This project will use extracellular electrophysiological recording to study the effects of background noise on the neural representation of pure tone stimuli. Neural responses will be measured in terms of average discharge rates for single units. Dynamic range properties of single-unit responses will be derived from measures of rate-level functions that are obtained in quiet and in the presence of continuous background noise. Dynamic range measures will be sampled in the dorsal cochlear nucleus, inferior colliculus and primary auditory cortex of behaving cats. Inhibitory mechanisms that shape the neural representation of tones in noise at each of these three levels of auditory processing will be described by frequency response maps, responses to bandpass noise, and responses to broad band noise with notched spectra. This research is based on independent observations that inhibitory influences increasingly reduce auditory responses to continuous noise at higher levels of the auditory system. A reduction in noise-driven activity potentially enhances the rate representation of signals that occur in the presence of background noise by decreasing the negative effects of noise adaptation The primary objectives of this proposal are to demonstrate changes in noise adaptation across three levels of auditory processing, to reveal neural inhibitory mechanisms that contribute to changes in noise-driven activity, and to measure the functional consequences of these changes in terms of the quality of neural representations for signals in noise. Although some of these objectives have been addressed in the nervous system of anesthetized and decerebrate cats, a comprehensive analysis of the neural encoding of pure tones in noisy environments has not been performed in behaving cats. Data obtained in behaving cats are critical to our understanding of noise adaptation because anesthesia substantially alters activity of descending efferent projections to the auditory periphery and inhibitory mechanisms at each subsequent level of auditory processing.

Project Start
1997-09-01
Project End
1998-08-31
Budget Start
1996-10-01
Budget End
1997-09-30
Support Year
8
Fiscal Year
1997
Total Cost
Indirect Cost
Name
Johns Hopkins University
Department
Type
DUNS #
045911138
City
Baltimore
State
MD
Country
United States
Zip Code
21218
Kanold, Patrick O; Davis, Kevin A; Young, Eric D (2011) Somatosensory context alters auditory responses in the cochlear nucleus. J Neurophysiol 105:1063-70
Davis, Kevin A (2005) Spectral processing in the inferior colliculus. Int Rev Neurobiol 70:169-205
Davis, Kevin A (2005) Contralateral effects and binaural interactions in dorsal cochlear nucleus. J Assoc Res Otolaryngol 6:280-96
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Peng, Grace C Y; Zee, David S; Minor, Lloyd B (2004) Phase-plane analysis of gaze stabilization to high acceleration head thrusts: a continuum across normal subjects and patients with loss of vestibular function. J Neurophysiol 91:1763-81
McKenna, George J; Peng, Grace C Y; Zee, David S (2004) Neck muscle vibration alters visually perceived roll in normals. J Assoc Res Otolaryngol 5:25-31
Rothman, Jason S; Manis, Paul B (2003) Kinetic analyses of three distinct potassium conductances in ventral cochlear nucleus neurons. J Neurophysiol 89:3083-96
Rothman, Jason S; Manis, Paul B (2003) Differential expression of three distinct potassium currents in the ventral cochlear nucleus. J Neurophysiol 89:3070-82
Rothman, Jason S; Manis, Paul B (2003) The roles potassium currents play in regulating the electrical activity of ventral cochlear nucleus neurons. J Neurophysiol 89:3097-113

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