Cross-frequency Phase–Amplitude Coupling as a Mechanism for Temporal Orienting of Attention in Childhood

Temporal orienting of attention operates by biasing the allocation of cognitive and motor resources in specific moments in time, resulting in the improved processing of information from expected compared with unexpected targets. Recent findings have shown that temporal orienting operates relatively...

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Veröffentlicht in:	Journal of cognitive neuroscience 2018-04, Vol.30 (4), p.594-602
Hauptverfasser:	Mento, Giovanni, Astle, Duncan E, Scerif, Gaia
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Sprache:	eng
Schlagworte:	Anticipation, Psychological - physiology Attention - physiology Brain - growth & development Brain - physiology Child Child Behavior - physiology Child Behavior - psychology Children Childrens health Cognitive ability Cognitive psychology Electroencephalography Humans Information processing Neuropsychology Orientation - physiology Psychology, Child Time Factors Time Perception - physiology
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creator	Mento, Giovanni Astle, Duncan E Scerif, Gaia
description	Temporal orienting of attention operates by biasing the allocation of cognitive and motor resources in specific moments in time, resulting in the improved processing of information from expected compared with unexpected targets. Recent findings have shown that temporal orienting operates relatively early across development, suggesting that this attentional mechanism plays a core role for human cognition. However, the exact neurophysiological mechanisms allowing children to attune their attention over time are not well understood. In this study, we presented 8- to 12-year-old children with a temporal cueing task designed to test (1) whether anticipatory oscillatory dynamics predict children's behavioral performance on a trial-by-trial basis and (2) whether anticipatory oscillatory neural activity may be supported by cross-frequency phase–amplitude coupling as previously shown in adults. Crucially, we found that, similar to what has been reported in adults, children's ongoing beta rhythm was strongly coupled with their theta rhythm and that the strength of this coupling distinguished validly cued temporal intervals, relative to neutral cued trials. In addition, in long trials, there was an inverse correlation between oscillatory beta power and children's trial-by-trial reaction, consistent with oscillatory beta power reflecting better response preparation. These findings provide the first experimental evidence that temporal attention in children operates by exploiting oscillatory mechanism.
doi_str_mv	10.1162/jocn_a_01223
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subjects	Anticipation, Psychological - physiology Attention - physiology Brain - growth & development Brain - physiology Child Child Behavior - physiology Child Behavior - psychology Children Childrens health Cognitive ability Cognitive psychology Electroencephalography Humans Information processing Neuropsychology Orientation - physiology Psychology, Child Time Factors Time Perception - physiology
title	Cross-frequency Phase–Amplitude Coupling as a Mechanism for Temporal Orienting of Attention in Childhood
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