Abstract
Growing evidence indicates that syntax and semantics are the basic aspects of music. After the onset of a chord, initial music-syntactic processing can be observed at about 150–400 ms and processing of musical semantics at about 300–500 ms. Processing of musical syntax activates inferior frontolateral cortex, ventrolateral premotor cortex and presumably the anterior part of the superior temporal gyrus. These brain structures have been implicated in sequencing of complex auditory information, identification of structural relationships, and serial prediction. Processing of musical semantics appears to activate posterior temporal regions. The processes and brain structures involved in the perception of syntax and semantics in music have considerable overlap with those involved in language perception, underlining intimate links between music and language in the human brain.
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References
Avanzini G, Faienza C, Miniacchi D, Lopez L, Majno M (2003) The Neurosciences and Music. Annals of the New York Academy of Sciences 999. This book provides another extensive overview of the different fields investigated within neurocognition of music
Baumgaertner A, Weiller C, Büchel C (2002) Event-related fMRI reveals cortical sites involved in contextual sentence integration. Neuroimage 16, 736–745
Besson M, Faita F (1995) An event-related potential study of musical expectancy: Comparison of musicians with nonmusicians. J Exp Psych: Hum Perc Perf 21, 1278–1296
Conway CM, Christiansen MH (2001) Sequential learning in nonhuman primates. Trends Cogn Sci 5, 539–546
Doeller CF, Opitz B, Mecklinger A, Krick C, Reith W, Schroger E (2003) Prefrontal cortex involvement in preattentive auditory deviance detection: neuroimaging and electrophysiological evidence. NeuroImage 20, 1270–1282
Fernald A (1989) Intonation and communicative intent in mothers’ speech to infants: is the melody the message? Child Dev 60, 1497–1510
Friederici AD (2002) Towards a neural basis of auditory sentence processing. Trends Cogn Sci 6, 78–84
Friederici AD, Wang Y, Herrmann CS, Maess B, Oertel U (2000) Localisation of early syntactic processes in frontal and temporal cortical areas: An MEG study. Hum Brain Mapp 11, 1–11
Friederici AD, Rüschemeyer S, Hahne A, Fiebach CJ (2003) The role of left inferior frontal and superior temporal cortex in sentence comprehension: localizing syntactic and semantic processes. Cereb Cortex 13, 170–177
Gaab N, Gaser C, Zaehle T, Jancke L, Schlaug G (2003) Functional anatomy of pitch memory — an fMRI study with sparse temporal sampling. Neuroimage 19, 1417–1426
Heinke W, Kenntner R, Gunter TC, Sammler D, Olthoff D, Koelsch S (2004) Differential effects of increasing propofol sedation on frontal and temporal cortices: an ERP study. Anesthesiology 100, 617–625. Using ERPs and music, the authors investigated the effects of sedative drugs (propofol) on auditory processing. It was found that propofol affects at lower doses processing of ‘higher’ cognitive functions located in multimodal cortex, whereas functions located in primary auditory cortical areas remain unaffected
Huettel SA, Mack PB, McCarthy G (2002) Perceiving patterns in random series: dynamic processing of sequence in prefrontal cortex. Nat Neurosci 5, 485–490
Janata P (1995) ERP measures assay the degree of expectancy violation of harmonic contexts in music. J Cogn Neurosci 7, 153–164
Janata P, Birk JL, Van Horn JD, Leman M, Tillmann B, Bharucha JJ (2002) The cortical topography of tonal structures underlying Western music. Science 298, 2167–2170
Janata P, Grafton ST (2003) Swinging in the brain: shared neural substrates for behaviors related to sequencing and music. Nat Neurosci 6, 682–687
Jusczyk PW, Krumhansl CL (1993) Pitch and rhythmic patterns affecting infants’ sensitivity to musical phrase structure. J Exp Psychol Hum Percept Perform 19, 627–640
