Brain areas involved in the control of speed during a motor sequence of the foot: Real movement versus mental imagery

Journal of Neuroradiology

Volumn 40, Issue 4, 2013, Pages 267-280

  Sauvage, C ^a   Jissendi, P ^a   Seignan, S ^a   Manto, M ^b   Habas, C ^c  

^a ERASME HOSPITAL   (Belgium)

^b FNRS   (Belgium)

^c CENTRE HOSPITALIER NATIONAL D OPHTALMOLOGIE DES QUINZE VINGTS   (France)

Author keywords

A; AC; Basal ganglia; CER; Cerebellum; CING; CN; DLPFC; DMPFC; DN; FMRI; FOP; FPC; GLM; INS; L; LN; M1 S1; ME; MI; MIQ R; Motor execution; Motor imagery; OCC; OFC; P; PCC; PMC; PO; PrC; Pre SMA; PREC; R; SD; SMC; SPC; THAL; Velocity; VER

Indexed keywords

ADULT; ANKLE; ARTICLE; BRAIN CORTEX; BRAIN REGION; CEREBELLUM; CEREBELLUM VERMIS; CINGULATE GYRUS; CONSCIOUSNESS; CORPUS STRIATUM; EXECUTIVE FUNCTION; FEMALE; FOOT MOVEMENT; HUMAN; HUMAN EXPERIMENT; IMAGERY; IMAGINATION; JOINT FUNCTION; LIMB MOVEMENT; MALE; MOTOR CONTROL; MOTOR PERFORMANCE; NERVE CELL NETWORK; NORMAL HUMAN; NUCLEAR MAGNETIC RESONANCE IMAGING; PARIETAL CORTEX; PREFRONTAL CORTEX; PREMOTOR CORTEX; SENSORIMOTOR CORTEX; TASK PERFORMANCE; VELOCITY; VOLUNTARY MOVEMENT; VOLUNTEER;

A; AC; ANGULARIS CORTEX; ANTERIOR; BASAL GANGLIA; CAUDATE NUCLEUS; CER; CEREBELLUM; CING; CINGULATE CORTEX; CN; DENTATE NUCLEUS; DLPFC; DMPFC; DN; DORSOLATERAL PREFRONTAL CORTEX; DORSOMEDIAN PREFRONTAL CORTEX; FMRI; FOP; FPC; FRONTO-OPERCULAR CORTEX; FRONTOPOLAR CORTEX; GLM; INS; INSULA; L; LEFT; LENTIFORM NUCLEUS; LN; M1/S1; ME; MI; MIQ-R; MOTOR EXECUTION; MOTOR IMAGERY; MOTOR IMAGINATION; MOVEMENT IMAGERY QUESTIONNAIRE-REVISED; OCC; OCCIPITAL CORTEX; OFC; ORBITOFRONTAL CORTEX; P; PCC; PMC; PO; POSTERIOR; PPARIETAL OPERCULE; PRC; PRE-SMA; PRE-SUPPLEMENTARY MOTOR AREA; PREC; PRECENTRAL (PREMOTOR) CORTEX; PRECENTRAL CORTEX; PRECUNEUS; PREMOTOR CORTEX; R; RIGHT; SD; SENSORIMOTOR CORTEX; SMC; SPC; STANDARD DEVIATION; SUPERIOR PARIETAL CORTEX; SUPRAMARGINAL CORTEX; THAL; THALAMUS; VELOCITY; VER; VERMIS;

ADULT; ANKLE JOINT; BRAIN; BRAIN MAPPING; EVOKED POTENTIALS, MOTOR; FEEDBACK, PHYSIOLOGICAL; FEMALE; HUMANS; IMAGINATION; MALE; MOVEMENT; NERVE NET; PHYSICAL EXERTION; PSYCHOMOTOR PERFORMANCE;

EID: 84885841167     PISSN: 01509861     EISSN: 17730406     Source Type: Journal    
DOI: 10.1016/j.neurad.2012.10.001     Document Type: Article

