Pitch of Complex Tones: Rate-Place and Interspike Interval Representations in the Auditory Nerve

Cedolin, Leonardo; Delgutte, Bertrand

doi:10.1152/jn.01114.2004

Cited by 75 publications

(132 citation statements)

References 82 publications

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“…Thus, the limits of tonotopic resolution illustrated in the model likely reflect peripheral limitations that are maintained throughout the tonotopic areas of the auditory pathways. This conclusion is supported by a recent study in the cat auditory nerve, which showed that the highest resolved harmonic varied from around the fifth at an f 0 of 200 Hz to around the 10th at an f 0 of 1000 Hz (Cedolin and Delgutte, 2005). Thus, even if human tuning is sharper than that found in cat by a factor of 2 (Shera et al, 2002), within our range of f 0 s (Ͻ 200 Hz) we would not expect harmonics above the 10th to be resolved in the auditory periphery or beyond.…”

Section: Methodssupporting

confidence: 74%

Human Cortical Activity during Streaming without Spectral Cues Suggests a General Neural Substrate for Auditory Stream Segregation

et al. 2007

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The brain continuously disentangles competing sounds, such as two people speaking, and assigns them to distinct streams. Neural mechanisms have been proposed for streaming based on gross spectral differences between sounds, but not for streaming based on other nonspectral features. Here, human listeners were presented with sequences of harmonic complex tones that had identical spectral envelopes, and unresolved spectral fine structure, but one of two fundamental frequencies ( f 0 ) and pitches. As the f 0 difference between tones increased, listeners perceived the tones as being segregated into two streams (one stream for each f 0 ) and cortical activity measured with functional magnetic resonance imaging and magnetoencephalography increased. This trend was seen in primary cortex of Heschl's gyrus and in surrounding nonprimary areas. The results strongly resemble those for pure tones. Both the present and pure tone results may reflect neuronal forward suppression that diminishes as one or more features of successive sounds become increasingly different. We hypothesize that feature-specific forward suppression subserves streaming based on diverse perceptual cues and results in explicit neural representations for auditory streams within auditory cortex.

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Section: Methodssupporting

confidence: 74%

Human Cortical Activity during Streaming without Spectral Cues Suggests a General Neural Substrate for Auditory Stream Segregation

et al. 2007

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“…Surprisingly, neural resolvability of double HCT harmonics in A1 is comparable with or greater than that observed in the auditory nerve of the anesthetized cat, where responses to HCTs tend to saturate at moderate to high stimulus levels (Cedolin and Delgutte, 2010). Despite their relatively high level in the present study (60 dB SPL per component), many of the lower harmonics of the double HCTs were well resolved in rate-place profiles.…”

Section: Discussionmentioning

confidence: 73%

“…Using a stimulus design employed in auditory nerve studies of pitch encoding (Cedolin and Delgutte, 2005;Larsen et al, 2008), the present study examined whether spectral and temporal information sufficient for extracting the F0s of two simultaneously presented HCTs, a prerequisite for their perceptual segregation, is available at the level of A1. F0s of the concurrent HCTs differed by 4 semitones, an amount sufficient for them to be reliably heard as two separate auditory objects with distinct pitches in human listeners (Assmann and Paschall, 1998;Micheyl and Oxenham, 2010).…”

Section: Discussionmentioning

confidence: 99%

“…Rate-place and temporal representations of double HCTs were evaluated using a stimulus design used in auditory-nerve studies of pitch encoding (Cedolin and Delgutte, 2005;Larsen et al, 2008) and in studies of neural responses to single HCTs in macaque auditory cortex . At each recording site, 89 double HCTs with variable F0s were presented in random order.…”

Section: Methodsmentioning

confidence: 99%

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Neural Representation of Concurrent Harmonic Sounds in Monkey Primary Auditory Cortex: Implications for Models of Auditory Scene Analysis

2014

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The ability to attend to a particular sound in a noisy environment is an essential aspect of hearing. To accomplish this feat, the auditory system must segregate sounds that overlap in frequency and time. Many natural sounds, such as human voices, consist of harmonics of a common fundamental frequency (F0). Such harmonic complex tones (HCTs) evoke a pitch corresponding to their F0. A difference in pitch between simultaneous HCTs provides a powerful cue for their segregation. The neural mechanisms underlying concurrent sound segregation based on pitch differences are poorly understood. Here, we examined neural responses in monkey primary auditory cortex (A1) to two concurrent HCTs that differed in F0 such that they are heard as two separate "auditory objects" with distinct pitches. We found that A1 can resolve, via a rate-place code, the lower harmonics of both HCTs, a prerequisite for deriving their pitches and for their perceptual segregation. Onset asynchrony between the HCTs enhanced the neural representation of their harmonics, paralleling their improved perceptual segregation in humans. Pitches of the concurrent HCTs could also be temporally represented by neuronal phaselocking at their respective F0s. Furthermore, a model of A1 responses using harmonic templates could qualitatively reproduce psychophysical data on concurrent sound segregation in humans. Finally, we identified a possible intracortical homolog of the "object-related negativity" recorded noninvasively in humans, which correlates with the perceptual segregation of concurrent sounds. Findings indicate that A1 contains sufficient spectral and temporal information for segregating concurrent sounds based on differences in pitch.

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“…For example, neither the sigmoidal shape of rate-level functions (firing rate as a function of stimulus SPL), their dynamic range, nor maximum firing rate, are dependent on stimulus frequency per se but on stimulus frequency relative to characteristic frequency (CF). This behavior, combined with cochlear band-pass filtering, underlies rate-place coding: spectral components are translated into a firing rate profile of the population of AN fibers (Cedolin and Delgutte 2005;). This is a tonotopic or "vertical" view of the audi-tory system in which strength of response along the tonotopic axis is proportional to spectral energy.…”

Section: An To Brain Stem: a Change In Orientationmentioning

confidence: 99%

Physiology, Psychoacoustics and Cognition in Normal and Impaired Hearing

Dijk¹,

Başkent²,

Gaudrain

et al. 2016

Advances in Experimental Medicine and Biology

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Pitch of Complex Tones: Rate-Place and Interspike Interval Representations in the Auditory Nerve

Cited by 75 publications

References 82 publications

Human Cortical Activity during Streaming without Spectral Cues Suggests a General Neural Substrate for Auditory Stream Segregation

Human Cortical Activity during Streaming without Spectral Cues Suggests a General Neural Substrate for Auditory Stream Segregation

Neural Representation of Concurrent Harmonic Sounds in Monkey Primary Auditory Cortex: Implications for Models of Auditory Scene Analysis

Physiology, Psychoacoustics and Cognition in Normal and Impaired Hearing

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