Knoesche TR, Neuhaus C, Haueisen J, Alter K, Maess B, Witte OW, Friederici AD (2005) The Perception of Phrase Structure in Music. Human Brain Mapp (in press)
Koelsch S, Gunter TC, Friederici AD, Schroger E (2000) Brain indices of music processing: ‘non-musicians’ are musical. J Cog Neurosci 12, 520–541
Koelsch S, Gunter TC, v Cramon DY, Zysset S, Lohmann G, Friederici AD (2002a) Bach speaks: a cortical “language-network” serves the processing of music. Neuroimage 17, 956–966
Koelsch S, Schmidt BH, Kansok J (2002b) Influences of musical expertise on the ERAN: An ERP-study. Psychophysiology 39, 657–663
Koelsch S, Grossmann T, Gunter TC, Hahne A, Friederici AD (2003) Children processing music: electric brain responses reveal musical competence and gender differences. J Cogn Neurosci 15, 683–693
Koelsch S, Kasper E, Sammler D, Schulze K, Gunter TC, Friederici AD (2004) Music, language, and meaning: brain signatures of semantic processing. Nat Neurosci 7, 302–307. Using ERPs and a priming paradigm the authors show that music can activate representations of meaningful concepts. This is the first study to show that music can transfer meaningful information, and that this transfer relies on those neurophysiological processes engaged for the processing of semantics in language
Koelsch S, Fritz T, Schulze K, Alsop D, Schlaug G (2005) Adults and Children Processing Music: An fMRI Study. NeuroImage (in press)
Kutas M, Federmeier KD (2000) Electrophysiology reveals semantic memory use in language comprehension. Trends Cogn Sci 4, 463–470
Maess B, Koelsch S, Gunter TC, Friederici AD (2001) ‘Musical syntax’ is processed in Broca’s area: an MEGstudy. Nat Neurosci 4, 540–545
Meyer LB (1956) Emotion and Meaning in Music. University of Chicago Press, Chicago
Patel A (2003) Language, music, syntax and the brain. Nat Neurosci 6, 674–681
Patel AD, Gibson E, Ratner J, Besson M, Holcomb PJ (1998) Processing syntactic relations in language and music: an event-related potential study. J Cogn Neurosci 10, 717–733
Pinker S (1997) How the mind works. Norton
Regnault P, Bigand E, Besson M (2001) Different brain mechanisms mediate sensitivity to sensory consonance and harmonic context: evidence from auditory event-related brain potentials. J Cogn Neurosci 13, 241–255
Schon D, Magne C, Besson M (2004) The music of speech: music training facilitates pitch processing in both music and language. Psychophysiology 41, 341–349
Schubotz RI, von Cramon DY (2002) Predicting perceptual events activates corresponding motor schemes in lateral premotor cortex: an fMRI study. Neuroimage 15(4), 787–796
Steinhauer K, Alter K, Friederici AD (1999) Brain potentials indicate immediate use of prosodic cues in natural speech processing. Nat Neurosci 2, 191–196
Tillmann B, Bharucha J, Bigand E (2000) Implicit learning of tonality: a self-organized approach. Psychol Rev 107, 885–913
Tillmann B, Janata P, Bharucha JJ (2003) Activation of the inferior frontal cortex in musical priming. Brain Res Cogn Brain Res 16, 145–161
Trehub S (2003) The developmental origins of musicality. Nat Neurosci 6, 669–673
Zatorre RJ, Belin P, Penhune VB (2002) Structure and function of auditory cortex: music and speech. Trends Cogn Sci 6, 37–46
Zatorre RJ, Peretz I (2003) The Cognitive Neuroscience of Music. Oxford University Press. This book provides an extensive overview of the different fields investigated within neurocognition of music
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Koelsch, S. (2009). Neural substrates of processing syntax and semantics in music. In: Haas, R., Brandes, V. (eds) Music that works. Springer, Vienna. https://doi.org/10.1007/978-3-211-75121-3_9
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DOI: https://doi.org/10.1007/978-3-211-75121-3_9
Publisher Name: Springer, Vienna
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