Spatial Receptive Fields of Primary Auditory Cortical Neurons in Quiet and in the Presence of Continuous Background Noise

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Spatial Receptive Fields of Primary Auditory Cortical Neurons in Quiet and in the Presence of Continuous Background Noise

John F. Brugge, Richard A. Reale, and Joseph E. Hind

Department of Physiology and Waisman Center, University of Wisconsin, Madison, Wisconsin 53705

Brugge, John F., Richard A. Reale, and Joseph E. Hind. Spatial receptive fields of primary auditory cortical neuronsin quiet and in the presence of continuous background noise. J.Neurophysiol. 80: 2417-2432, 1998. Spatial receptive fields ofprimary auditory (AI) neurons were studied by delivering, binaurally,synthesized virtual-space signals via earphones to cats underbarbiturate anesthesia. Signals were broadband or narrowband transientspresented in quiet anechoic space or in acoustic space filledwith uncorrelated continuous broadband noise. In the absence ofbackground noise, AI virtual space receptive fields (VSRFs) aretypically large, representing a quadrant or more of acoustic space.Within the receptive field, onset latency and firing strengthform functional gradients. We hypothesized earlier that functionalgradients in the receptive field provide information about sound-sourcedirection. Previous studies indicated that spatial gradients couldremain relatively constant across changes in signal intensity.In the current experiments we tested the hypothesis that directionalsensitivity to a transient signal, as reflected in the gradientstructure of VSRFs of AI neurons, is also retained in the presenceof a continuous background noise. When background noise was introducedthree major affects on VSRFs were observed. 1) The size of theVSRF was reduced, accompanied by a reduction of firing strengthand lengthening of response latency for signals at an acousticaxis and on-lines of constant azimuth and elevation passing throughthe acoustic axis. These effects were monotonically related tothe intensity of the background noise over a noise intensity rangeof~30 dB. 2) The noise intensity-dependent changes in VSRFs weremirrored by the changes that occurred when the signal intensitywas changed in signal-alone conditions. Thus adding backgroundnoise was equivalent to a shift in the threshold of a directionalsignal, and this shift was seen across the spatial receptive field.3) The spatial gradients of response strength and latency remainedevident over the range of background noise intensity that reducedspike count and lengthened onset latency. Those gradients alongthe azimuth that spanned the frontal midline tended to remainconstant in slope and position in the face of increasing intensityof background noise. These findings are consistent with our hypothesisthat, under background noise conditions, information that underliesdirectional acuity and accuracy is retained within the spatialreceptive fields of an ensemble of AI neurons.

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