Asymmetric excitatory synaptic dynamics underlie interaural time difference processing in the auditory system.
about
The natural history of sound localization in mammals--a story of neuronal inhibition.Predicting binaural responses from monaural responses in the gerbil medial superior olive.Neuronal coupling by endogenous electric fields: cable theory and applications to coincidence detector neurons in the auditory brain stem.Physiology and anatomy of neurons in the medial superior olive of the mouse.High-Frequency Resonance in the Gerbil Medial Superior Olive.Maps of interaural delay in the owl's nucleus laminaris.Behavior and modeling of two-dimensional precedence effect in head-unrestrained catsRoles for Coincidence Detection in Coding Amplitude-Modulated Sounds.A functional circuit model of interaural time difference processingChange in the coding of interaural time difference along the tonotopic axis of the chicken nucleus laminaris.In vivo coincidence detection in mammalian sound localization generates phase delays.On the localization of complex sounds: temporal encoding based on input-slope coincidence detection of envelopesNeural tuning matches frequency-dependent time differences between the earsA model of the medial superior olive explains spatiotemporal features of local field potentials.Directional hearing by linear summation of binaural inputs at the medial superior oliveA mechanistic understanding of the role of feedforward inhibition in the mammalian sound localization circuitry.Glycinergic inhibition tunes coincidence detection in the auditory brainstem.Glycinergic transmission modulates GABAergic inhibition in the avian auditory pathway.Biophysical basis of the sound analog membrane potential that underlies coincidence detection in the barn owl.Signal-to-noise ratio in the membrane potential of the owl's auditory coincidence detectors.Frequency-invariant representation of interaural time differences in mammals.Microseconds matter.Phasic Firing and Coincidence Detection by Subthreshold Negative Feedback: Divisive or Subtractive or, Better, Both.Ionic mechanisms of microsecond-scale spike timing in single cells.Impact of fast sodium channel inactivation on spike threshold dynamics and synaptic integration.Nonlinear Dynamics of Neuronal Excitability, Oscillations, and Coincidence Detection.An essential role for modulation of hyperpolarization-activated current in the development of binaural temporal precisionSound localization: Jeffress and beyondTonotopic organization of the hyperpolarization-activated current (Ih) in the mammalian medial superior olive.ON and OFF inhibition as mechanisms for forward masking in the inferior colliculus: a modeling study.Theoretical foundations of the sound analog membrane potential that underlies coincidence detection in the barn owl.Modulation of synaptic input by GABAB receptors improves coincidence detection for computation of sound location.Frequency-dependent interaural delays in the medial superior olive: implications for interaural cochlear delays.Extraction of Inter-Aural Time Differences Using a Spiking Neuron Network Model of the Medial Superior Olive.
P2860
Q28655199-777213A7-38A6-4CF2-9657-AC4F1D20CF54Q30355234-4DC5AAA8-DCAA-4D8D-A055-34295901B6CFQ30359886-4C4E5314-5263-40DB-B937-39361D7098E3Q30367755-8CF8ECFE-9BB7-46DB-A820-E26010879671Q30368272-DD56DB5E-F63F-4ABC-8C6E-9876FF13541EQ30375350-A1EEAB85-3224-4D34-A6F6-F0793AC635E3Q30377818-102E9636-41F1-49AB-9CEF-77442CC1BAA9Q30378767-36B9F264-A9D2-4AD5-A584-6637EBF88F7DQ30397453-B825489F-B946-4C1F-A7E0-E0B9328A4733Q30403357-1C7D7EA6-C890-4CA0-A389-AFB39B913CF0Q30403964-7A7A6F29-F77E-4EE5-8983-225372E8BE9CQ30404867-25C272CF-6894-4239-9E02-2E82CA63105BQ30411139-81E7F2B1-D624-4863-8E45-5340EAAE0D27Q30417924-1E1E5DBF-FCA5-4DAF-AC42-DD35FD145665Q30437226-258CB6F7-4736-45EB-9162-08FEDA141ABDQ30437230-B73DA5A1-9960-4618-AC6E-3005B27E9BA5Q30438318-83845777-D5E4-4BFE-80A8-95356A9EAC40Q30441255-8E13B954-D684-4451-8450-236D32EF94A6Q30446932-099A59A6-E696-4559-80F3-5A9EE3987C9AQ30447167-49819B26-7BB4-422A-9F14-F60A2701670AQ30476189-8688C824-1069-4849-9D5C-E680D77F112BQ30480626-2ED9C368-BA3E-4D26-9B5D-57EEBE70CF0CQ30837178-28CB57F4-B8D3-4E5D-9F7D-ED464A5BE221Q33575220-BF653947-6982-4D36-A1D0-66DBACE00835Q33900820-FAE97785-8E3C-4853-8951-57D449C125BBQ34479283-1D16D86E-EBE2-4C87-BFB0-207D5DC3BC1DQ35929816-EB2A1E2F-47B5-4DEB-8EF4-DC487A312748Q37885554-AEBFF653-09DB-4EB4-901F-B77F08452D38Q41993747-B39A5EF2-6D46-48B6-8DB4-1C6F22D2A548Q42175443-89421900-E0E4-49ED-A9A6-1E03508EE46AQ42917592-AD40D54D-7C91-4BF2-A944-B874B30AC2C2Q48585207-8B371B0E-89A9-401A-AE0B-B48D3D20EC58Q49027535-B4757384-37BF-4EB4-881D-BC7DA73457B3Q52348517-53933A3C-58D2-45A6-B8E9-10A054E9427F
P2860
Asymmetric excitatory synaptic dynamics underlie interaural time difference processing in the auditory system.
description
2010 nî lūn-bûn
@nan
2010 թուականի Յունիսին հրատարակուած գիտական յօդուած
@hyw
2010 թվականի հունիսին հրատարակված գիտական հոդված
@hy
2010年の論文
@ja
2010年論文
@yue
2010年論文
@zh-hant
2010年論文
@zh-hk
2010年論文
@zh-mo
2010年論文
@zh-tw
2010年论文
@wuu
name
Asymmetric excitatory synaptic ...... essing in the auditory system.
@ast
Asymmetric excitatory synaptic ...... essing in the auditory system.
@en
type
label
Asymmetric excitatory synaptic ...... essing in the auditory system.
@ast
Asymmetric excitatory synaptic ...... essing in the auditory system.
@en
prefLabel
Asymmetric excitatory synaptic ...... essing in the auditory system.
@ast
Asymmetric excitatory synaptic ...... essing in the auditory system.
@en
P2093
P2860
P1433
P1476
Asymmetric excitatory synaptic ...... cessing in the auditory system
@en
P2093
Dan H Sanes
Gytis Svirskis
John Rinzel
Vibhakar C Kotak
P2860
P304
P356
10.1371/JOURNAL.PBIO.1000406
P407
P50
P577
2010-06-29T00:00:00Z