Music, clicks, and their imaginations favor differently the event-based timing component for rhythmic movements
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- 作者:Riccardo Bravi ; Eros Quarta ; Claudia Del Tongo…
- 关键词:Sensory ; motor integration ; Timing ; Isochronous movements ; Auditory imagery ; Music
- 刊名:Experimental Brain Research
- 出版年:2015
- 出版时间:June 2015
- 年:2015
- 卷:233
- 期:6
- 页码:1945-1961
- 全文大小:1,388 KB
- 参考文献:Aleman A, Nieuwenstein MR, Boecker KBE, de Hann EHF (2000) Music training and mental imagery ability. Neuropsychologia 38:1664-668. doi:10.-016/?S0028-3932(00)00079-8 View Article PubMed
Allan LG (1979) The perception of time. Percept Psychophys 26:340-54View Article
Baer LH, Thibodeau JL, Gralnick TM, Li KZ, Penhune VB (2013) The role of musical training in emergent and event-based timing. Front Hum Neurosci 7:191. doi:10.-389/?fnhum.-013.-0191 View Article PubMed Central PubMed
Balasubramaniam R, Wing AM, Daffertshofer A (2004) Keeping with the beat: movement trajectories contribute to movement timing. Exp Brain Res 159:129-34. doi:10.-007/?s00221-004-2066-z PubMed
Bishop L, Bailes F, Dean RT (2013) Musical expertise and the ability to imagine loudness. PLoS ONE 8:e56052. doi:10.-371/?journal.?pone.-056052 View Article PubMed Central PubMed
Bravi R, Del Tongo C, Cohen EJ, Dalle Mura G, Tognetti A, Minciacchi D (2014a) Modulation of isochronous movements in a flexible environment: links between motion and auditory experience. Exp Brain Res 232:1663-675. doi:10.-007/?s00221-014-3845-9 View Article PubMed
Bravi R, Quarta E, Cohen EJ, Gottard A, Minciacchi D (2014b) A little elastic for a better performance: kinesiotaping of the motor effector modulates neural mechanisms for rhythmic movements. Front Syst Neurosci 8:181. doi:10.-389/?fnsys.-014.-0181 View Article PubMed Central PubMed
Brodsky W, Henik A, Rubinstein B, Zorman M (2003) Auditory imagery from musical notation in expert musicians. Percept Psychophys 65:602-12. doi:10.-758/?BF03194586 View Article PubMed
Cannam C, Landone C, Sandler M (2010) Sonic visualiser: an open source application for viewing, analysing, and annotating music audio files. In: Proceedings of ACM multimedia 2010 international conference. doi:10.-145/-873951.-874248
Collier GL, Ogden RT (2004) Adding drift to the composition of simple isochronous tapping: an extension of the Wing-Kristofferson model. J Exp Psychol Hum Percept Perform 30:853-72. doi:10.-037/-096-1523.-0.-.-53 View Article PubMed
Coull JT, Cheng R, Meck WH (2011) Neuroanatomical and neurochemical substrates of timing. Neuropsychopharmacol 36:3-5. doi:10.-038/?npp.-010.-13 View Article
Dannenberg RB, Mohan S (2011) Characterizing tempo change in musical performances. In: ICMC Proceedings. Publishing, Ann Arbor, MI
Delignières D, Torre K (2011) Event-based and emergent timing: dichotomy or continuum? A reply to Repp and Steinman (2010). J Mot Behav 43:311-18. doi:10.-080/-0222895.-011.-88274 View Article PubMed
Delignières D, Lemoine L, Torre K (2004) Time intervals production in tapping and oscillatory motion. Hum Mov Sci 23:87-03. doi:10.-016/?j.?humov.-004.-7.-01 View Article PubMed
Elliott MT, Welchman AE, Wing AM (2009) Being discrete helps keep to the beat. Exp Brain Res 192:731-37. doi:10.-007/?s00221-008-1646-8 View Article PubMed
Ellis M (1991) Thresholds for detecting tempo change. Psychol Music 19:164-69. doi:10.-177/-305735691192007-/span> View Article
Fraisse P (1982) Rhythm and Tempo. In: Deutsch D (ed) The psychology of music. Academic Press, New York, NY, pp 149-80View Article
