Areas of
Interest:
Neuroscience
of the auditory system; computational neuroscience of single neurons
and neural
systems; otolaryngology research using otoacoustic emissions;
biomedical engineering.
Our research seeks to
integrate systems-neuroscience experimental investigations with
mathematical
modeling. Neurophysiological methods include single-unit recording of
neurons
in the auditory system of awake animals. Modeling methods include
digital
computer simulations at each of the following levels: ion channels,
synapses
distributed over the dendrites and soma, single neurons and
multi-neuron systems.
Localizing sounds is important to
humans and animals for basic functions such as escape from a threat,
capturing
a prey, and communication. Neural mechanisms for localizing sounds in
two-dimensions, horizontal (azimuth) and vertical (elevation) angles,
have been
studied extensively. In contrast, mechanisms responsible for
localization of
distance, the third spatial dimension, are poorly understood. A stimulus of any modality (auditory, visual
or tactile) presented at a close distance is particularly potent in
evoking a
defensive response. This suggests that the brains of humans and animals
can
recognize distance of a sensory stimulus (including sound) particularly
when
the stimulus is nearby.
The present study is
designed to break a new ground by investigating how the brain processes
auditory distance. Physiologically, we will measure how neurons in the
rabbit
midbrain encode auditory distance. The hypothesis
is that neurons of the inferior colliculus (IC) convey information
about
auditory distance based on a ratio of direct to reverberant signal
amplitudes
(D/R ratio). We have recorded binaural room impulse responses (BRIRs)
of the
rabbit in a reverberant acoustic chamber. Analysis of the BRIR acoustic
signals
indicate that D/R ratio systematically changes as a function of
auditory
distance. In this research, virtual sound fields (with a sound source
at a
variable location) will be created by combining BRIRs with a source
signal and
presented to the rabbit. Responses of single neurons in the midbrain of
unanesthetized rabbits will be recorded in response to virtual sound
fields.
Our preliminary observations indicate that the IC neurons exhibit
sensitivity
to auditory distance.
Schneider
DM, Moiseff A, Adulthood adaptive plasticity of the barn-owl auditory
localization system. Neural Engineering 2005, Conference Proceedings,
Inernational IEEE EMBS Conference,
pp 591-593, 2005, IEEE EMBS,
ISBN
0-7803-8710-4. Click to view the article.
Kim DO, Yang XM, Ye Y. A
subpopulation of dorsal raphe nucleus neurons retrogradely labeled with
cholera toxin-B injected into the inner ear. Experimental Brain
Research 153: 514-521, 2003. Click to view the article. Presented
at "Central
Auditory Processing - Integration of Auditory and Non-Auditory
Information" Meeting , Ascona, Switzerland, May 12-16, 2002.
Partcipants of the
Ascona
meeting.
(Click on the picture to enlarge it.)
Warr WB, Boche JEB, Ye Y, Kim DO. 2002. Organization
of olivocochlear neurons in the cat studied with
the
retrograde
tracer cholera toxin-B. J. Assoc. Res.
Otolar. 3: 457-478. Click to view the article .
Kim DO et al. Effects of the
medial
olivocochlear system on cochlear mechanics: Experimental and modeling
studies of DPOAE. Presented at
"Biophysics of the Cochlea" Meeting , Titisee, Germany, July,
2002. Published
in "Biophysics of the Cochlea", A.W. Gummer, Ed., World Scientific, New
Jersey,
pp 506-516. Click to view the article
.
Kim DO, Dorn PA, Neely ST, Gorga MP. 2001. Adaptation
of distortion product otoacoustic emission in humans. J.
Assoc. Res. Otolar. 2: 31-40. Click here to view the article .
Ye Y, Kim DO. 2001. Connections between the
dorsal
raphe nucleus and a hindbrain region consisting of the cochlear nucleus
and neighboring structures. Acta
Otolaryngol. 121: 284-288.
Click to view the article and figures .
Parham K, Sun XM, Kim DO. 2001. Noninvasive assessment of auditory function in mice: auditory brainstem response and distortion product otoacoustic emission. In Handbook of Mouse Auditory Research, JF Willott, Ed., CRC Press, pp 37-58. Click to view the article .
Pathmanathan JS, Kim DO. 2001. A
computational model for the AVCN marginal shell with medial
olivocochlear feedback: Generation of a wide dynamic range. Neurocomputing
38-40: 807-815. Click to view the
article .
Warr WB, Boche JEB, Ye Y, Kim DO. 2002. Organization
of olivocochlear neurons in the cat studied with
the
retrograde
tracer cholera toxin-B. J. Assoc. Res.
Otolar. 3: 457-478. Click to view the article .
Ye Y, Machado DG, Kim DO. 2000. Projection of the marginal shell of the anteroventral cochlear nucleus to olivocochlear neurons in the cat. J. Comp. Neurol. 420: 127-138. Click to viewthe article.
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