Coding of Sound Intensity in the Chick Cochlear Nerve

doi:10.1152/jn.00381.2002

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Coding of Sound Intensity in the Chick Cochlear Nerve

James C. Saunders,¹ Corey E. Ventetuolo,¹ Stefan K.-R. Plontke,² and Burton A. Weiss³

¹Department of Otorhinolaryngology, Head and Neck Surgery, University of Pennsylvania, Philadelphia, Pennsylvania 19104; ²Hearing Research Center and Department of Otorhinolaryngology, Head and Neck Surgery, University of Tuebingen, D-72076 Tuebingen, Germany; and ³Liberal Arts Division, University of the Arts, Philadelphia, Pennsylvania 19104

Saunders, James C., Corey E. Ventetuolo, Stefan K.-R. Plontke, and Burton A. Weiss. Coding of Sound Intensity in the Chick Cochlear Nerve. J. Neurophysiol. 88: 2887-2898, 2002. Tuning curves, spontaneous activity, and rate-intensity (RI) functions were obtained from units in the chick cochlear nerve.The characteristic frequency (CF) was determined from each tuningcurve. The shape of each RI function was subjectively evaluatedand assigned to one of four RI types. The breakpoint, dischargerate at the highest SPLs, and slopes of the primary and secondarysegments were quantified for each function. The CF and RI typewere then related to these variables. A new RI function was observedin which the discharge activity in the secondary segment diminishedas stimulus level increased above the breakpoint. This functionwas called a "sloping-down" type. In 959 units, saturating, sloping-up,sloping-down, and straight RI types were identified in 39.2, 35.5,12.6, and 12.7% of the sample, respectively. The slope of theprimary segment was nearly the same in each of the four typesand averaged 5.48 S · s¹ · dB¹ across all units. The slopes of the secondary segments formedfour groupings when segregated by RI type based on the subjectiveassignments and averaged 0.03, 1.22, $-$ 0.90, and 3.95 S · s¹ · dB¹ in the saturating, sloping-up, sloping-down, and straight types,respectively. The data describing the secondary segments of allunits were fit with a multi-compartment polynomial and showeda continuous distribution that segregated, with some overlap,into the different RI categories. The proportion of RI types,as well as the secondary and primary slopes were approximatelyconstant across CFs. In addition, it would appear that the otherparameters that define the four types were, for the most part,homogeneously distributed across the frequency axis of the chickinner ear. Finally, a comparison of RI functions having a commonCF suggested that the compressive nonlinearity that determinesRI type may be a phenomenon localized to individual hair cellsin the birdear.

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