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1Biomedical Engineering Program and 2Department of Electrical and Computer Engineering, University of Connecticut, Storrs, Connecticut 06269-2157; and 3W. M. Keck Center for Integrative Neuroscience, University of California, San Francisco, California 94143
Submitted 25 September 2002; accepted in final form 3 March 2003
The spectro-temporal receptive field (STRF) is a model representation of
the excitatory and inhibitory integration area of auditory neurons. Recently
it has been used to study spectral and temporal aspects of monaural
integration in auditory centers. Here we report the properties of monaural
STRFs and the relationship between ipsi- and contralateral inputs to neurons
of the central nucleus of cat inferior colliculus (ICC) of cats. First, we use
an optimal singular-value decomposition method to approximate auditory STRFs
as a sum of time-frequency separable Gabor functions. This procedure extracts
nine physiologically meaningful parameters. The STRFs of 
60% of
collicular neurons are well described by a time-frequency separable Gabor STRF
model, whereas the remaining neurons exhibited obliquely oriented or multiple
excitatory/inhibitory subfields that require a nonseparable Gabor fitting
procedure. Parametric analysis reveals distinct spectro-temporal tradeoffs in
receptive field size and modulation filtering resolution. Comparisons between
an identical model used to study spatio-temporal integration areas of visual
neurons further shows that auditory and visual STRFs share numerous structural
properties. We then use the Gabor STRF model to compare quantitatively
receptive field properties of contra- and ipsilateral inputs to the ICC. We
show that most interaural STRF parameters are highly correlated bilaterally.
However, the spectral and temporal phases of ipsi- and contralateral STRFs
often differ significantly. This suggests that activity originating from each
ear share various spectro-temporal response properties such as their temporal
delay, bandwidth, and center frequency but have shifted or interleaved
patterns of excitation and inhibition. These differences in converging
monaural receptive fields expand binaural processing capacity beyond
interaural time and intensity aspects and may enable colliculus neurons to
detect disparities in the spectro-temporal composition of the binaural
input.
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