Sequence learning modulates neural responses and oscillatory coupling in human and monkey auditory cortex

Kikuchi, Y.; Attaheri, Adam; Wilson, Benjamin; Rhone, Ariane E.; Nourski, Kirill V.; Gander, Phillip E.; Kovach, Christopher K.; Kawasaki, Hiroto; Griffiths, Timothy D.; Howard, Matthew A.; Petkov, Christopher I.

doi:10.1371/journal.pbio.2000219

Cited by 60 publications

(72 citation statements)

References 92 publications

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“…Sensitivity to the sequential order in which sounds occur could be a functional property that characterizes high-level auditory regions. However, very few studies have examined neuronal responses to changes in the ordering relationships of elements within sequences by recording single-unit activity in the auditory cortex of mammalian species (Weinberger and McKenna, 1988;McKenna et al, 1989;Kikuchi et al, 2017).…”

Section: Non-linear Processingmentioning

confidence: 99%

Neuronal Encoding in a High-Level Auditory Area: From Sequential Order of Elements to Grammatical Structure

et al. 2019

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Sensitivity to the sequential structure of communication sounds is fundamental not only for language comprehension in humans but also for song recognition in songbirds. By quantifying single-unit responses, we first assessed whether the sequential order of song elements, called syllables, in conspecific songs is encoded in a secondary auditory cortex-like region of the zebra finch brain. Based on a habituation/ dishabituation paradigm, we show that, after multiple repetitions of the same conspecific song, rearranging syllable order reinstated strong responses. A large proportion of neurons showed sensitivity to song context in which syllables occurred providing support for the nonlinear processing of syllable sequences. Sensitivity to the temporal order of items within a sequence should enable learning its underlying structure, an ability considered a core mechanism of the human language faculty. We show that repetitions of songs that were ordered according to a specific grammatical structure (i.e., ABAB or AABB structures; A and B denoting song syllables) led to different responses in both anesthetized and awake birds. Once responses were decreased due to song repetitions, the transition from one structure to the other could affect the firing rates and/or the spike patterns. Our results suggest that detection was based on local differences rather than encoding of the global song structure as a whole. Our study demonstrates that a high-level auditory region provides neuronal mechanisms to help discriminate stimuli that differ in their sequential structure.Sequence processing has been proposed as a potential precursor of language syntax. As a sequencing operation, the encoding of the temporal order of items within a sequence may help in recognition of relationships between adjacent items and in learning the underlying structure. Taking advantage of the stimulus-specific adaptation phenomenon observed in a high-level auditory region of the zebra finch brain, we addressed this question at the neuronal level. Reordering elements within conspecific songs reinstated robust responses. Neurons also detected changes in the structure of artificial songs, and this detection depended on local transitions between adjacent or nonadjacent syllables. These findings establish the songbird as a model system for deciphering the mechanisms underlying sequence processing at the single-cell level.

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Section: Non-linear Processingmentioning

confidence: 99%

Neuronal Encoding in a High-Level Auditory Area: From Sequential Order of Elements to Grammatical Structure

et al. 2019

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“…In humans, theta (4−8 Hz)/gamma (80−150 Hz) PAC was described in human auditory cortex during speech perception [Canolty et al, 2006]. In more recent work, theta/gamma PAC was reported during the processing of auditory sequences in both humans and monkeys [Kikuchi et al, 2017], during working memory maintenance in human hippocampus [Axmacher et al, 2010], and during serial memory recall using non-invasive human magnetoencephalography (MEG) [Heusser et al, 2016]. PAC has been proposed to support the maintenance of information and to play an important role in long distance communication between different neural populations, considering that slow oscillations can propagate at larger scales than fast ones [Jensen and Colgin, 2007, Khan et al, 2013, Lisman and Jensen, 2013, Bonnefond et al, 2017.…”

Section: Introductionmentioning

confidence: 97%

Non-linear Auto-Regressive Models for Cross-Frequency Coupling in Neural Time Series

Tour

Tallot

Grabot

et al. 2017

Preprint

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We address the issue of reliably detecting and quantifying cross-frequency coupling (CFC) in neural time series. Based on non-linear auto-regressive models, the proposed method provides a generative and parametric model of the time-varying spectral content of the signals. As this method models the entire spectrum simultaneously, it avoids the pitfalls related to incorrect filtering or the use of the Hilbert transform on wide-band signals. As the model is probabilistic, it also provides a score of the model "goodness of fit" via the likelihood, enabling easy and legitimate model selection and parameter comparison; this data-driven feature is unique to our model-based approach. Using three datasets obtained with invasive neurophysiological recordings in humans and rodents, we demonstrate that these models are able to replicate previous results obtained with other metrics, but also reveal new insights such as the influence of the amplitude of the slow oscillation. Using simulations, we demonstrate that our parametric method can reveal neural couplings with shorter signals than non-parametric methods. We also show how the likelihood can be used to find optimal filtering parameters, suggesting new properties on the spectrum of the driving signal, but also to estimate the optimal delay between the coupled signals, enabling a directionality estimation in the coupling. Author SummaryNeural oscillations synchronize information across brain areas at various anatomical and temporal scales. Of particular relevance, slow fluctuations of brain activity have been shown to affect high frequency neural activity, by regulating the excitability level of neural populations. Such cross-frequency-coupling can take several forms. In the most frequently observed type, the power of high frequency activity is time-locked to a specific phase of slow frequency oscillations, yielding phase-amplitude-coupling (PAC). Even when readily observed in neural recordings, such non-linear coupling is particularly challenging to formally characterize. Typically, neuroscientists use band-pass filtering and Hilbert transforms with ad-hoc correlations. Here, we explicitly address current limitations and propose an alternative probabilistic signal modeling approach, for which statistical inference is fast and well-posed. To statistically model PAC, we propose to use non-linear auto-regressive models which estimate the spectral modulation of a signal conditionally to a driving signal. This conditional spectral analysis enables easy model selection and clear hypothesis-testing by using the likelihood of a given model. We demonstrate the advantage of the model-based approach on three datasets acquired in rats and in humans. We further provide novel neuroscientific insights on previously reported PAC phenomena, capturing two mechanisms in PAC: influence of amplitude and directionality estimation.

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“…Our study aims at examining the effects of music in macaque monkeys because of the great similarity in brain architecture between humans and monkeys (Mansouri, Koechlin, Rosa, & Buckley, ; Petrides, Tomaiuolo, Yeterian, & Pandya, ), the ability of monkeys in processing abstract rules and concepts and their enriched social behavior (Kikuchi et al, ; Mansouri, Buckley, Fehring, & Tanaka, ; Mansouri, Egner, & Buckley, ; Mansouri, Tanaka, & Buckley, ; Miller, Nieder, Freedman, & Wallis, ).…”

Section: Introductionmentioning

confidence: 99%

Interaction of music and emotional stimuli in modulating working memory in macaque monkeys

Zarei

Sheibani

Mansouri

2019

American J Primatol

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Sequence learning modulates neural responses and oscillatory coupling in human and monkey auditory cortex

Cited by 60 publications

References 92 publications

Neuronal Encoding in a High-Level Auditory Area: From Sequential Order of Elements to Grammatical Structure

Neuronal Encoding in a High-Level Auditory Area: From Sequential Order of Elements to Grammatical Structure

Non-linear Auto-Regressive Models for Cross-Frequency Coupling in Neural Time Series

Interaction of music and emotional stimuli in modulating working memory in macaque monkeys

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