References (60)

1. Thach W.T., Goodkin H.G., Keating J.G. Cerebellum and the adaptative coordination of movement. Ann Rev Neurosci 1992, 15:403-442.
2. Coffman K.A., Dum R.P., Strick P.L. Cerebellar vermis is a target of projections from the motor areas in the cerebral cortex. Proc Natl Acad Sci USA 2011, 108:16068-16073.
3. Manto M. Physiology of the cerebellum. Cerebellar disorders. A practical approach to diagnosis and management 2010, Cambridge University Press, Cambridge, United Kingdom.
4. Ebner T., Pasalar S. Cerebellum predicts the future motor state. Cerebellum 2008, 7:583-588.
5. Annett J. Motor imagery: perception or action?. Neuropsychologia 1995, 33:1395-1417.
6. Kosslyn S.M., Ganis G., Thompson W.L. Neural foundations in imagery. Nat Rev Neurosci 2001, 2(9):635-642.
7. Lotze M., Halsband U. Motor imagery. J Physiol Paris 2006, 99:386-395.
8. Mulder T. Motor imagery and action observation: cognitive tools for rehabilitation. J Neural Transmis 2007, 114:1265-1278.
9. Ciccarelli O., Toosy A.T., Marsden J.F., Wheeler-Kingshott C.M., Sahyoun J.F., Matthews P.M., et al. Identifying brain regions for integrative sensorimotor processing with ankle movements. Exp Brain Res 2005, 166:31-42.
10. Binkofski F., Amunts K., Stephan K.M., Posse S., Schormann T., Freund H.J., et al. Broca's region subserves imagery of motion: a combined cytoarchitectonic and fMRI study. Hum Brain Mapp 2000, 11:273-285.
11. Ruby P., Decety J. Effect of subjective perspective taking during simulation of action: a PET investigation of agency. Nat Neurosci 2001, 4(5):546-550.
12. Li C.R. Impairment of motor imagery in putamen lesions in humans. Neurosci Lett 2000, 287:13-16.
13. Guillot A., Collet C., Nguyen V.A., Malouin F., Richards C., Doyon J. Functional neuroanatomical networks associated with expertise in motor imagery. NeuroImage 2008, 41:1471-1483.
14. Jackson P.L., Lafleur M.F., Malouin F., Richards C., Doyon J. Potential role of mental practice using motor imagery in neurologic rehabilitation. Arch Phys Med Rehabil 2001, 82:1133-1141.
15. Sauvage C., Poirriez S., Manto M., Jissendi P., Habas C. Reevaluating brain networks activated during mental imagery of finger movements using probabilistic Tensorial Independent Component Analysis (TICA). Brain Imaging Behav 2011, 5:137-148.
16. Decety J., Grèzes J. Neural mechanisms subserving the perception of human actions. Trends Cogn Sci 1999, 3:172-178.
17. Lotze M., Cohen L.G. Volition and imagery in neurorehabilitation. Cogn Behav Neurol 2006, 19:135-140.
18. Jeannerod M. Neural simulation of action: a unifying mechanism for motor cognition. NeuroImage 2001, 14:S103-S109.
19. Ebner T. Cerebellum and internal models. Handbook of the cerebellum and cerebellar disorders 2012, 1281-1296. Springer, New York. M. Manto, D. Gruol, J.D. Schmahmann, N. Koibuchi, F. Rossi (Eds.).
20. Chan R.C.K., Huang J., Di X. Dexterous movement complexity and cerebellar activation: a meta-analysis. Brain Res Rev 2009, 59:316-323.
21. Chapman J.P., Chapman L.J., Allen J.A. The measurement of foot preference. Neuropsychologia 1987, 25-3:579-584.
22. Lorant J., Nicolas A. Validation de la traduction française du Movement Imagery Questionnaire-Revised (MIQ-R). Sci Motr 2004, 53:57-68.
23. Hanakawa T., Immisch I., Toma K., Dimyan M.A., Van Gelderen P., Hallett M. Functional properties of brain areas associated with motor execution and imagery. J Neurophysiol 2003, 89(2):989-1002.
