Your search keyword '"110 014 Public activities"' showing total 14 results

1. The suppression of repetition enhancement: A review of fMRI studies

Author

Peter Hagoort, Floris P. de Lange, Katrien Segaert, Kirsten Weber, and Karl Magnus Petersson

Subjects

Adult, 110 000 Neurocognition of Language, 110 012 Social cognition of verbal communication, Cognitive Neuroscience, Repression, Psychology, A neurocomputational model for the Processing of Linguistic Utterances based on the Unification-Space architecture [110 007 PLUS], 110 013 Binding and the MUC-model, Experimental and Cognitive Psychology, Models, Psychological, 110 023 Syntactic Priming, Stimulus (physiology), Brain mapping, Behavioral Neuroscience, Image Processing, Computer-Assisted, Explicit memory, Humans, Learning, Attention, 110 014 Public activities, Bold response, Brain Mapping, Predictive coding, Single model, Brain, fMRI adaptation, 180 000 Predictive Brain, Magnetic Resonance Imaging, Oxygen, Facilitation, 110 009 The human brain and Chinese prosody, Psychology, Cognitive psychology

Abstract

Contains fulltext : 115434.pdf (Publisher’s version ) (Closed access) Repetition suppression in fMRI studies is generally thought to underlie behavioural facilitation effects (i.e., priming) and it is often used to identify the neuronal representations associated with a stimulus. However, this pays little heed to the large number of repetition enhancement effects observed under similar conditions. In this review, we identify several cognitive variables biasing repetition effects in the BOLD response towards enhancement instead of suppression. These variables are stimulus recognition, learning, attention, expectation and explicit memory. We also evaluate which models can account for these repetition effects and come to the conclusion that there is no one single model that is able to embrace all repetition enhancement effects. Accumulation, novel network formation as well as predictive coding models can all explain subsets of repetition enhancement effects.

Published

2013

2. The neurobiology of syntax: beyond string sets

Author

Karl Magnus Petersson and Peter Hagoort

Subjects

110 012 Social cognition of verbal communication, Computer science, computer.software_genre, 0302 clinical medicine, Neurobiology, 110 014 Public activities, Language, Psycholinguistics, Parsing, Algorithmic learning theory, 05 social sciences, Analog, Brain, Articles, Language acquisition, Adaptation, Physiological, Magnetic Resonance Imaging, Frontal Lobe, Language and Communication [DI-BCB_DCC_Theme 1], Comprehension, General Agricultural and Biological Sciences, Artificial grammar, 110 000 Neurocognition of Language, Artificial grammar learning, Chomsky hierarchy, Embedded english sentences, A neurocomputational model for the Processing of Linguistic Utterances based on the Unification-Space architecture [110 007 PLUS], 110 013 Binding and the MUC-model, Nerve Tissue Proteins, Working-memory, Models, Biological, 050105 experimental psychology, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, Rule-based machine translation, Memory, Humans, Learning, 0501 psychology and cognitive sciences, Dynamical-systems, Human language, Functional Mri, Brocas region, Syntax (programming languages), Computational Biology, Membrane Proteins, Theory of computation, 110 009 The human brain and Chinese prosody, computer, Neuroscience, 030217 neurology & neurosurgery

Abstract

The human capacity to acquire language is an outstanding scientific challenge to understand. Somehow our language capacities arise from the way the human brain processes, develops and learns in interaction with its environment. To set the stage, we begin with a summary of what is known about the neural organization of language and what our artificial grammar learning (AGL) studies have revealed. We then review the Chomsky hierarchy in the context of the theory of computation and formal learning theory. Finally, we outline a neurobiological model of language acquisition and processing based on an adaptive, recurrent, spiking network architecture. This architecture implements an asynchronous, event-driven, parallel system for recursive processing. We conclude that the brain represents grammars (or more precisely, the parser/generator) in its connectivity, and its ability for syntax is based on neurobiological infrastructure for structured sequence processing. The acquisition of this ability is accounted for in an adaptive dynamical systems framework. Artificial language learning (ALL) paradigms might be used to study the acquisition process within such a framework, as well as the processing properties of the underlying neurobiological infrastructure. However, it is necessary to combine and constrain the interpretation of ALL results by theoretical models and empirical studies on natural language processing. Given that the faculty of language is captured by classical computational models to a significant extent, and that these can be embedded in dynamic network architectures, there is hope that significant progress can be made in understanding the neurobiology of the language faculty. Max Planck Institute for Psycholinguistics; Donders Institute for Brain, Cognition and Behaviour; Fundacao para a Ciencia e Tecnologia (IBB/CBME, LA, FEDER/POCI) [PTDC/PSI-PCO/110734/2009]; Vetenskapsradet info:eu-repo/semantics/publishedVersion

