Literature DB >> 12433411

Tuning and timing in the gerbil ear: Wiener-kernel analysis.

Edwin R Lewis1, Kenneth R Henry, Walter M Yamada.   

Abstract

Information about the tuning and timing of excitation in cochlear axons with low-characteristic frequency (CF) is embodied in the first-order Wiener kernel, or reverse correlation function. For high-CF axons, the highest-ranking eigenvector (or singular vector) of the second-order Wiener kernel often can serve as a surrogate for the first-order kernel, providing the same information. For mid-CF axons, the two functions are essentially identical. In this paper we apply these tools to gerbil cochlear-nerve axons with CFs ranging from 700 Hz to 14 kHz. Eigen or singular-value decomposition of the second-order Wiener kernel allows us to separate excitatory and suppressive effects, and to determine precisely the timing of the latter.

Mesh:

Year:  2002        PMID: 12433411     DOI: 10.1016/s0378-5955(02)00695-0

Source DB:  PubMed          Journal:  Hear Res        ISSN: 0378-5955            Impact factor:   3.208


  13 in total

1.  Reverse correlation analysis of auditory-nerve fiber responses to broadband noise in a bird, the barn owl.

Authors:  Bertrand Fontaine; Christine Köppl; Jose L Peña
Journal:  J Assoc Res Otolaryngol       Date:  2014-10-15

2.  Wiener kernels of chinchilla auditory-nerve fibers: verification using responses to tones, clicks, and noise and comparison with basilar-membrane vibrations.

Authors:  Andrei N Temchin; Alberto Recio-Spinoso; Pim van Dijk; Mario A Ruggero
Journal:  J Neurophysiol       Date:  2005-01-19       Impact factor: 2.714

3.  Wiener-Volterra characterization of neurons in primary auditory cortex using poisson-distributed impulse train inputs.

Authors:  Martin Pienkowski; Greg Shaw; Jos J Eggermont
Journal:  J Neurophysiol       Date:  2009-03-25       Impact factor: 2.714

4.  Theoretical analysis of reverse-time correlation for idealized orientation tuning dynamics.

Authors:  Gregor Kovacic; Louis Tao; David Cai; Michael J Shelley
Journal:  J Comput Neurosci       Date:  2008-04-08       Impact factor: 1.621

5.  Multidimensional stimulus encoding in the auditory nerve of the barn owl.

Authors:  Brian J Fischer; Jacob L Wydick; Christine Köppl; José L Peña
Journal:  J Acoust Soc Am       Date:  2018-10       Impact factor: 1.840

6.  Emergence of band-pass filtering through adaptive spiking in the owl's cochlear nucleus.

Authors:  Bertrand Fontaine; Katrina M MacLeod; Susan T Lubejko; Louisa J Steinberg; Christine Köppl; Jose L Peña
Journal:  J Neurophysiol       Date:  2014-04-30       Impact factor: 2.714

7.  Divergent Auditory Nerve Encoding Deficits Between Two Common Etiologies of Sensorineural Hearing Loss.

Authors:  Kenneth S Henry; Mark Sayles; Ann E Hickox; Michael G Heinz
Journal:  J Neurosci       Date:  2019-07-08       Impact factor: 6.167

Review 8.  Effects of sensorineural hearing loss on temporal coding of narrowband and broadband signals in the auditory periphery.

Authors:  Kenneth S Henry; Michael G Heinz
Journal:  Hear Res       Date:  2013-01-29       Impact factor: 3.208

9.  Distorted Tonotopic Coding of Temporal Envelope and Fine Structure with Noise-Induced Hearing Loss.

Authors:  Kenneth S Henry; Sushrut Kale; Michael G Heinz
Journal:  J Neurosci       Date:  2016-02-17       Impact factor: 6.167

10.  Frequency response areas in the inferior colliculus: nonlinearity and binaural interaction.

Authors:  Jane J Yu; Eric D Young
Journal:  Front Neural Circuits       Date:  2013-05-10       Impact factor: 3.492
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