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Experimental Brain Research
Published in: Experimental Brain Research 3/2017

Open Access 01-03-2017 | Research Article

Executive control and working memory are involved in sub-second repetitive motor timing

Authors: Linus Holm, Olympia Karampela, Fredrik Ullén, Guy Madison

Published in: Experimental Brain Research | Issue 3/2017

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Abstract

The nature of the relationship between timing and cognition remains poorly understood. Cognitive control is known to be involved in discrete timing tasks involving durations above 1 s, but has not yet been demonstrated for repetitive motor timing below 1 s. We examined the latter in two continuation tapping experiments, by varying the cognitive load in a concurrent task. In Experiment 1, participants repeated a fixed three finger sequence (low executive load) or a pseudorandom sequence (high load) with either 524-, 733-, 1024- or 1431-ms inter-onset intervals (IOIs). High load increased timing variability for 524 and 733-ms IOIs but not for the longer IOIs. Experiment 2 attempted to replicate this finding for a concurrent memory task. Participants retained three letters (low working memory load) or seven letters (high load) while producing intervals (524- and 733-ms IOIs) with a drum stick. High load increased timing variability for both IOIs. Taken together, the experiments demonstrate that cognitive control processes influence sub-second repetitive motor timing.
Literature
Baddeley A (1966) The capacity for generating information by randomization. Q J Exp Psychol 18:119–129CrossRefPubMed
Baddeley A, Emslie H, Kolodny J, Duncan J (1998) Random generation and the executive control of working memory. Q J Exp Psychol A 51:819–852CrossRefPubMed
Brown SW (1997) Attentional resources in timing: interference effects in concurrent temporal and nontemporal working memory tasks. Percept Psychophys 59:1118–1140CrossRefPubMed
Brown SW (2006) Timing and executive function: bidirectional interference between concurrent temporal production and randomization tasks. Mem Cogn 34:1464–1471CrossRef
Buhusi CV, Meck WH (2005) What makes us tick? Functional and neural mechanisms of interval timing. Nat Rev Neurosci 6(10):755–765CrossRefPubMed
Deary IJ, Der G, Ford G (2001) Reaction times and intelligence differences:a population-based cohort study. Intelligence 29:389–399CrossRef
Galton F (1883) Inquiries into human faculty and its development. Macmillan, LondonCrossRef
Getty D (1975) Discrimination of short temporal intervals: a comparison of two models. Percept Psychophys 18:1–8CrossRef
Hiscock M, Cheesman J, Inch R, Chipuer HM (1989) Rate and variability of finger tapping as measures of lateralized concurrent task effects. Brain Cogn 10:87–104CrossRefPubMed
Holm L, Madison G (2013) Whenever next: hierarchical timing. commentary on clark. Behav Brain Sci 36(3):37–38CrossRef
Holm L, Ullén F, Madison G (2011) Intelligence and temporal accuracy of behavior: unique and shared associations between intelligence, reaction time and motor timing. Exp Brain Res 214:175–183CrossRefPubMed
Holm L, Ullén F, Madison G (2013) Motor and executive control in repetitive timing of brief intervals. J Exp Psychol Hum Percept Perform 39:365–380CrossRefPubMed
Ivry RB, Hazeltine RE (1995) Perception and production of temporal intervals across a range of durations: evidence for a common timing mechanism. J Exp Psychol: Hum Percept Perform 21(1):3–18
Jahanshahi M, Dirnberger G, Fuller R, Frith CD (2000) The role of the dorsolateral prefrontal cortex in random number generation: a study with positron emission tomography. Neuroimage 12:713–725CrossRefPubMed
Jensen AR (2006) Clocking the mind: mental chronometry and individual differences. Elsevier, Oxford
Karatekin C, Couperus JW, Marcus DJ (2004) Attention allocation in the dual-task paradigm as measured through behavioral and psychological responses. Psychophysiology 41:175–185CrossRefPubMed
Kaspar F, Schuster HG (1987) Easily calculable measure for the complexity of spatiotemporal patterns. Phys Rev A 36:842–847CrossRef
Kee DW, Morris K, Bathurst K, Hellige J (1986) Lateralized interference in finger tapping: comparisons of rate and variability measures under speed and consistency tapping instructions. Brain Cogn 5:268–279CrossRefPubMed
Lempel A, Ziv J (1976) On the complexity of finite sequences. IEEE Trans Inf Theory 22:75–81CrossRef
Levenshtein VI (1966) Binary codes capable of correcting deletions, insertions and reversals. Sov Phys Dokl 6:707–710
Lewis PA, Miall RC (2003) Distinct systems for automatic and cognitively controlled time measurement: evidence from neuroimaging. Curr Opin Neurobiol 13:250–255CrossRefPubMed
Logie R, Maylor EA, Della Sala S, Smith G (2004) Working memory in event- and time-based prospective memory tasks: effects of secondary demand and age. Eur J Cogn Psychol 16:441–456CrossRef
Madison G (2001) Variability in isochronous tapping: higher-order dependencies as a function of inter tap interval. J Exp Psychol Hum Percept Perform 27:411–422CrossRefPubMed
Madison G (2004) Fractal modeling of human isochronous serial interval production. Biol Cybern 90:105–112CrossRefPubMed
Madison G, Delignières D (2009) Auditory feedback affects the long-range correlation of isochronous serial interval production. support for a closed-loop or memory model of timing. Exp Brain Res 193:519–527CrossRefPubMed