Published

2012

3. What artificial grammar learning reveals about the neurobiology of syntax

Author

Peter Hagoort, Vasiliki Folia, and Karl Magnus Petersson

Subjects

Adult, Male, Sentence comprehension, Linguistics and Language, 110 000 Neurocognition of Language, 110 012 Social cognition of verbal communication, Artificial grammar learning, Chomsky hierarchy, Cognitive Neuroscience, media_common.quotation_subject, A neurocomputational model for the Processing of Linguistic Utterances based on the Unification-Space architecture [110 007 PLUS], 110 013 Binding and the MUC-model, Working-memory, Experimental and Cognitive Psychology, Language and Linguistics, Speech and Hearing, Brocas Area, Humans, Learning, Dynamical-systems, Language Faculty, Word grammar, 110 014 Public activities, Language, media_common, Cognitive science, Brain Mapping, Time analog computations, Psycholinguistics, Grammar, Musical syntax, Inferior frontal-cortex, Brain, Linguistics, Magnetic Resonance Imaging, Syntax, Broca's region, Syntactic movement, Female, Simple recurrent networks, Language and Communication [DI-BCB_DCC_Theme 1], 110 009 The human brain and Chinese prosody, Psychology, Functional localization

Abstract

In this paper we examine the neurobiological correlates of syntax, the processing of structured sequences, by comparing FMRI results on artificial and natural language syntax. We discuss these and similar findings in the context of formal language and computability theory. We used a simple right-linear unification grammar in an implicit artificial grammar learning paradigm in 32 healthy Dutch university students (natural language FMRI data were already acquired for these participants). We predicted that artificial syntax processing would engage the left inferior frontal region (BA 44/45) and that this activation would overlap with syntax-related variability observed in the natural language experiment. The main findings of this study show that the left inferior frontal region centered on BA 44/45 is active during artificial syntax processing of well-formed (grammatical) sequence independent of local subsequence familiarity. The same region is engaged to a greater extent when a syntactic violation is present and structural unification becomes difficult or impossible. The effects related to artificial syntax in the left inferior frontal region (BA 44/45) were essentially identical when we masked these with activity related to natural syntax in the same subjects. Finally, the medial temporal lobe was deactivated during this operation, consistent with the view that implicit processing does not rely on declarative memory mechanisms that engage the medial temporal lobe. In the context of recent FMRI findings, we raise the question whether Broca's region (or subregions) is specifically related to syntactic movement operations or the processing of hierarchically nested non-adjacent dependencies in the discussion section. We conclude that this is not the case. Instead, we argue that the left inferior frontal region is a generic on-line sequence processor that unifies information from various sources in an incremental and recursive manner, independent of whether there are any processing requirements related to syntactic movement or hierarchically nested structures. In addition, we argue that the Chomsky hierarchy is not directly relevant for neurobiological systems. (C) 2010 Elsevier Inc. All rights reserved. Max Planck Institute for Psycholinguistics; Donders Institute for Brain, Cognition and Behaviour; FCT; LA; FEDER/POCI; Vetenskapsradet [8276]; Hedlunds Stiftelse; Stockholm County Council (ALF, FoUU) info:eu-repo/semantics/publishedVersion

Published

2012

4. Pattern perception and computational complexity: Introduction to the special issue

Author

Peter Hagoort, W. Tecumseh Fitch, and Angela D. Friederici

Subjects

110 000 Neurocognition of Language, 110 012 Social cognition of verbal communication, Computational complexity theory, Artificial grammar learning, A neurocomputational model for the Processing of Linguistic Utterances based on the Unification-Space architecture [110 007 PLUS], 110 013 Binding and the MUC-model, Pattern perception, 050105 experimental psychology, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, 0302 clinical medicine, Empirical research, Formal language, Comparative cognition, 0501 psychology and cognitive sciences, 110 014 Public activities, Cognitive science, Introduction, Psycholinguistics, 05 social sciences, Theory of computation, Language and Communication [DI-BCB_DCC_Theme 1], General Agricultural and Biological Sciences, Psychology, 110 009 The human brain and Chinese prosody, Neuroscience, 030217 neurology & neurosurgery

