The neural correlates of processing scale-invariant environmental sounds at birth

Sensory systems are thought to have evolved to efficiently represent the full range of sensory stimuli encountered in the natural world. The statistics of natural environmental sounds are characterized by scale-invariance: the property of exhibiting similar patterns at different levels of observatio...

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Veröffentlicht in:NeuroImage (Orlando, Fla.) Fla.), 2016-06, Vol.133, p.144-150
Hauptverfasser: Gervain, Judit, Werker, Janet F., Black, Alexis, Geffen, Maria N.
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Sprache:eng
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Zusammenfassung:Sensory systems are thought to have evolved to efficiently represent the full range of sensory stimuli encountered in the natural world. The statistics of natural environmental sounds are characterized by scale-invariance: the property of exhibiting similar patterns at different levels of observation. The statistical structure of scale-invariant sounds remains constant at different spectro-temporal scales. Scale-invariance plays a fundamental role in how efficiently animals and human adults perceive acoustic signals. However, the developmental origins and brain correlates of the neural encoding of scale-invariant environmental sounds remain unexplored. Here, we investigate whether the human brain extracts the statistical property of scale-invariance. Synthetic sounds generated by a mathematical model to respect scale-invariance or violate it were presented to newborns. In alternating blocks, the two sound types were presented together in an alternating fashion, whereas in non-alternating blocks, only one type of sound was presented. Newborns' brain responses were measured using near-infrared spectroscopy. We found that scale-invariant and variable-scale sounds were discriminated by the newborn brain, as suggested by differential activation in the left frontal and temporal areas to alternating vs. non-alternating blocks. These results indicate that newborns already detect and encode scale-invariance as a characteristic feature of acoustic stimuli. This suggests that the mathematical principle of efficient coding of information guides the auditory neural code from the beginning of human development, a finding that may help explain how evolution has prepared the brain for perceiving the natural world. •Scale-invariance is a key property of environmental sounds.•In adults and infants, the auditory system extracts and processes scale-invariance in an efficient way.•We found that the newborn brain discriminates scale-invariant and variable-scale sounds.•Mathematically efficient information coding guides auditory processing from the onset of development.
ISSN:1053-8119
1095-9572
DOI:10.1016/j.neuroimage.2016.03.001