Musical experience shapes human brainstem encoding of linguistic pitch patterns

Wong, Patrick C. M.; Skoe, Erika; Russo, Nicole; Dees, Tasha M.; Kraus, Nina

doi:10.1038/nn1872

Cited by 831 publications

(868 citation statements)

References 15 publications

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“…One mechanism involves specialized neurons that are tuned to relevant aspects of sensory input, or attenuate irrelevant aspects [e.g., Gordon and O'Neil, 2000;Rauschecker et al, 1995;Wong et al, 2007b]. In the auditory system, which subserves both speech and music processing, evidence suggests that low-level neurons are tuned to basic acoustic properties such as center frequency (CF) and frequency modulation (FM) (''information-bearing elements'' or IBEs), while high-level neurons are sensitive to relevant parts and combinations of IBEs, which carry species-specific communicative functions [Suga, 1995;Suga et al, 2000].…”

Section: Introductionmentioning

confidence: 99%

Selective neurophysiologic responses to music in instrumentalists with different listening biographies

Margulis

Mlsna

Uppunda

et al. 2007

Human Brain Mapping

120

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To appropriately adapt to constant sensory stimulation, neurons in the auditory system are tuned to various acoustic characteristics, such as center frequencies, frequency modulations, and their combinations, particularly those combinations that carry species-specific communicative functions. The present study asks whether such tunings extend beyond acoustic and communicative functions to auditory self-relevance and expertise. More specifically, we examined the role of the listening biographyan individual's long term experience with a particular type of auditory input-on perceptual-neural plasticity. Two groups of expert instrumentalists (violinists and flutists) listened to matched musical excerpts played on the two instruments (J.S. Bach Partitas for solo violin and flute) while their cerebral hemodynamic responses were measured using fMRI. Our experimental design allowed for a comprehensive investigation of the neurophysiology (cerebral hemodynamic responses as measured by fMRI) of auditory expertise (i.e., when violinists listened to violin music and when flutists listened to flute music) and nonexpertise (i.e., when subjects listened to music played on the other instrument). We found an extensive cerebral network of expertise, which implicates increased sensitivity to musical syntax (BA 44), timbre (auditory association cortex), and sound-motor interactions (precentral gyrus) when listening to music played on the instrument of expertise (the instrument for which subjects had a unique listening biography). These findings highlight auditory self-relevance and expertise as a mechanism of perceptual-neural plasticity, and implicate neural tuning that includes and extends beyond

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Section: Introductionmentioning

confidence: 99%

Selective neurophysiologic responses to music in instrumentalists with different listening biographies

Margulis

Mlsna

Uppunda

et al. 2007

Human Brain Mapping

120

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“…Over the past decade, an increasing number of scientists have sought to understand what underlies this seemingly ubiquitous benefit of musical training. We now know that the musician's brain has functional adaptations for processing pitch and timbre (3)(4)(5)(6) as well as structural specializations in auditory, visual, motor, and cerebellar regions of the brain (7)(8)(9). Some studies also suggest that the interplay between modalities is stronger in musicians (10) and, in the case of conductors, that improved audiovisual task performance is related to enhanced activity in multisensory brain areas (11).…”

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confidence: 99%

“…Measurements of the speech-evoked onset response and FFR, such as peak latencies and spectral amplitudes, have been studied extensively. In addition, it has been shown that these two main features of the brainstem response are influenced by viewing phoneme articulations and auditory training (6,12,37,38), thus making these responses suitable tools for the investigation of musicianship effects.…”

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confidence: 99%

Musicians have enhanced subcortical auditory and audiovisual processing of speech and music

Musacchia¹,

Sams

Skoe³

et al. 2007

Proc. Natl. Acad. Sci. U.S.A.

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Musical training is known to modify cortical organization. Here, we show that such modifications extend to subcortical sensory structures and generalize to processing of speech. Musicians had earlier and larger brainstem responses than nonmusician controls to both speech and music stimuli presented in auditory and audiovisual conditions, evident as early as 10 ms after acoustic onset. Phaselocking to stimulus periodicity, which likely underlies perception of pitch, was enhanced in musicians and strongly correlated with length of musical practice. In addition, viewing videos of speech (lip-reading) and music (instrument being played) enhanced temporal and frequency encoding in the auditory brainstem, particularly in musicians. These findings demonstrate practice-related changes in the early sensory encoding of auditory and audiovisual information.brainstem ͉ plasticity ͉ visual ͉ multisensory language

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“…Brainstem responses in musicians relative to nonmusicians have recently been shown to be faster, larger, and more reliable when encoding the periodicity of speech and music (9,10). Importantly, the enhanced auditory processing skills transferred from music to speech (11).…”

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confidence: 99%

Long-term music training tunes how the brain temporally binds signals from multiple senses

Lee

Noppeney

2011

Proc. Natl. Acad. Sci. U.S.A.

155

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Practicing a musical instrument is a rich multisensory experience involving the integration of visual, auditory, and tactile inputs with motor responses. This combined psychophysics-fMRI study used the musician's brain to investigate how sensory-motor experience molds temporal binding of auditory and visual signals. Behaviorally, musicians exhibited a narrower temporal integration window than nonmusicians for music but not for speech. At the neural level, musicians showed increased audiovisual asynchrony responses and effective connectivity selectively for music in a superior temporal sulcus-premotor-cerebellar circuitry. Critically, the premotor asynchrony effects predicted musicians' perceptual sensitivity to audiovisual asynchrony. Our results suggest that piano practicing fine tunes an internal forward model mapping from action plans of piano playing onto visible finger movements and sounds. This internal forward model furnishes more precise estimates of the relative audiovisual timings and hence, stronger prediction error signals specifically for asynchronous music in a premotor-cerebellar circuitry. Our findings show intimate links between action production and audiovisual temporal binding in perception.audiovisual synchrony | multisensory integration | sensorimotor learning | crossmodal integration | experience-dependent plasticity P racticing a musical instrument is a rich multisensory experience involving the integration of visual, auditory, and tactile inputs with motor responses. The musician's brain, thus, provides an ideal model to study experience-dependent plasticity in humans (1, 2).Previous research in musicians has focused on neural plasticity affecting unisensory and motor processing. Little is known about how musical expertise alters the integration of inputs from multiple senses. Because musical performance requires precise timing, musical expertise may specifically modulate the temporal binding of sensory signals. Given the variability in physical and neural transmission times, sensory signals do not have to be precisely synchronous but must co-occur within a temporal window that flexibly adapts to the temporal statistics of the sensory inputs as a consequence of music (3) or audiovisual training (4). At the neural level, audiovisual (a)synchrony processing relies on a widespread neural system encompassing subcortical, primary sensory, higher-order association, cerebellar, and premotor areas (5-8).This study used the musician's brain as a model to investigate how long-term sensory-motor experience (i.e., piano practicing) shapes the neural processes underlying temporal binding of auditory and visual signals. We presented subjects with synchronous and asynchronous speech and piano music as two stimulus classes that are both characterized by a rich hierarchical temporal structure but linked to different motor effectors (mouth vs. hand). Comparing the effect of musical expertise on synchrony perception of speech and music allowed us to dissociate generic and context-specific neural mechanisms ...

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Musical experience shapes human brainstem encoding of linguistic pitch patterns

Cited by 831 publications

References 15 publications

Selective neurophysiologic responses to music in instrumentalists with different listening biographies

Selective neurophysiologic responses to music in instrumentalists with different listening biographies

Musicians have enhanced subcortical auditory and audiovisual processing of speech and music

Long-term music training tunes how the brain temporally binds signals from multiple senses

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