1A49E74-4A18-4E0D-991A-699BBA278848 Q47856393-9EE443BA-E7C2-47ED-AA08-EF5AE9765CDE Q50311292-F1D3EA60-6C25-4207-B4A3-11B9569FA1DB Q50315586-C4BCF0DA-AE28-4880-A4C7-1D0D7823CA17 Q51021841-F56698AA-46AA-4B18-B6FA-26E16991C132 Q52370611-15162BAA-E6FF-4726-8D64-424A0637DE0B Q55309435-9489F816-29B0-48A7-B18A-93C2FD4B4CE4 Q57492111-C157DF91-1AAE-4B50-BBB9-D6E04A50B3EB Q58763593-ABD21E21-1086-4DCA-9106-C797439F1550 Q58802439-5AEDF5B6-4DB1-404D-ACB8-6E10741AC0F8

P2860

Noninvasive in vivo imaging reveals differences between tectorial membrane and basilar membrane traveling waves in the mouse cochlea.

http://www.wikidata.org/entity/Q30403242

description

2015 nî lūn-bûn

@nan

2015 թուականի Մարտին հրատարակուած գիտական յօդուած

@hyw

2015 թվականի մարտին հրատարակված գիտական հոդված

@hy

2015年の論文

@ja

2015年論文

@yue

2015年論文

@zh-hant

2015年論文

@zh-hk

2015年論文

@zh-mo

2015年論文

@zh-tw

2015年论文

@wuu

name

Noninvasive in vivo imaging re ...... ng waves in the mouse cochlea.

@ast

Noninvasive in vivo imaging re ...... ng waves in the mouse cochlea.

@en

type

label

Noninvasive in vivo imaging re ...... ng waves in the mouse cochlea.

@ast

Noninvasive in vivo imaging re ...... ng waves in the mouse cochlea.

@en

prefLabel

Noninvasive in vivo imaging re ...... ng waves in the mouse cochlea.

@ast

Noninvasive in vivo imaging re ...... ng waves in the mouse cochlea.

@en

P1433

Q30403242-7CFC1F70-E1BF-487A-AEA2-6A65F8F6F5EE

P1476

Q30403242-F190425B-85BE-4706-943F-332ADA3DF141

P2093

Q30403242-1B11712B-2C7D-4745-8ADA-B05873015F7C

Q30403242-2CE22DD4-16EA-40C6-81E4-C5B7DD0F0FFA

Q30403242-8295DD26-925D-4EBF-9CD9-ACE73E59712A

Q30403242-9195F76C-9D09-4A77-A7CD-44076EDCDBB0

Q30403242-D3B797DA-A983-4A95-8C3B-8D3219A5BE8E

Q30403242-D4E845BE-E012-48A2-9F19-91A06786C2B2

P2860

Q30403242-02783DC5-2FD1-4C8C-8A1A-3E63E5323355

Q30403242-0D1A7C80-E458-4DBD-898F-8E6C8D128465

Q30403242-141E1DE9-04CC-44A1-9A17-89B2B1D0B022

Q30403242-14EA3474-23C5-48EF-A16E-544A1EEFF97E

Q30403242-19717E74-D621-454F-B446-939C5F01C2FF

Q30403242-1A31B3E4-9CCE-4020-8B8D-C4154FBBDF28

Q30403242-2498256A-B241-4EEF-A414-3E7C44665C7F

Q30403242-2C8C64A8-F930-4464-811F-E80B13B47851

Q30403242-3EEDF64C-86E5-4892-A2C1-28C9E9E7B04A

Q30403242-41EB8091-C0C0-4577-885B-6C68C83A85A0

P304

Q30403242-994EEC01-B8B6-4857-A18F-F23F31252E4D

P31

Q30403242-CE4C087A-A370-473E-89E4-18F7ED035C30

P356

Q30403242-0366685B-6591-4C4E-A99B-BB38D6FBFCC1

P407

Q30403242-2BC78C1E-664B-43AD-82A8-C4326595F1E5

P433

Q30403242-4D15C29E-991F-4C4D-92FA-5DD78D79A007

P478

Q30403242-9467A3F9-643D-40DA-AB7B-F5A84578F971

P577

Q30403242-4B972B3C-1E8B-4241-A393-C77A1D82277A

P5875

Q30403242-4D1DBB5B-3E85-4E4B-8A62-9FFB49ADCDF4

P698

Q30403242-7A0C8204-B729-4DB0-81DD-5BE9EB9B7F94

P932

Q30403242-CE1C5602-92E3-4331-8168-061502DF961A

P356

PNAS.1500038112

P1433

Proceedings of the National Academy of Sciences of the United States of America

P1476

Noninvasive in vivo imaging re ...... ng waves in the mouse cochlea.

@en

P2093

Audrey K Ellerbee

http://www.w3.org/2001/XMLSchema#string

Brian E Applegate

http://www.w3.org/2001/XMLSchema#string

Hee Yoon Lee

http://www.w3.org/2001/XMLSchema#string

Jesung Park

http://www.w3.org/2001/XMLSchema#string

John S Oghalai

http://www.w3.org/2001/XMLSchema#string

Patrick D Raphael

http://www.w3.org/2001/XMLSchema#string

P2860

A cochlear frequency-position function for several species--29 years later

Vibration of the organ of Corti within the cochlear apex in mice.

Filtering of acoustic signals within the hearing organ.

Frequency selectivity without resonance in a fluid waveguide

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

Prestin regulation and function in residual outer hair cells after noise-induced hearing loss.

Instrumentation for studies of cochlear mechanics: from von Békésy forward.

Subnanometer optical coherence tomographic vibrography.

The spatial pattern of cochlear amplification

Mechanics of the mammalian cochlea.

P304

3128-3133

http://www.w3.org/2001/XMLSchema#string

P31

scholarly article

P356

10.1073/PNAS.1500038112

http://www.w3.org/2001/XMLSchema#string

P407

P433

10

http://www.w3.org/2001/XMLSchema#string

P478

112

http://www.w3.org/2001/XMLSchema#string

P577

2015-03-03T00:00:00Z

http://www.w3.org/2001/XMLSchema#dateTime

P5875

273787151

http://www.w3.org/2001/XMLSchema#string

P698

25737536

http://www.w3.org/2001/XMLSchema#string

P932

4364183

http://www.w3.org/2001/XMLSchema#string