Neural correlates of the pitch of complex tones. I. Pitch and pitch salience

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Neural correlates of the pitch of complex tones. I. Pitch and pitch salience

P. A. Cariani and B. Delgutte
Department of Otology and Laryngology, Harvard Medical School, Boston, Massachusetts, USA.

1. The temporal discharge patterns of auditory nerve fibers in Dial-anesthetized cats were studied in response to periodic complex acoustic waveforms that evoke pitches at their fundamental frequencies. Single-formant vowels, amplitude-modulated (AM) and quasi-frequency-modulated tones. AM noise, click trains, and other complex tones were utilized. Distributions of intervals between successive spikes ("1st-order intervals") and between both successive and nonsuccessive spikes ("all-order intervals") were computed from spike trains. Intervals from many fibers were pooled to estimate interspike interval distributions for the entire auditory nerve. Properties of these "pooled interspike interval distributions," such as the positions of interval peaks and their relative heights, were examined for correspondence to the psychophysical data on pitch frequency and pitch salience. 2. For a diverse set of complex stimuli and levels, the most frequent all-order interspike interval present in the pooled distribution corresponded to the pitch heard in psychophysical experiments. Pitch estimates based on pooled interval distributions (30-85 fibers, 100 stimulus presentations per fiber) were highly accurate (within 1%) for harmonic stimuli that produce strong pitches at 60 dB SPL. 3. Although the most frequent intervals in pooled all-order interval distributions were very stable with respect to sound intensity level (40, 60, and 80 dB total SPL), this was not necessarily the case for first-order interval distributions. Because the low pitches of complex tones are largely invariant with respect to level, pitches estimated from all-order interval distributions correspond better to perception. 4. Spectrally diverse stimuli that evoke similar low pitches produce pooled interval distributions with similar most-frequent intervals. This suggests that the pitch equivalence of these different stimuli could result from central auditory processing mechanisms that analyze interspike interval patterns. 5. Complex stimuli that evoke strong or "salient" pitches produce pooled interval distributions with high peak-to-mean ratios. Those stimuli that evoke weak pitches produce pooled interval distributions with low peak-to-mean ratios. 6. Pooled interspike interval distributions for stimuli consisting of low-frequency components generally resembled the short-time auto-correlation function of stimulus waveforms. Pooled interval distributions for stimuli consisting of high-frequency components resembled the short-time autocorrelation function of the waveform envelope. 7. Interval distributions in populations of neurons constitute a general, distributed means of encoding, transmitting, and representing information. Existence of a central processor capable of analyzing these interval patterns could provide a unified explanation for many different aspects of pitch perception.

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				Y. Gai and L. H. Carney Temporal Measures and Neural Strategies for Detection of Tones in Noise Based on Responses in Anteroventral Cochlear Nucleus J Neurophysiol, November 1, 2006; 96(5): 2451 - 2464. [Abstract] [Full Text] [PDF]

				M. Chait, D. Poeppel, and J. Z. Simon Neural Response Correlates of Detection of Monaurally and Binaurally Created Pitches in Humans Cereb Cortex, June 1, 2006; 16(6): 835 - 848. [Abstract] [Full Text] [PDF]

				T. J. Gardner and M. O. Magnasco Sparse time-frequency representations PNAS, April 18, 2006; 103(16): 6094 - 6099. [Abstract] [Full Text] [PDF]

				S. M. N. Woolley, P. R. Gill, and F. E. Theunissen Stimulus-Dependent Auditory Tuning Results in Synchronous Population Coding of Vocalizations in the Songbird Midbrain J. Neurosci., March 1, 2006; 26(9): 2499 - 2512. [Abstract] [Full Text] [PDF]

				L. Cedolin and B. Delgutte Pitch of Complex Tones: Rate-Place and Interspike Interval Representations in the Auditory Nerve J Neurophysiol, July 1, 2005; 94(1): 347 - 362. [Abstract] [Full Text] [PDF]

				V. Neuert, J. L. Verhey, and I. M. Winter Temporal Representation of the Delay of Iterated Rippled Noise in the Dorsal Cochlear Nucleus J Neurophysiol, May 1, 2005; 93(5): 2766 - 2776. [Abstract] [Full Text] [PDF]