24. Cramer S.C., Orr E.L.R., Cohen M.J., Lacourse M.G. Effects of motor imagery training after chronic, complete spinal cord injury. Exp Brain Res 2007, 177:233-242.
25. Lacourse M.G., Orr E.L.R., Cramer S.C., Cohen M.J. Brain activation during execution and motor imagery of novel and skilled sequential hand movements. NeuroImage 2005, 27:505-519.
26. Higuchi S., Imamizu H., Kawato M. Cerebellar activity evoked by common tool-use execution and imagery tasks: an fMRI study. Cortex 2007, 43:350-358.
27. Munzert J., Lorey B., Zentgraf K. Cognitive motor processes: the role of motor imagery in the study of motor representations. Brain Res Rev 2009, 60:306-326.
28. Bestmann S., Swayne O., Blankenburg F., Ruff C.C., Haggard P., et al. Dorsal premotor cortex exerts state-dependant causal influences on activity in contralateral primary motor and dorsal premotor cortex. Cereb Cortex 2008, 18:1281-1291.
29. Cincotta M., Ziemann U. Neurophysiology of unimanual motor control and mirror movements. Clin Neurophysiol 2008, 119:744-762.
30. Agnew J.A., Zeffiro T.A., Eden G.F. Left hemisphere specialization for the control of voluntary movement rate. NeuroImage 2004, 22:289-303.
31. Van den Berg F.E., Swinnen S.P., Wenderoth N. Excitability of the motor cortex ipsilateral to the moving body side depends on spatiotemporal task complexity and hemispheric specialization. PLOS One 2011, 6:e17742.
32. Johannsen P., Christensen L.O.D., Sinkjaer T., Nielsen J.B. Cerebral functional anatomy of voluntary contractions of ankle muscles in man. J Physiol 2001, 535:397-406.
33. Deiber M.P., Ibañez V., Honda M., Sadato N., Raman R., Hallett M. Cerebral processes related to visuomotor imagery and generation of simple finger movements studied with positron emission tomography. NeuroImage 1998, 7:73-85.
34. Gerardin E., Sirigu A., Lehéricy S., Poline J.B., Gaymard B., Marsault C., et al. Partially overlapping neural networks for real and imagined hand movements. Cereb Cortex 2000, 10:1093-1104.
35. Dechent P., Merboldt K.D., Frahm J. Is the human primary motor cortex involved in motor imagery?. Brain Res Cogn Brain Res 2004, 19:138-144.
36. Naito E., Kochiyama T., Kitada R., Nakamura S., Matsumura M., Yonekura Y., et al. Internally simulated movement sensations during motor imagery activate cortical motor areas and the cerebellum. J Neurosci 2002, 22(9):3683-3691.
37. Purves D., Augustine G.J., Fitzpatrick D., Hall W.C., LaMantia A.S., McNamara J.O., et al. Neurosciences 2005, Editions De Boeck, Bruxelles. 3rd ed.
38. Lafleur M.F., Jackson P.L., Malouin F., Richards C.L., Evans A.C., Doyon J. Motor learning produces parallel dynamic functional changes during the execution and imagination of sequential foot movements. NeuroImage 2002, 16:142-157.
39. La Fougère C., Zwergal A., Rominger A., Förster S., Fesl G., Dieterich M., et al. Real versus imagined locomotion: a [18F]-FDG PET-fMRI comparison. NeuroImage 2010, 50:1589-1599.
40. Bode S., Koeneke S., Jänke L. Different strategies do not moderate primary cortex involvement in mental rotation: a TMS study. Behav Brain Funct 2007, 3:38.
41. Hanakawa T., Dimyan M.A., Hallett M. Motor planning, imagery and execution in the distributed motor network: a time-course study with functional MRI. Cereb Cortex 2008, 18(12):2775-2788.
