P600 (neuroscience)
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The P600 is an event-related potential (ERP) component, or peak in electrical brain activity measured by electroencephalography (EEG). It is a language-relevant ERP component and is thought to be elicited by hearing or reading grammatical errors and other syntactic anomalies. Therefore, it is a common topic of study in neurolinguistic experiments investigating sentence processing in the human brain.
The P600 can be elicited in both visual (reading) and auditory (listening) experiments,[1] and is characterized as a positive-going deflection with an onset around 500 milliseconds after the stimulus that elicits it; it often reaches its peak around 600 milliseconds after presentation of the stimulus (hence its name), and lasts several hundred milliseconds.[2][3][note 1] In other words, in the EEG waveform it is a large peak in the positive direction, which starts around 500 milliseconds after the subject sees or hears a stimulus. It is typically thought of as appearing mostly on centro-parietal electrodes (i.e., over the posterior part of the center of the scalp), but frontal P600s have also been observed in several studies.[4] In EEG, however, this distribution at the scalp does not mean the P600 is coming from that part of the brain; a 2007 study using magnetoencephalography (MEG) speculates that the generators of the P600 are in the posterior temporal lobe, behind Wernicke's area.[5]
The P600 was first reported by Lee Osterhout and Phillip Holcomb in 1992.[6] It is also sometimes called the syntactic positive shift (SPS), since it has a positive polarity and is usually elicited by syntactic phenomena.[2][7][8]
Elicitation
[edit]The P600 was originally considered a "syntactic" ERP component,[6][9][10][11] as it is elicited by several types of syntactic phenomena, including ungrammatical stimuli, garden-path sentences that require reanalysis, complex sentences with a large number of thematic roles, and the processing of filler-gap dependencies (such as wh-words that appear at the beginning of a sentence in English but are actually interpreted somewhere else).
- Grammatical errors
A P600 may be elicited by several kinds of grammatical errors in sentences, such as problems in agreement, such as "the child *throw the toy".[4] In addition to this sort of subject-verb disagreement, P600s have also been elicited by disagreements in tense, gender, number, and case, as well as phrase structure violations.[3] A 2009 study has suggested that these errors elicit stronger P600s than the other syntactic stimuli that have been implicated.[12]
- Garden paths
P600s are also known to occur when a sentence contains no outright grammatical error, but must be parsed in a different way than the reader originally expects.[13] These sentences are known as "garden path" sentences, because the reader follows one interpretation of the sentence only to realize later that this interpretation was wrong and he must backtrack to understand the sentence. For example, Osterhout & Holcomb (1992) found P600s elicited by the word to in sentences such as
The broker persuaded to sell the stock was tall.
In sentences such as this, the preferred reading is to interpret "persuaded" as the main verb of the sentence (i.e., "the broker persuaded me"), and upon seeing the word to the reader has to re-analyze the sentence to mean something more like "the broker that was persuaded to sell the stock, he was tall".[6]
- Syntactic errors in music
P600s are also elicited by errors in musical harmony, such as when a chord is played out of key with the rest of a musical phrase. This implies that P600s are not "language-specific," but "can be elicited in nonlinguistic (but rule-governed) sequences."[14]
- Dependencies and complexity
Some studies have found a P600 elicited by words where there is no grammatical error and no "garden path" (i.e., where the word is exactly what the reader would expect), but when the sentence is complex because there are a number of noun phrases active. This has most often been the case when the reader has to "re-activate" a word that appeared earlier in the sentence. For example, in a sentence like "Who did you imitate?", the word who appears in the beginning of the sentence but is actually the direct object of imitate, and must be interpreted in that way (i.e., as "you imitated who?"); several studies have found that after the reader sees the word imitate he or she has a P600 response, possibly as a result of re-activating who.[15] These sorts of P600s get stronger as the number of noun phrases active in the sentences increases, suggesting that the P600 generator is sensitive to the level of complexity in a sentence.[16][17]
- Semantic attraction
Kim & Osterhout (2005) demonstrated a so-called "semantic P600" in sentences that are grammatically correct but semantically anomalous, and in which syntactic reanalysis is more appealing than semantic reanalysis. For example, a P600 may be elicited in the following sentence:
The hearty meal was devouring the kids.
This suggests that the reader would rather interpret the sentence as containing a morphosyntactic error (saying "devouring" instead of "devoured by") rather than a semantic one (meals can't devour kids, but can be devoured by them). The interpretation of "semantic P600s" has attracted considerable attention and controversy in the literature.[18]
Interpretations
[edit]There are several theories about what computational processes the P600 may be triggered by. Because it often happens in response to grammatical violations or garden path sentences, one theory is that the P600 reflects processes of revision (i.e., trying to "rescue" the interpretation of a sentence that can't be processed normally because of structural errors) and reanalysis (i.e., trying to rearrange the structure of a sentence that has been interpreted incorrectly because of a garden path).[19][20] On the other hand, other models suggest that the P600 may not reflect these processes in particular, but just the amount of time and effort in general it takes to build up coherent structure in a sentence,[21] or the general processes of creating or destroying syntactic structure (not specifically because of repair).[22] Another proposal is that the P600 does not necessarily reflect any linguistic processes per se, but is similar to the P300 in that it is triggered when a subject encounters "improbable" stimuli—since ungrammatical sentences are relatively rare in natural speech, a P600 may not be a linguistic response but simply an effect of the subject's "surprise" upon encountering an unexpected stimulus.[23] Another account is that the P600 reflects error/surprisal propagation due to learning processes that take place during linguistic adaptation and this account has been implemented in a connectionist model that explains several P600/N400 results.[24]
See also
[edit]- Bereitschaftspotential
- C1 and P1
- Contingent negative variation
- Difference due to memory
- Early left anterior negativity
- Error-related negativity
- Late positive component
- Lateralized readiness potential
- Mismatch negativity
- N2pc
- N100
- N170
- N200
- N400
- P3a
- P3b
- P200
- P300 (neuroscience)
- Somatosensory evoked potential
- Visual N1
Notes
[edit]- ^ Different authors give slightly different time periods for the P600; for example, Kaan & Swaab (2003, p. 98) claim it may start as early as 400 milliseconds, and Friederici (2002, p. 81) describes it as occurring "between 600–1000 ms.