				C. Alain, K. Reinke, Y. He, C. Wang, and N. Lobaugh Hearing Two Things at Once: Neurophysiological Indices of Speech Segregation and Identification J. Cogn. Neurosci., May 1, 2005; 17(5): 811 - 818. [Abstract] [Full Text] [PDF]

				D. McAlpine Neural Sensitivity to Periodicity in the Inferior Colliculus: Evidence for the Role of Cochlear Distortions J Neurophysiol, September 1, 2004; 92(3): 1295 - 1311. [Abstract] [Full Text] [PDF]

				D. H. G. Louage, M. van der Heijden, and P. X. Joris Temporal Properties of Responses to Broadband Noise in the Auditory Nerve J Neurophysiol, May 1, 2004; 91(5): 2051 - 2065. [Abstract] [Full Text] [PDF]

				A. J. Oxenham, J. G. W. Bernstein, and H. Penagos From the Cover: Correct tonotopic representation is necessary for complex pitch perception PNAS, February 3, 2004; 101(5): 1421 - 1425. [Abstract] [Full Text] [PDF]

				M. G. Heinz, H. S. Colburn, and L. H. Carney Evaluating Auditory Performance Limits: I. One-Parameter Discrimination Using a Computational Model for the Auditory Nerve Neural Comput., October 1, 2001; 13(10): 2273 - 2316. [Abstract] [Full Text] [PDF]

				L. Wiegrebe and I. M. Winter Temporal Representation of Iterated Rippled Noise as a Function of Delay and Sound Level in the Ventral Cochlear Nucleus J Neurophysiol, March 1, 2001; 85(3): 1206 - 1219. [Abstract] [Full Text] [PDF]

				E. Salinas, A. Hernandez, A. Zainos, and R. Romo Periodicity and Firing Rate As Candidate Neural Codes for the Frequency of Vibrotactile Stimuli J. Neurosci., July 15, 2000; 20(14): 5503 - 5515. [Abstract] [Full Text] [PDF]

				B. S. Krishna and M. N. Semple Auditory Temporal Processing: Responses to Sinusoidally Amplitude-Modulated Tones in the Inferior Colliculus J Neurophysiol, July 1, 2000; 84(1): 255 - 273. [Abstract] [Full Text] [PDF]

				W. P. Shofner Responses of Cochlear Nucleus Units in the Chinchilla to Iterated Rippled Noises: Analysis of Neural Autocorrelograms J Neurophysiol, June 1, 1999; 81(6): 2662 - 2674. [Abstract] [Full Text] [PDF]

				N. L. Golding, M. J. Ferragamo, and D. Oertel Role of Intrinsic Conductances Underlying Responses to Transients in Octopus Cells of the Cochlear Nucleus J. Neurosci., April 15, 1999; 19(8): 2897 - 2905. [Abstract] [Full Text] [PDF]

				D. A. Bodnar and A. H. Bass Midbrain Combinatorial Code for Temporal and Spectral Information in Concurrent Acoustic Signals J Neurophysiol, February 1, 1999; 81(2): 552 - 563. [Abstract] [Full Text] [PDF]

				J. J. Eggermont Representation of Spectral and Temporal Sound Features in Three Cortical Fields of the Cat. Similarities Outweigh Differences J Neurophysiol, November 1, 1998; 80(5): 2743 - 2764. [Abstract] [Full Text] [PDF]

ARTICLES

Neural correlates of the pitch of complex tones. I. Pitch and pitch salience

				P. Heil and D. R.�F. Irvine First-Spike Timing of Auditory-Nerve Fibers and Comparison With Auditory Cortex J Neurophysiol, November 1, 1997; 78(5): 2438 - 2454. [Abstract] [Full Text] [PDF]

				D. A. Bodnar and A. H. Bass Temporal Coding of Concurrent Acoustic Signals in Auditory Midbrain J. Neurosci., October 1, 1997; 17(19): 7553 - 7564. [Abstract] [Full Text] [PDF]