Abstract

Item does not contain fulltext Research on pattern perception and rule learning, grounded in formal language theory (FLT) and using artificial grammar learning paradigms, has exploded in the last decade. This approach marries empirical research conducted by neuroscientists, psychologists and ethologists with the theory of computation and FLT, developed by mathematicians, linguists and computer scientists over the last century. Of particular current interest are comparative extensions of this work to non-human animals, and neuroscientific investigations using brain imaging techniques. We provide a short introduction to the history of these fields, and to some of the dominant hypotheses, to help contextualize these ongoing research programmes, and finally briefly introduce the papers in the current issue. 8 p.

Published

2012

5. Implicit Acquisition of Grammars With Crossed and Nested Non-Adjacent Dependencies: Investigating the Push-Down Stack Model

Author

Martin Ingvar, Peter Hagoort, Julia Udden, and Karl Magnus Petersson

Subjects

Adult, Male, 110 000 Neurocognition of Language, 110 012 Social cognition of verbal communication, Artificial grammar learning, Computer science, Cognitive Neuroscience, media_common.quotation_subject, Nonlocal musical rules, A neurocomputational model for the Processing of Linguistic Utterances based on the Unification-Space architecture [110 007 PLUS], 110 013 Binding and the MUC-model, Experimental and Cognitive Psychology, Models, Psychological, computer.software_genre, Syntactic structure, Rule-based machine translation, Memory, Artificial Intelligence, Humans, Learning, 110 014 Public activities, Auxiliary memory, Language, media_common, Psycholinguistics, Syntax (programming languages), Grammar, business.industry, Language acquisition, Implicit learning, Dependency theory (database theory), Female, Language and Communication [DI-BCB_DCC_Theme 1], Artificial intelligence, 110 009 The human brain and Chinese prosody, business, computer, Natural language processing

Abstract

A recent hypothesis in empirical brain research on language is that the fundamental difference between animal and human communication systems is captured by the distinction between finite-state and more complex phrase-structure grammars, such as context-free and context-sensitive grammars. However, the relevance of this distinction for the study of language as a neurobiological system has been questioned and it has been suggested that a more relevant and partly analogous distinction is that between non-adjacent and adjacent dependencies. Online memory resources are central to the processing of non-adjacent dependencies as information has to be maintained across intervening material. One proposal is that an external memory device in the form of a limited push-down stack is used to process non-adjacent dependencies. We tested this hypothesis in an artificial grammar learning paradigm where subjects acquired non-adjacent dependencies implicitly. Generally, we found no qualitative differences between the acquisition of non-adjacent dependencies and adjacent dependencies. This suggests that although the acquisition of non-adjacent dependencies requires more exposure to the acquisition material, it utilizes the same mechanisms used for acquiring adjacent dependencies. We challenge the push-down stack model further by testing its processing predictions for nested and crossed multiple non-adjacent dependencies. The push-down stack model is partly supported by the results, and we suggest that stack-like properties are some among many natural properties characterizing the underlying neurophysiological mechanisms that implement the online memory resources used in language and structured sequence processing. info:eu-repo/semantics/publishedVersion