Freyer F, Reinacher M, Nolte G, Dinse HR, Ritter P (2012) Repetitive tactile stimulation changes resting-state functional connectivity-implications for treatment of sensorimotor decline. Front Hum Neurosci 6:144. doi:10.-389/?fnhum.-012.-0144 View Article PubMed Central PubMed
Fujioka T, Trainor LJ, Ross B, Kakigi R, Pantev C (2004) Musical training enhances automatic encoding of melodic contour and interval structure. J Cogn Neurosci 16:1010-021. doi:10.-162/-898929041502706-/span> View Article PubMed
Fujioka T, Trainor LJ, Ross B, Kakigi R, Pantev C (2005) Automatic encoding of polyphonic melodies in musicians and nonmusicians. J Cogn Neurosci 17:1578-592. doi:10.-162/-898929057745972-3 View Article PubMed
Halpern AR (1992) Musical aspects of auditory imagery. In: Reisberg D (ed) Auditory imagery. Erlbaum, Hillsdale, NJ, pp 1-7
Herholz SC, Lappe C, Knief A, Pantev C (2008) Neural basis of music imagery and the effect of musical expertise. Eur J Neurosci 28:2352-360. doi:10.-111/?j.-460-9568.-008.-6515.?x View Article PubMed
Herholz SC, Halpern AR, Zatorre RJ (2012) Neuronal correlates of perception, imagery, and memory for familiar tunes. J Cogn Neurosci 24:1382-397. doi:10.-162/?jocn_?a_-0216 View Article PubMed
Huang J, Gamble D, Sarnlertsophon K, Wang X, Hsiao S (2012) Feeling music: integration of auditory and tactile inputs in musical meter perception. PLoS ONE 7:e48496. doi:10.-371/?journal.?pone.-048496 View Article PubMed Central PubMed
Hubbard TL (2010) Auditory imagery: empirical findings. Psychol Bull 136:302-29. doi:10.-037/?a0018436 View Article PubMed
Hunt N, McGrath D, Stergiou N (2014) The influence of auditory-motor coupling on fractal dynamics - 作者单位:Riccardo Bravi (1)
Eros Quarta (1)
Claudia Del Tongo (1)
Nicola Carbonaro (2)
Alessandro Tognetti (2) (3)
Diego Minciacchi (1)
1. Department of Experimental and Clinical Medicine, Physiological Sciences Section, University of Florence, Viale Morgagni 63, 50134, Florence, Italy
2. Research Center E. Piaggio, University of Pisa, Via Diotisalvi 2, Pisa, Italy
3. Information Engineering Department, University of Pisa, Via Caruso 2, Pisa, Italy - 刊物类别:Biomedical and Life Sciences
- 刊物主题:Biomedicine
Neurosciences
Neurology - 出版者:Springer Berlin / Heidelberg
- ISSN:1432-1106
文摘
The involvement or noninvolvement of a clock-like neural process, an effector-independent representation of the time intervals to produce, is described as the essential difference between event-based and emergent timing. In a previous work (Bravi et al. in Exp Brain Res 232:1663-675, 2014a. doi:10.-007/?s00221-014-3845-9), we studied repetitive isochronous wrist’s flexion–extensions (IWFEs), performed while minimizing visual and tactile information, to clarify whether non-temporal and temporal characteristics of paced auditory stimuli affect the precision and accuracy of the rhythmic motor performance. Here, with the inclusion of new recordings, we expand the examination of the dataset described in our previous study to investigate whether simple and complex paced auditory stimuli (clicks and music) and their imaginations influence in a different way the timing mechanisms for repetitive IWFEs. Sets of IWFEs were analyzed by the windowed (lag one) autocorrelation—wγ(1), a statistical method recently introduced for the distinction between event-based and emergent timing. Our findings provide evidence that paced auditory information and its imagination favor the engagement of a clock-like neural process, and specifically that music, unlike clicks, lacks the power to elicit event-based timing, not counteracting the natural shift of wγ(1) toward positive values as frequency of movements increase.