Functional specializations for music processing in the human newborn brain

Perani, Daniela; Saccuman, Maria Cristina; Scifo, Paola; Spada, Danilo; Andreolli, Guido; Rovelli, Rosanna; Baldoli, Cristina; Koelsch, Stefan

doi:10.1073/pnas.0909074107

Cited by 290 publications

(212 citation statements)

References 77 publications

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“…This finding suggests a higher reliance on prosodic than segmental information during speech processing in newborns. Such an interpretation would be compatible with optical imaging data reported for 3-mo-olds (24); moreover, it is reminiscent of a comparable right-predominant activation in primary and secondary auditory cortex when newborns listen to music (36). Together, our results suggest that very early in life, speech processing and music processing rely partially on the same neural substrates in the right auditory cortex.…”

Section: Discussionsupporting

confidence: 78%

“…However, the full brain activation pattern for speech in newborns (present study) shows similarities and differences from the pattern reported for newborns while hearing music (36). Crucially, in both studies, the activations at birth were not confined to primary and secondary auditory cortices but extended toward higher associative brain areas, for music being associated with a highly predominant overall right hemispheric activation (36), and for language showing an extended bilateral hemispheric involvement (present study).…”

Section: Discussioncontrasting

confidence: 41%

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Neural language networks at birth

Perani

Saccuman

Scifo

et al. 2011

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

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404

327

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The ability to learn language is a human trait. In adults and children, brain imaging studies have shown that auditory language activates a bilateral frontotemporal network with a left hemispheric dominance. It is an open question whether these activations represent the complete neural basis for language present at birth. Here we demonstrate that in 2-d-old infants, the language-related neural substrate is fully active in both hemispheres with a preponderance in the right auditory cortex. Functional and structural connectivities within this neural network, however, are immature, with strong connectivities only between the two hemispheres, contrasting with the adult pattern of prevalent intrahemispheric connectivities. Thus, although the brain responds to spoken language already at birth, thereby providing a strong biological basis to acquire language, progressive maturation of intrahemispheric functional connectivity is yet to be established with language exposure as the brain develops

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Section: Discussionsupporting

confidence: 78%

Section: Discussioncontrasting

confidence: 41%

Neural language networks at birth

Perani

Saccuman

Scifo

et al. 2011

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

Self Cite

404

327

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“…Bach concerto blindfolded, 27 indicating that this area supports higher musical representations. 25 A recent functional MR imaging study 28 indicates that the planum polare of a neonate, whose brain was not yet functionally specialized, was activated by musical stimuli. For adults, this area becomes increasingly involved with increasing melodic complexity.…”

Section: Fa Decrease In Planum Polare and Thalamusmentioning

confidence: 99%

Altered White Matter Integrity in Adolescents with Prelingual Deafness: A High-Resolution Tract-Based Spatial Statistics Imaging Study

Wen¹,

Li²,

Tang

et al. 2012

AJNR Am J Neuroradiol

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BACKGROUND AND PURPOSE:Prelingual deafness is a hearing loss that occurs before language is acquired and may result in brain structural alterations. We studied microstructural WM alterations in prelingually deaf adolescents by using DTI. We hypothesized that any morphologic alterations are mainly located in the auditory association areas. Furthermore, considering that the developing brain is both more vulnerable to deprivation and more plastic than the adult brain, we speculated that the affected areas should be larger than those previously reported in adult deafness.

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“…Although their perception is in some cases dependent on context (4), marked differences between consonance and dissonance are typically apparent even in isolated chords (5)(6)(7)(8). Preferences for consonance appear to be present in human infants (9)(10)(11)(12) and perhaps also in other species with little exposure to music (13,14, although see also ref. 15), consistent with a biological basis.…”

mentioning

confidence: 99%

The basis of musical consonance as revealed by congenital amusia

Cousineau

McDermott

Peretz

2012

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

108

164

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Some combinations of musical notes sound pleasing and are termed "consonant," but others sound unpleasant and are termed "dissonant." The distinction between consonance and dissonance plays a central role in Western music, and its origins have posed one of the oldest and most debated problems in perception. In modern times, dissonance has been widely believed to be the product of "beating": interference between frequency components in the cochlea that has been believed to be more pronounced in dissonant than consonant sounds. However, harmonic frequency relations, a higher-order sound attribute closely related to pitch perception, has also been proposed to account for consonance. To tease apart theories of musical consonance, we tested sound preferences in individuals with congenital amusia, a neurogenetic disorder characterized by abnormal pitch perception. We assessed amusics' preferences for musical chords as well as for the isolated acoustic properties of beating and harmonicity. In contrast to control subjects, amusic listeners showed no preference for consonance, rating the pleasantness of consonant chords no higher than that of dissonant chords. Amusics also failed to exhibit the normally observed preference for harmonic over inharmonic tones, nor could they discriminate such tones from each other. Despite these abnormalities, amusics exhibited normal preferences and discrimination for stimuli with and without beating. This dissociation indicates that, contrary to classic theories, beating is unlikely to underlie consonance. Our results instead suggest the need to integrate harmonicity as a foundation of music preferences, and illustrate how amusia may be used to investigate normal auditory function. music perception | aesthetic preferences | roughness

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Functional specializations for music processing in the human newborn brain

Cited by 290 publications

References 77 publications

Neural language networks at birth

Neural language networks at birth

Altered White Matter Integrity in Adolescents with Prelingual Deafness: A High-Resolution Tract-Based Spatial Statistics Imaging Study

The basis of musical consonance as revealed by congenital amusia

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