Published

2012

6. Neural dissociation in processing noise and accent in spoken language comprehension

Author

Peter Hagoort, Matthew H. Davis, and Patti Adank

Subjects

Male, Speech production, 110 012 Social cognition of verbal communication, Speech recognition, Prefrontal cortex, Psycholinguistics, Accent, Behavioral Neuroscience, Motor speech, 110 014 Public activities, Brain Mapping, Phonetics, Magnetic Resonance Imaging, Temporal Lobe, Frontal Lobe, FMRI, Auditory Perception, Speech Perception, Female, 110 016 Auditory and articulatory brain regions in accent adaptation, Language and Communication [DI-BCB_DCC_Theme 1], Comprehension, Psychology, psychological phenomena and processes, Cognitive psychology, Adult, 110 000 Neurocognition of Language, Speech perception, Adolescent, Cognitive Neuroscience, A neurocomputational model for the Processing of Linguistic Utterances based on the Unification-Space architecture [110 007 PLUS], 110 013 Binding and the MUC-model, Inferior frontal gyrus, Experimental and Cognitive Psychology, behavioral disciplines and activities, Speech shadowing, Young Adult, Arts and Humanities (miscellaneous), otorhinolaryngologic diseases, Humans, Speech, Auditory cortex, Speech Intelligibility, Neurocomputational speech processing, 110 009 The human brain and Chinese prosody, Noise

Abstract

Item does not contain fulltext We investigated how two distortions of the speech signal - added background noise and speech in an unfamiliar accent - affect comprehension of speech using functional Magnetic Resonance Imaging (fMRI). Listeners performed a speeded sentence verification task for speech in quiet in Standard Dutch, in Standard Dutch with added background noise and for speech in an unfamiliar accent of Dutch. The behavioural results showed slower responses for both types of distortion compared to clear speech, and no difference between the two distortions. The neuroimaging results showed that, compared to clear speech, processing noise resulted in more activity bilaterally in Inferior Frontal Gyrus, Frontal Operculum, while processing accented speech recruited an area in left Superior Temporal Gyrus/Sulcus. It is concluded that the neural bases for processing different distortions of the speech signal dissociate. It is suggested that current models of the cortical organisation of speech are updated to specifically associate bilateral inferior frontal areas with processing external distortions (e.g., background noise) and left temporal areas with speaker-related distortions (e.g., accents). Crown Copyright (C) 2011 Published by Elsevier Ltd. All rights reserved.

Published

2012

7. The neuronal infrastructure of speaking

Author

Laura Menenti, Peter Hagoort, and Katrien Segaert

Subjects

Adult, Male, Linguistics and Language, Speech production, 110 000 Neurocognition of Language, 110 012 Social cognition of verbal communication, Cognitive Neuroscience, A neurocomputational model for the Processing of Linguistic Utterances based on the Unification-Space architecture [110 007 PLUS], 110 013 Binding and the MUC-model, Experimental and Cognitive Psychology, Semantics, Language and Linguistics, Speech and Hearing, Young Adult, Image Processing, Computer-Assisted, Humans, Speech, 110 014 Public activities, Language, Brain Mapping, Psycholinguistics, Repetition (rhetorical device), Language production, fMRI adaptation, Brain, Syntax, Magnetic Resonance Imaging, Linguistics, Speech Perception, Female, Language and Communication [DI-BCB_DCC_Theme 1], Psychology, 110 009 The human brain and Chinese prosody, Sentence, Meaning (linguistics)

Abstract

Contains fulltext : 115530.pdf (Publisher’s version ) (Closed access) Models of speaking distinguish producing meaning, words and syntax as three different linguistic components of speaking. Nevertheless, little is known about the brain's integrated neuronal infrastructure for speech production. We investigated semantic, lexical and syntactic aspects of speaking using fMRI. In a picture description task, we manipulated repetition of sentence meaning, words, and syntax separately. By investigating brain areas showing response adaptation to repetition of each of these sentence properties, we disentangle the neuronal infrastructure for these processes. We demonstrate that semantic, lexical and syntactic processes are carried out in partly overlapping and partly distinct brain networks and show that the classic left-hemispheric dominance for language is present for syntax but not semantics. (C) 2012 Elsevier Inc. All rights reserved.

Published

2012

8. Effective Connectivity Determines the Nature of Subjective Experience in Grapheme-Color Synesthesia

Author

Peter Hagoort, Tessa M. van Leeuwen, Hanneke E. M. den Ouden, and Language, Communication and Cognition