Madison G, Merker B (2004) Human sensorimotor tracking of continuous subliminal deviations from isochrony. Neurosci Lett 370:69–73CrossRefPubMed
Madison G, Forsman L, Blom Ö, Karabanov A, Ullén F (2009) Correlations between general intelligence and components of serial timing variability. Intelligence 37:68–75CrossRef
Madison G, Karampela O, Ullén F, Holm L (2013) Effects of practice on variability in an isochronous serial interval production task: asymptotical levels of tapping variability after training are similar to those of musicians. Acta Psychol 143:119–128CrossRef
Maes P-J, Wanderley AA, Palmer C (2015) The role of working memory in the temporal control of discrete and continuous movements. Exp Brain Res 233:263–273CrossRefPubMed
Mantini D, Corbetta M, Romani GL, Orban GA, Vanduffel W (2013) Evolutionarily novel functional networks in the human brain? J Neurosci 20:3259–3275CrossRef
Marsh RL, Hicks JL (1998) Event-based prospective memory and executive control of working memory. J Exp Psychol Learn Mem Cogn 24:336–349CrossRefPubMed
McFarland K, Ashton R (1978) The influence of concurrent task difficulty on manual performance. Neuropsychologia 16:735–741CrossRefPubMed
Merchant H, Zarco W, Bartolo R, Prado L (2008) The context of temporal processing is represented in the multidimensional relationships between timing tasks. PLoS ONE 3:e3169 1–e3169 9CrossRef
Merchant H, Harrington DL, Meck WH (2013) Neural basis of the perception and estimation of time. Annu Rev Neurosci 36(1):313–336CrossRefPubMed
Michon J (1964) Studies on subjective duration: I. Differential sensitivity in the perception of repeated temporal intervals. Acta Psychol 22:441–450CrossRef
Miyake A, Friedman NP, Emerson MJ, Witski AH, Howerter A, Wager TD (2000) The unity and diversity of executive functions and their contributions to complex “frontal lobe” tasks: a latent variable analysis. Cogn Psychol 41:49–100CrossRefPubMed
Nagasaki H (1990) Rhythm in periodic tapping is centrally produced. Percept Mot Skills 71:985–986CrossRef
Niendam TA, Laird AR, Ray LR, Dean MY, Glahn DC, Carter CS (2012) Meta-analytic evidence for a superordinate cognitive network subserving diverse executive functions. Cogn Affect Behav Neurosci 12:241–268CrossRefPubMedPubMedCentral
Owen AM, McMillan KM, Laird AR, Bullmore E (2005) N-back working memory paradigm: a meta-analysis of normative functional neuroimaging studies. Hum Brain Mapp 25:46–59CrossRefPubMed
Rammsayer TH (1999) Neuropharmacological evidence for different timing mechanisms in humans. Q J Exp Psychol B 52:273–286CrossRefPubMed
Rammsayer TH, Troche SJ (2014) In search of the internal structure of the processes underlying interval timing in the sub-second and the second range: a confirmatory factor analysis approach. Acta Psychol 147:68–74CrossRef
Repp BH (2006) Does an auditory distractor sequence affect self-paced tapping? Acta Psychol 121:81–107CrossRef
Schneider S, Joppich G, van der Lugt A, Däuper J, Münte TF (2004) Brain potentials and self-paced random number generation in humans. Neurosci Lett 367:51–55CrossRefPubMed
Sergent V, Hellige J, Cherry B (1993) Effects of responding hand and concurrent verbal processing on time-keeping and motor-implementation processes. Brain Cogn 23:243–262CrossRefPubMed
Siegle GJ, Ichikawa N, Steinhauer S (2008) Blink before you think: blinks occur prior to and following cognitive load indexed by pupillary responses. Psychophysiology 45:679–687CrossRefPubMed
Silverman I (2012) Simple reaction time: it is not what it used to be. Am J Psychol 123:39–50CrossRef
Troche S, Rammsayer TH (2011) Temporal information processing and mental ability: a new perspective. In: Multidisciplinary aspects of time and time perception–COST TD0904 international workshop. Athens, Greece, October 7–8, 2010, pp 186–195
Ullén F, Forsman L, Blom Ö, Karabanov A, Madison G (2008) Intelligence and variability in a simple timing task share neural substrates in the prefrontal white matter. J Neurosci 28:4239–4243CrossRef
Ullén F, Söderlund T, Kääriä L, Madison G (2012) Bottom-up mechanisms are involved in the relation between accuracy in timing tasks and intelligence-further evidence using manipulations of state motivation. Intelligence 40(2):100–106CrossRef
Ullén F, Mosing MA, Madison G (2015) Associations between motor timing, music practice, and intelligence studied in a large sample of twins. Ann N Y Acad Sci 1337:125–129CrossRefPubMed
Veltman DJ, Rombouts SARB, Dolan RJ (2003) Maintenance versus manipulation in verbal working memory revisited: an fMRI study. Neuroimage 18:247–256CrossRefPubMed
Wing AM, Kristofferson A (1973) Response delays and the timing of discrete motor responses. Percept Psychophys 14:5–12CrossRef
Zarco W, Merchant H, Prado L, Mendez JC (2009) Subsecond timing in primates: comparison of interval production between human subjects and rhesus monkeys. J Neurophysiol 102:3191–3202CrossRefPubMedPubMedCentral
Metadata
Title
Executive control and working memory are involved in sub-second repetitive motor timing
Authors
Linus Holm
Olympia Karampela
Fredrik Ullén
Guy Madison
Publication date
01-03-2017
Publisher
Springer Berlin Heidelberg
Published in
Experimental Brain Research / Issue 3/2017
Print ISSN: 0014-4819
Electronic ISSN: 1432-1106
DOI
https://doi.org/10.1007/s00221-016-4839-6

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