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Literature DB >> 22006305

Effect of instantaneous frequency glides on interaural time difference processing by auditory coincidence detectors.

Brian J Fischer¹, Louisa J Steinberg, Bertrand Fontaine, Romain Brette, Jose L Peña.

Abstract

Detecting interaural time difference (ITD) is crucial for sound localization. The temporal accuracy required to detect ITD, and how ITD is initially encoded, continue to puzzle scientists. A fundamental question is whether the monaural inputs to the binaural ITD detectors differ only in their timing, when temporal and spectral tunings are largely inseparable in the auditory pathway. Here, we investigate the spectrotemporal selectivity of the monaural inputs to ITD detector neurons of the owl. We found that these inputs are selective for instantaneous frequency glides. Modeling shows that ITD tuning depends strongly on whether the monaural inputs are spectrotemporally matched, an effect that may generalize to mammals. We compare the spectrotemporal selectivity of monaural inputs of ITD detector neurons in vivo, demonstrating that their selectivity matches. Finally, we show that this refinement can develop through spike timing-dependent plasticity. Our findings raise the unexplored issue of time-dependent frequency tuning in auditory coincidence detectors and offer a unifying perspective.

Mesh：

Year: 2011 PMID： 22006305 PMCID： PMC3207647 DOI： 10.1073/pnas.1108921108

Source DB: PubMed Journal: Proc Natl Acad Sci U S A ISSN： 0027-8424 Impact factor: 11.205

40 in total

Effect of instantaneous frequency glides on interaural time difference processing by auditory coincidence detectors.

1. Localization by interaural time difference (ITD): effects of interaural frequency mismatch.

2. Cochlear and neural delays for coincidence detection in owls.

3. Temporal map formation in the barn owl's brain.

4. A compressive gammachirp auditory filter for both physiological and psychophysical data.

5. Cell-specific, spike timing-dependent plasticities in the dorsal cochlear nucleus.

6. Tolerance to sound intensity of binaural coincidence detection in the nucleus laminaris of the owl.

7. On cochlear encoding: potentialities and limitations of the reverse-correlation technique.

8. Some effects of stimulus intensity on response of auditory nerve fibers in the squirrel monkey.

9. A circuit for detection of interaural time differences in the brain stem of the barn owl.

10. Cross-correlation in the auditory coincidence detectors of owls.

1. Sensory receptor diversity establishes a peripheral population code for stimulus duration at low intensities.

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

3. Binaural gain modulation of spectrotemporal tuning in the interaural level difference-coding pathway.

4. Predicting spike timing in highly synchronous auditory neurons at different sound levels.

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

6. Signal-to-noise ratio in the membrane potential of the owl's auditory coincidence detectors.

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

8. Predicting binaural responses from monaural responses in the gerbil medial superior olive.

9. Contribution of action potentials to the extracellular field potential in the nucleus laminaris of barn owl.

10. Effect of Stimulus-Dependent Spike Timing on Population Coding of Sound Location in the Owl's Auditory Midbrain.