Subjects

Adult, Male, 110 000 Neurocognition of Language, 110 012 Social cognition of verbal communication, Statistics as Topic, A neurocomputational model for the Processing of Linguistic Utterances based on the Unification-Space architecture [110 007 PLUS], Individuality, Grapheme, 110 013 Binding and the MUC-model, Models, Biological, Brain mapping, Young Adult, Image Processing, Computer-Assisted, medicine, Humans, Synesthesia, Association (psychology), 110 014 Public activities, Visual Cortex, Causal model, Brain Mapping, Psycholinguistics, Fusiform gyrus, General Neuroscience, Grapheme-color synesthesia, Parietal lobe, Bayes Theorem, Articles, medicine.disease, Magnetic Resonance Imaging, Oxygen, Nonlinear Dynamics, Pattern Recognition, Visual, Female, Language and Communication [DI-BCB_DCC_Theme 1], 110 009 The human brain and Chinese prosody, Psychology, Color Perception, Photic Stimulation, Cognitive psychology

Abstract

Contains fulltext : 115492.pdf (Publisher’s version ) (Open Access) Synesthesia provides an elegant model to investigate neural mechanisms underlying individual differences in subjective experience in humans. In grapheme-color synesthesia, written letters induce color sensations, accompanied by activation of color area V4. Competing hypotheses suggest that enhanced V4 activity during synesthesia is either induced by direct bottom-up cross-activation from grapheme processing areas within the fusiform gyrus, or indirectly via higher-order parietal areas. Synesthetes differ in the way synesthetic color is perceived: "projector" synesthetes experience color externally colocalized with a presented grapheme, whereas "associators" report an internally evoked association. Using dynamic causal modeling for fMRI, we show that V4 cross-activation during synesthesia was induced via a bottom-up pathway (within fusiform gyrus) in projector synesthetes, but via a top-down pathway (via parietal lobe) in associators. These findings show how altered coupling within the same network of active regions leads to differences in subjective experience. Our findings reconcile the two most influential cross-activation accounts of synesthesia. 6 p.

Published

2011

9. Exploring the cognitive infrastructure of communication

Author

de Ruiter, J.P., Noordzij, Matthijs L., Newman-Norlund, Sarah, Newman-Norlund, Roger, Hagoort, Peter, Levinson, Stephen C., Toni, Ivan, Galantucci, Bruno, Garros, Simon, and Faculty of Behavioural, Management and Social Sciences

Subjects

Linguistics and Language, 110 000 Neurocognition of Language, 110 012 Social cognition of verbal communication, Computer science, A neurocomputational model for the Processing of Linguistic Utterances based on the Unification-Space architecture [110 007 PLUS], 110 013 Binding and the MUC-model, Dysfunctional family, computer.software_genre, Language and Linguistics, Code (semiotics), Task (project management), Human–computer interaction, Language in Time and Space, 111 000 Intention & Action, 110 014 Public activities, Human communication, Communication, Multimedia, Action, intention, and motor control, business.industry, Perception, Action and Control [DI-BCB_DCC_Theme 2], Cognition, Human-Computer Interaction, Action (philosophy), Animal Science and Zoology, 110 009 The human brain and Chinese prosody, business, Psychology, computer

Abstract

Contains fulltext : 86126.pdf (Publisher’s version ) (Closed access) Human communication is often thought about in terms of transmitted messages in a conventional code like a language. But communication requires a specialized interactive intelligence. Senders have to be able to perform recipient design, while receivers need to be able to do intention recognition, knowing that recipient design has taken place. To study this interactive intelligence in the lab, we developed a new task that taps directly into the underlying abilities to communicate in the absence of a conventional code. We show that subjects are remarkably successful communicators under these conditions, especially when senders get feedback from receivers. Signaling is accomplished by the manner in which an instrumental action is performed, such that instrumentally dysfunctional components of an action are used to convey communicative intentions. The findings have important implications for the nature of the human communicative infrastructure, and the task opens up a line of experimentation on human communication.

Published

2010

10. Syntactic unification operations are reflected in oscillatory dynamics during online sentence comprehension

Author

Peter Hagoort, Lilla Magyari, Marcel C. M. Bastiaansen, Academy for Leisure & Events, and Leisure and Tourism Experiences

Subjects

110 000 Neurocognition of Language, 110 012 Social cognition of verbal communication, Unification, Cognitive Neuroscience, A neurocomputational model for the Processing of Linguistic Utterances based on the Unification-Space architecture [110 007 PLUS], 110 013 Binding and the MUC-model, computer.software_genre, Vocabulary, Synchronization (computer science), Humans, 110 014 Public activities, Language, Neurons, Working memory, business.industry, Brain, Magnetoencephalography, Trace (linguistics), Linguistics, Semantics, Comprehension, Alpha (programming language), Reading, Artificial intelligence, Psychology, business, Beta Rhythm, 110 009 The human brain and Chinese prosody, computer, Word (computer architecture), Sentence, Natural language processing

