Aarhus University Seal / Aarhus Universitets segl

Strength of word-specific neural memory traces assessed electrophysiologically: PLoS One

Research output: Contribution to journal/Conference contribution in journal/Contribution to newspaperJournal articleResearchpeer-review

Standard

Strength of word-specific neural memory traces assessed electrophysiologically : PLoS One. / Alexandrov, A. A.; Boricheva, D. O.; Pulvermuller, F.; Shtyrov, Yury.

In: PLOS ONE, Vol. 6, 2011, p. e22999.

Research output: Contribution to journal/Conference contribution in journal/Contribution to newspaperJournal articleResearchpeer-review

Harvard

APA

CBE

MLA

Vancouver

Author

Alexandrov, A. A. ; Boricheva, D. O. ; Pulvermuller, F. ; Shtyrov, Yury. / Strength of word-specific neural memory traces assessed electrophysiologically : PLoS One. In: PLOS ONE. 2011 ; Vol. 6. pp. e22999.

Bibtex

@article{4b6a1120af8746be9a6c7e8876b355e6,
title = "Strength of word-specific neural memory traces assessed electrophysiologically: PLoS One",
abstract = "Memory traces for words are frequently conceptualized neurobiologically as networks of neurons interconnected via reciprocal links developed through associative learning in the process of language acquisition. Neurophysiological reflection of activation of such memory traces has been reported using the mismatch negativity brain potential (MMN), which demonstrates an enhanced response to meaningful words over meaningless items. This enhancement is believed to be generated by the activation of strongly intraconnected long-term memory circuits for words that can be automatically triggered by spoken linguistic input and that are absent for unfamiliar phonological stimuli. This conceptual framework critically predicts different amounts of activation depending on the strength of the word's lexical representation in the brain. The frequent use of words should lead to more strongly connected representations, whereas less frequent items would be associated with more weakly linked circuits. A word with higher frequency of occurrence in the subject's language should therefore lead to a more pronounced lexical MMN response than its low-frequency counterpart. We tested this prediction by comparing the event-related potentials elicited by low- and high-frequency words in a passive oddball paradigm; physical stimulus contrasts were kept identical. We found that, consistent with our prediction, presenting the high-frequency stimulus led to a significantly more pronounced MMN response relative to the low-frequency one, a finding that is highly similar to previously reported MMN enhancement to words over meaningless pseudowords. Furthermore, activation elicited by the higher-frequency word peaked earlier relative to low-frequency one, suggesting more rapid access to frequently used lexical entries. These results lend further support to the above view on word memory traces as strongly connected assemblies of neurons. The speed and magnitude of their activation appears to be linked to the strength of internal connections in a memory circuit, which is in turn determined by the everyday use of language elements.",
keywords = "Acoustic Stimulation *Electrophysiological Phenomena Evoked Potentials/physiology Female Humans *Linguistics Male Memory/*physiology *Nervous System Physiological Phenomena Sound Spectrography Young Adult",
author = "Alexandrov, {A. A.} and Boricheva, {D. O.} and F. Pulvermuller and Yury Shtyrov",
year = "2011",
doi = "10.1371/journal.pone.0022999",
language = "English",
volume = "6",
pages = "e22999",
journal = "P L o S One",
issn = "1932-6203",
publisher = "public library of science",

}

RIS

TY - JOUR

T1 - Strength of word-specific neural memory traces assessed electrophysiologically

T2 - PLoS One

AU - Alexandrov, A. A.

AU - Boricheva, D. O.

AU - Pulvermuller, F.

AU - Shtyrov, Yury

PY - 2011

Y1 - 2011

N2 - Memory traces for words are frequently conceptualized neurobiologically as networks of neurons interconnected via reciprocal links developed through associative learning in the process of language acquisition. Neurophysiological reflection of activation of such memory traces has been reported using the mismatch negativity brain potential (MMN), which demonstrates an enhanced response to meaningful words over meaningless items. This enhancement is believed to be generated by the activation of strongly intraconnected long-term memory circuits for words that can be automatically triggered by spoken linguistic input and that are absent for unfamiliar phonological stimuli. This conceptual framework critically predicts different amounts of activation depending on the strength of the word's lexical representation in the brain. The frequent use of words should lead to more strongly connected representations, whereas less frequent items would be associated with more weakly linked circuits. A word with higher frequency of occurrence in the subject's language should therefore lead to a more pronounced lexical MMN response than its low-frequency counterpart. We tested this prediction by comparing the event-related potentials elicited by low- and high-frequency words in a passive oddball paradigm; physical stimulus contrasts were kept identical. We found that, consistent with our prediction, presenting the high-frequency stimulus led to a significantly more pronounced MMN response relative to the low-frequency one, a finding that is highly similar to previously reported MMN enhancement to words over meaningless pseudowords. Furthermore, activation elicited by the higher-frequency word peaked earlier relative to low-frequency one, suggesting more rapid access to frequently used lexical entries. These results lend further support to the above view on word memory traces as strongly connected assemblies of neurons. The speed and magnitude of their activation appears to be linked to the strength of internal connections in a memory circuit, which is in turn determined by the everyday use of language elements.

AB - Memory traces for words are frequently conceptualized neurobiologically as networks of neurons interconnected via reciprocal links developed through associative learning in the process of language acquisition. Neurophysiological reflection of activation of such memory traces has been reported using the mismatch negativity brain potential (MMN), which demonstrates an enhanced response to meaningful words over meaningless items. This enhancement is believed to be generated by the activation of strongly intraconnected long-term memory circuits for words that can be automatically triggered by spoken linguistic input and that are absent for unfamiliar phonological stimuli. This conceptual framework critically predicts different amounts of activation depending on the strength of the word's lexical representation in the brain. The frequent use of words should lead to more strongly connected representations, whereas less frequent items would be associated with more weakly linked circuits. A word with higher frequency of occurrence in the subject's language should therefore lead to a more pronounced lexical MMN response than its low-frequency counterpart. We tested this prediction by comparing the event-related potentials elicited by low- and high-frequency words in a passive oddball paradigm; physical stimulus contrasts were kept identical. We found that, consistent with our prediction, presenting the high-frequency stimulus led to a significantly more pronounced MMN response relative to the low-frequency one, a finding that is highly similar to previously reported MMN enhancement to words over meaningless pseudowords. Furthermore, activation elicited by the higher-frequency word peaked earlier relative to low-frequency one, suggesting more rapid access to frequently used lexical entries. These results lend further support to the above view on word memory traces as strongly connected assemblies of neurons. The speed and magnitude of their activation appears to be linked to the strength of internal connections in a memory circuit, which is in turn determined by the everyday use of language elements.

KW - Acoustic Stimulation Electrophysiological Phenomena Evoked Potentials/physiology Female Humans Linguistics Male Memory/physiology Nervous System Physiological Phenomena Sound Spectrography Young Adult

U2 - 10.1371/journal.pone.0022999

DO - 10.1371/journal.pone.0022999

M3 - Journal article

C2 - 21853063

VL - 6

SP - e22999

JO - P L o S One

JF - P L o S One

SN - 1932-6203

ER -