References
[edit]- ^ Hagoort 2007, p. 251
- ^ a b Hagoort, Brown & Osterhout 1999, p. 286
- ^ a b Gouvea et al. 2009, p. 7
- ^ a b Kaan & Swaab 2003, p. 98
- ^ Service et al. 2007, pp. 1200–1202
- ^ a b c Coulson, King & Kutas 1998, p. 26
- ^ Gouvea et al. 2009, p. 4
- ^ Coulson, King & Kutas 1998, p. 22
- ^ Friederici & Weissenborn 2007, p. 51
- ^ Hagoort, Brown & Osterhout 1999, pp. 283–84
- ^ Gouvea et al. 2009, p. 6
- ^ Gouvea et al. 2009, p. 29
- ^ Gouvea et al. 2009, p. 8
- ^ Patel, A.D.; Gibson, E.; Ratner, J.; Besson, M.; Holcomb, P.J.; et al. (1998). "Processing syntactic relations in language and music: An event-related potential study". Journal of Cognitive Neuroscience. 10 (6): 717–33. CiteSeerX 10.1.1.592.6210. doi:10.1162/089892998563121. PMID 9831740. S2CID 972521.
- ^ Gouvea et al. 2009, p. 11
- ^ Kaan & Swaab 2003, p. 99
- ^ beim Graben, Gerth & Vasishth 2008
- ^ See, for example, and the numerous references therein.
- ^ Friederici 2002, p. 79
- ^ Kaan & Swaab 2003
- ^ Hagoort 2003
- ^ Gouvea et al. 2009, p. 45
- ^ Coulson, King & Kutas 1998
- ^ Fitz, Hartmut; Chang, Franklin (2019). "Language ERPs reflect learning through prediction error propagation". Cognitive Psychology. 111: 15–52. doi:10.1016/j.cogpsych.2019.03.002. hdl:21.11116/0000-0003-474F-6. PMID 30921626. S2CID 85501792.
Bibliography
[edit]- beim Graben, Peter; Gerth, Sabrina; Vasishth, Shravan (2008). "Towards dynamical system models of language-related brain potentials". Cognitive Neurodynamics. 2 (3): 229–55. doi:10.1007/s11571-008-9041-5. PMC 2518748. PMID 19003488.
- Coulson, Seanna; King, Jonathan; Kutas, Marta (1998). "Expect the unexpected: event-related brain response to morphosyntactic violations". Language and Cognitive Processes. 13 (1): 21–58. CiteSeerX 10.1.1.359.7707. doi:10.1080/016909698386582.
- Fitz, Hartmut; Chang, Franklin (2019). "Language ERPs reflect learning through prediction error propagation". Cognitive Psychology. 111: 15–52. doi:10.1016/j.cogpsych.2019.03.002. hdl:21.11116/0000-0003-474F-6. PMID 30921626. S2CID 85501792.
- Friederici, Angela D (2002). "Towards a neural basis of auditory sentence processing" (PDF). Trends in Cognitive Sciences. 6 (2): 78–84. doi:10.1016/S1364-6613(00)01839-8. PMID 15866191.
- Friederici, Angela D; Weissenborn, Jurgen (2007). "Mapping sentence form onto meaning: the syntax-semantic interface". Brain Research. 1146: 50–8. doi:10.1016/j.brainres.2006.08.038. PMID 16956590. S2CID 14664214.
- Gouvea, Ana; Phillips, Colin; Kazanina, Nina; Poeppel, David (2009). "The linguistic processes underlying the P600".
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- Hagoort, Peter (2007). "The memory, unification, and control (MUC) model of language". In Antje S. Meyer; Linda R. Wheeldon; Andrea Krott (eds.). Automaticity and Control in Language Processing. Advances in Behavioural Brain Science. ISBN 978-1-84169-650-8.
- Hagoort, Peter; Brown, Colin; Osterhout, Lee (1999). "The neurocognition of syntactic processing". The Neurocognition of Language. New York: Oxford University Press. ISBN 978-0-19-852448-9.
- Kaan, Edith; Swaab, Tamara (2003). "Repair, revision, and complexity in syntactic analysis: an electrophysiological differentiation" (PDF). Journal of Cognitive Neuroscience. 15 (1): 98–110. doi:10.1162/089892903321107855. PMID 12590846. S2CID 14934107.
- Kim, Albert; Osterhout, Lee (2005). "The independence of combinatory semantic processing: evidence from event-related potentials". Journal of Memory and Language. 52 (2): 205–225. CiteSeerX 10.1.1.115.4927. doi:10.1016/j.jml.2004.10.002.
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- Service, Elisabet; Helenius, Paivi; Maury, Sini; Salmelin, Riitta (2007). "Localization of syntactic and semantic brain responses using magnetoencephalography". Journal of Cognitive Neuroscience. 19 (7): 1193–205. doi:10.1162/jocn.2007.19.7.1193. PMID 17583994. S2CID 24251261.