Abstract

Contains fulltext : 90335.pdf (Publisher’s version ) (Open Access) There is growing evidence suggesting that synchronization changes in the oscillatory neuronal dynamics in the EEG or MEG reflect the transient coupling and uncoupling of functional networks related to different aspects of language comprehension. In this work, we examine how sentence-level syntactic unification operations are reflected in the oscillatory dynamics of the MEG. Participants read sentences that were either correct, contained a word category violation, or were constituted of random word sequences devoid of syntactic structure. A time-frequency analysis of MEG power changes revealed three types of effects. The first type of effect was related to the detection of a (word category) violation in a syntactically structured sentence, and was found in the alpha and gamma frequency bands. A second type of effect was maximally sensitive to the syntactic manipulations: A linear increase in beta power across the sentence was present for correct sentences, was disrupted upon the occurrence of a word category violation, and was absent in syntactically unstructured random word sequences. We therefore relate this effect to syntactic unification operations. Thirdly, we observed a linear increase in theta power across the sentence for all syntactically structured sentences. The effects are tentatively related to the building of a working memory trace of the linguistic input. In conclusion, the data seem to suggest that syntactic unification is reflected by neuronal synchronization in the lower-beta frequency band.

Published

2010

11. The neural integration of speaker and message

Author

Peter Hagoort, Danielle van den Brink, Miriam Kos, Cathelijne M. J. Y. Tesink, and Jos J. A. Van Berkum

Subjects

Adult, Male, 110 000 Neurocognition of Language, 110 012 Social cognition of verbal communication, Cognitive Neuroscience, A neurocomputational model for the Processing of Linguistic Utterances based on the Unification-Space architecture [110 007 PLUS], 110 013 Binding and the MUC-model, Context (language use), Semantics, 110 030 ERC Janzen Spatial memory, Cognitive neurosciences [UMCN 3.2], Reference Values, 110 003 Autism & depression, Perception and Action [DCN 1], Humans, 110 014 Public activities, Evoked Potentials, Cerebral Cortex, Psycholinguistics, Verbal Behavior, Pragmatics, Speaker recognition, Linguistics, Speaker diarisation, Accent (music), Acoustic Stimulation, Social Perception, Speech Perception, Female, Language and Communication [DI-BCB_DCC_Theme 1], 110 003 Autism & depressions, 110 009 The human brain and Chinese prosody, Comprehension, Psychology, Functional Neurogenomics [DCN 2], Sentence, Meaning (linguistics)

Abstract

Contains fulltext : 70720.pdf (Publisher’s version ) (Open Access) When do listeners take into account who the speaker is? We asked people to listen to utterances whose content sometimes did not match inferences based on the identity of the speaker (e.g., "If only I looked like Britney Spears" in a male voice, or "I have a large tattoo on my back" spoken with an upper-class accent). Event-related brain responses revealed that the speaker's identity is taken into account as early as 200-300 msec after the beginning of a spoken word, and is processed by the same early interpretation mechanism that constructs sentence meaning based on just the words. This finding is difficult to reconcile with standard "Gricean" models of sentence interpretation in which comprehenders initially compute a local, context-independent meaning for the sentence ("semantics") before working out what it really means given the wider communicative context and the particular speaker ("pragmatics"). Because the observed brain response hinges on voice-based and usually stereotype-dependent inferences about the speaker, it also shows that listeners rapidly classify speakers on the basis of their voices and bring the associated social stereotypes to bear on what is being said. According to our event-related potential results, language comprehension takes very rapid account of the social context, and the construction of meaning based on language alone cannot be separated from the social aspects of language use. The linguistic brain relates the message to the speaker immediately.

