about
Maps of ITD in the nucleus laminaris of the barn owl.Reverse correlation analysis of auditory-nerve fiber responses to broadband noise in a bird, the barn owl.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.Emergence of band-pass filtering through adaptive spiking in the owl's cochlear nucleusSalient features of otoacoustic emissions are common across tetrapod groups and suggest shared properties of generation mechanisms.Tonotopic projections of the auditory nerve to the cochlear nucleus angularis in the barn owlEvidence for an auditory fovea in the New Zealand kiwi (Apteryx mantelli).The Binaural Interaction Component in Barn Owl (Tyto alba) Presents few Differences to Mammalian Data.Phase locking to high frequencies in the auditory nerve and cochlear nucleus magnocellularis of the barn owl, Tyto alba.Phylogenetic development of the cochlea and its innervation.Coding interaural time differences at low best frequencies in the barn owl.Inner-ear morphology of the New Zealand kiwi (Apteryx mantelli) suggests high-frequency specializationWhat have lizard ears taught us about auditory physiology?Molecular bases of K(+) secretory cells in the inner ear: shared and distinct features between birds and mammalsPlasticity in tinnitus patients: a role for the efferent auditory system?Evolution and development of hair cell polarity and efferent function in the inner ear.Frequency tuning and spontaneous activity in the auditory nerve and cochlear nucleus magnocellularis of the barn owl Tyto alba.In vivo Recordings from Low-Frequency Nucleus Laminaris in the Barn Owl.Efferent innervation to the auditory basilar papilla of scincid lizards.A quantitative study of cochlear afferent axons in birds.Quantitative anatomical basis for a model of micromechanical frequency tuning in the Tokay gecko, Gekko gecko.The basilar papilla of the barn owl Tyto alba: a quantitative morphological SEM analysis.Calcium modulates the frequency and amplitude of spontaneous otoacoustic emissions in the bobtail skink.Rate-intensity functions in the emu auditory nerve.Auditory nerve terminals in the cochlear nucleus magnocellularis: differences between low and high frequencies.Spontaneous generation in early sensory development. Focus on "spontaneous discharge patterns in cochlear spiral ganglion cells before the onset of hearing in cats".Activity of primary auditory neurons in the cochlear ganglion of the emu Dromaius novaehollandiae: spontaneous discharge, frequency tuning, and phase locking.Spontaneous otoacoustic emissions in two gecko species, Gekko gecko and Eublepharis macularius.Spontaneous otoacoustic emissions in the bobtail lizard. II: Interactions with external tones.Barn owls have ageless ears.Reversed tonotopic map of the basilar papilla in Gekko gecko.Contribution of action potentials to the extracellular field potential in the nucleus laminaris of barn owl.Auditory peripheral tuning: evidence for a simple resonance phenomenon in the lizard TiliquaA neural map of interaural intensity differences in the brain stem of the barn owlEfferent axons in the avian auditory nerveFine structure of the basilar papilla of the emu: implications for the evolution of avian hair-cell typesLow density of membrane particles in auditory hair cells of lizards and birds suggests an absence of somatic motilityAuditory neuroscience: how to encode microsecond differencesSpontaneous activity of auditory nerve fibers in the barn owl (Tyto alba): analyses of interspike interval distributions
P50
Q30380784-B1445918-8233-477B-9827-1B0BDA1C5371Q30392308-5D51990B-BBC2-433E-9033-B30960F9B2CEQ30397453-462908AE-B221-4269-B448-A5AA7A541B1EQ30403357-85E200A9-4393-4BE9-8426-E7230E9BF69AQ30406818-8A73F227-DDF4-4AFC-827E-B9A5795F47DBQ30416026-0A6EC07E-C46C-4230-8DEA-513C646641F6Q30473528-0528B135-01AA-456D-8D8E-7FA6E95E7560Q30474398-094C9E29-0403-48C6-B088-845E1FC80A9CQ31123690-55FF2615-DC7A-4C64-A0E7-A3FC085AA603Q34421012-F81CCAEF-8307-4750-9EA4-1EACFF286C2BQ34663605-90A8DB03-206A-456A-89DD-4E40EFEEC419Q35914575-3009D10B-1DD6-4323-B3CA-06B06EB71858Q36233204-3AFA4322-880D-409B-99D2-3B60F09DCD29Q36993527-41FA7F79-4A07-465C-9092-4CA4BE114CA1Q37294043-25B63180-D54C-4804-BF3B-9799AEEAFA1EQ38201276-5EA5840E-5D92-4313-BD27-38568573F431Q38207860-129814FD-58DC-49E4-BCCC-ABBE1333EB43Q38558412-D318341C-8804-4855-B7E0-A175E847E493Q40727983-A52DB5AF-B3EA-4167-ABA3-D548DFED4E15Q42456214-4159BA79-95EF-4696-AC00-AECA4D8C72CAQ42481312-49560DE4-8E93-4668-9B09-C866C18469E4Q42485577-2EDDE512-5A7D-42F4-9FF0-2B2DF7AE90DCQ42519405-63C52195-1DCF-46C2-86FF-A6AF774E7201Q44854874-BCF8A033-6CA5-4D57-9E31-921F313945A3Q46987864-987C862E-BC85-4F50-93D6-E34A00092752Q48189668-7B6E1CFD-D483-46C8-8CDB-259717EDCD93Q50456235-D6140BAE-711A-4823-AD04-88721FAE08AEQ50510335-34F1759B-1560-43C6-BA04-85CC785641FDQ50515552-57E2539F-180B-4DAD-ABE0-A03A74CF9081Q50526361-FDCD3944-B1E8-4C0A-9E7F-3368438630F5Q51795743-FD3804AB-1BC5-476E-A5AB-0174E538B0B1Q52213095-CFF0C8BA-12CB-43FC-A5BF-7EDED06699E5Q52708917-B7F58472-625D-4596-A398-82427DB1A4DEQ68451275-3B123DF2-1FB4-477F-AE0B-8E3FD52AB252Q68489650-2419B12D-B9CD-4F62-A10E-48F3498F1E90Q74013584-4802CC4D-5903-4B91-92A8-D29461F35D9BQ77745619-1DE9F5D2-8BA8-4B5F-B3C6-DC000761ECCBQ80796854-9CA1CDAE-8893-4DCE-BE51-4CCCFC57A6D7Q83332693-1E7A9516-BF82-43BD-A171-3BF3D1C61071Q83630193-A77B713F-4BE2-45B2-82CF-648C615B11AA
P50
description
hulumtuese
@sq
onderzoeker
@nl
researcher
@en
հետազոտող
@hy
name
Christine Köppl
@ast
Christine Köppl
@en
Christine Köppl
@es
Christine Köppl
@nl
type
label
Christine Köppl
@ast
Christine Köppl
@en
Christine Köppl
@es
Christine Köppl
@nl
prefLabel
Christine Köppl
@ast
Christine Köppl
@en
Christine Köppl
@es
Christine Köppl
@nl
P106
P21
P31
P496
0000-0003-0729-709X