42. Dosenbach N.U., Visscher K.M., Palmer E.D., Miezin F.M., Wenger K.K., Kang H.C., et al. A core system for the implementation of task sets. Neuron 2006, 50:799-812.
43. Gilbert S.J., Gonen-Yaacovi G., Benoit R.G., Volle E., Burgess P.W. Distinct functional connectivity associated with lateral versus medial rostral prefrontal cortex: a meta-analysis. NeuroImage 2010, 53:1359-1367.
44. Dreher J.C., Koechlin E., Tierney M., Grafman J. Damage to the frontopolar cortex is associated with impaired multitasking. PLoS One 2008, 3:e3227.
45. Burgess P.W., Gilbert S.J., Dumontheil I. Function and localization within rostral prefrontal cortex (area 10). Philos Trans R Soc Lond B Biol Sci 2007, 362:887-899.
46. Elliott R., Dolan R.J., Frith C.D. Dissociable functions in the medial and lateral orbitofrontal cortex: evidence from human neuroimaging studies. Cereb Cortex 2000, 10:308-317.
47. Cabeza R., Nyberg L. Neural bases of learning and memory: functional neuroimaging evidence. Curr Opin Neurol 2000, 13(4):415-421.
48. Tresseras S., Boulanouar K., Conchou F., Simonetta-Moreau M., Berry I., Celsis P., et al. Transition from rest to movement: brain correlates revealed by functional connectivity. NeuroImage 2009, 48(1):207-216.
49. Brown S., Martinez M.J., Parsons L.M. The neural basis of human dance. Cereb Cortex 2006, 16:1157-1167.
50. Huda S., Rodriguez R., Lastra L., Warren M., Lacourse M.G., Cohen M.J., et al. Cortical activation during foot movements: II. Effect of movement rate and side. Neuroreport 2008, 19(16):1573-1577.
51. Dhamal N., Pagnoni G., Wiesenfled K., Zink C.F., Martin M., Berns G.S. Neural correlates of the complexity of rhythmic finger-tapping. NeuroImage 2003, 20:918-926.
52. Orban P., Peigneux P., Lungu O., Debas K., Barakat M., Bellec P., et al. Functional neuroanatomy associated with the expression of distinct movement kinematics in motor sequence learning. Neuroscience 2011, 179:94-103.
53. Jahn K., Deutschländer A., Stephan T., Strupp M., Wiesmann M., Brandt T. Brain activation patterns during imagined stance and locomotion in functional magnetic resonance imaging. NeuroImage 2004, 22(4):1722-1731.
54. Francis S., Lin Y., Aboushoushah S., White T.P., Phillips M., Bowtell R., et al. fMRI analysis of active, passive and electrically stimulated ankle dorsiflexion. NeuroImage 2009, 44:469-479.
55. 15 positron emission tomography study on mental imagery of movement sequences. The effect of modulating sequence length and direction. NeuroImage 2002, 17:999-1009.
56. Jäncke L., Loose R., Lutz K., Specht K., Shah W.J. Cortical activations during paced finger-tapping applying visual and auditory pacing stimuli. Brain Res Cogn Brain Res 2000, 10:51-66.
57. Schlerf J.E., Verstynen T.D., Ivry R.B., Spencer M.C. Evidence of novel somatotopic map in the human neocerebellum during complex actions. J Neurophysiol 2010, 103:3330-3336.
58. Johansen-Berg H., Dawes H., Guy C., Smith S.M., Wade D.T., Matthews P.M. Correlation between motor improvements and altered activity after rehabilitative therapy. Brain 2010, 125:2731-2742.
59. Habas C., Kamdar N., Nguyen D., Prater K., Beckmann C.F., Menon V., et al. Distinct cerebellar contributions to intrinsic connectivity networks. J Neurosci 2009, 29(26):8586-8594.
60. Destrieux C., Hommet C., Domengie F., et al. Influence of age on the dynamics of fMRI activations during a semantic fluency task. J Neuroradiol 2012, 39:158-166.