Published

2008

12. The cascaded nature of lexical selection and integration in auditory sentence processing

Author

Colin M. Brown, Danielle van den Brink, and Peter Hagoort

Subjects

Adult, Male, Linguistics and Language, 110 000 Neurocognition of Language, 110 012 Social cognition of verbal communication, A neurocomputational model for the Processing of Linguistic Utterances based on the Unification-Space architecture [110 007 PLUS], 110 013 Binding and the MUC-model, Experimental and Cognitive Psychology, Lexicon, computer.software_genre, Semantics, Language and Linguistics, Sentence processing, Mental Processes, Cognitive neurosciences [UMCN 3.2], Perception and Action [DCN 1], Determinants in Health and Disease [EBP 1], Selection (linguistics), Reaction Time, Humans, Semantic integration, 110 014 Public activities, Language, Analysis of Variance, Brain Mapping, Psycholinguistics, Language Tests, business.industry, Verbal Behavior, Electroencephalography, N400, Linguistics, Acoustic Stimulation, Word recognition, Evoked Potentials, Auditory, Female, Artificial intelligence, 110 009 The human brain and Chinese prosody, Psychology, business, Functional Neurogenomics [DCN 2], computer, Natural language processing, Sentence

Abstract

Contains fulltext : 49746.pdf (Publisher’s version ) (Closed access) An event-related brain potential experiment was carried out to investigate the temporal relationship between lexical selection and the semantic integration in auditory sentence processing. Participants were presented with spoken sentences that ended with a word that was either semantically congruent or anomalous. Information about the moment in which a sentence-final word could uniquely be identified, its isolation point (IP), was compared with the onset of the elicited N400 congruity effect, reflecting semantic integration processing. The results revealed that the onset of the N400 effect occurred prior to the IP of the sentence-final words. Moreover, the factor early or late IP did not affect the onset of the N400. These findings indicate that lexical selection and semantic integration are cascading processes, in that semantic integration processing can start before the acoustic information allows the selection of a unique candidate and seems to be attempted in parallel for multiple candidates that are still compatible with the bottom-up acoustic input.

Published

2006

13. What does it mean to predict one's own utterances?

Author

Peter Hagoort and Antje S. Meyer

Subjects

110 000 Neurocognition of Language, 110 012 Social cognition of verbal communication, Psycholinguistics, Language production, Physiology, A neurocomputational model for the Processing of Linguistic Utterances based on the Unification-Space architecture [110 007 PLUS], 110 013 Binding and the MUC-model, Linguistics, Comprehension, Behavioral Neuroscience, Neuropsychology and Physiological Psychology, Production (economics), Language and Communication [DI-BCB_DCC_Theme 1], 110 009 The human brain and Chinese prosody, Psychology, 110 014 Public activities

Abstract

Many authors have recently highlighted the importance of prediction for language comprehension. Pickering & Garrod (P&G) are the first to propose a central role for prediction in language production. This is an intriguing idea, but it is not clear what it means for speakers to predict their own utterances, and how prediction during production can be empirically distinguished from production proper.

Published

2013

14. Reply: Change in grey matter volume cannot be assumed to be due to cognitive behavioural therapy

Author

Gijs Bleijenberg, Peter Hagoort, Ivan Toni, Jos W. M. van der Meer, and Floris P. de Lange

Subjects

110 000 Neurocognition of Language, 110 012 Social cognition of verbal communication, Psychotherapist, Action, intention, and motor control, A neurocomputational model for the Processing of Linguistic Utterances based on the Unification-Space architecture [110 007 PLUS], Perception, Action and Control [DI-BCB_DCC_Theme 2], 110 013 Binding and the MUC-model, Cognition, 180 000 Predictive Brain, Grey matter, medicine.disease, Panacea (medicine), medicine.anatomical_structure, Full recovery, medicine, Chronic fatigue syndrome, 111 000 Intention & Action, Neurology (clinical), 110 009 The human brain and Chinese prosody, Psychology, 110 014 Public activities, Clinical psychology

Abstract

Sir, We thank Tom Kindlon for his letter, in which he raises several important issues. We will respond to all the issues in the same order as they appear in his letter. First, Tom Kindlon points out that cognitive behavioural therapy (CBT) is not a panacea for the chronic fatigue syndrome (CFS). It should be obvious from all previous meta-analyses that CBT does not lead to a full recovery in all CFS patients (while the exact numbers on improvement rates depend on a host of experimental factors like the exact type of therapy given, inclusion criteria of the study, as well as other factors …

Published

2009