Neural coding within human brain areas involved in actions

Current Opinion in Neurobiology

Volumn 33, Issue , 2015, Pages 141-149

  Gallivan, Jason P ^a,b   Culham, Jody C ^c  

^a QUEEN S UNIVERSITY   (Canada)

^b QUEEN S UNIVERSITY   (Canada)

^c UNIVERSITY OF WESTERN ONTARIO   (Canada)

Author keywords

[No Author keywords available]

Indexed keywords

BRAIN FUNCTION; BRAIN REGION; CENTRAL SULCUS; CINGULATE GYRUS; CINGULATE SULCUS; DIFFUSION TENSOR IMAGING; FUNCTIONAL MAGNETIC RESONANCE IMAGING; FUSIFORM FACE AREA; FUSIFORM GYRUS; HUMAN; INFERIOR PARIETAL LOBULE; INTRAPARIETAL SULCUS; MEASUREMENT; MULTIVOXEL PATTERN ANALYSIS; NEURAL CODING; NEUROSCIENCE; PARAHIPPOCAMPAL PLACE AREA; PARIETO-OCCIPITAL SULCUS; POSTCENTRAL GYRUS; POSTERIOR PARIETAL CORTEX; PRECENTRAL SULCUS; PRECUNEUS; PREMOTOR CORTEX; PRIMARY MOTOR CORTEX; PRIORITY JOURNAL; REVIEW; SENSORIMOTOR CORTEX; SUPERIOR FRONTAL GYRUS; SUPERIOR PARIETAL LOBULE; SUPERIOR TEMPORAL SULCUS; SUPPLEMENTARY MOTOR AREA; BRAIN; BRAIN MAPPING; MOVEMENT (PHYSIOLOGY); NEUROIMAGING; PHYSIOLOGY;

BRAIN; BRAIN MAPPING; HUMANS; MOVEMENT; NEUROIMAGING;

EID: 84927161099     PISSN: 09594388     EISSN: 18736882     Source Type: Journal    
DOI: 10.1016/j.conb.2015.03.012     Document Type: Review

References (90)

1. Culham J.C., Valyear K.F. Human parietal cortex in action. Curr Opin Neurobiol 2006, 16:205-212.
2. Culham J.C., Cavina-Pratesi C., Singhal A. The role of parietal cortex in visuomotor control: what have we learned from neuroimaging?. Neuropsychologia 2006, 44:2668-2684.
3. Grefkes C., Fink G.R. The functional organization of the intraparietal sulcus in humans and monkeys. J Anat 2005, 207:3-17.
4. Culham J.C., Kanwisher N.G. Neuroimaging of cognitive functions in human parietal cortex. Curr Opin Neurobiol 2001, 11:157-163.
5. Haxby J.V., Gobbini M.I., Furey M.L., Ishai A., Schouten J.L., Pietrini P. Distributed and overlapping representations of faces and objects in ventral temporal cortex. Science 2001, 293:2425-2430.
6. Tong F., Pratte M.S. Decoding patterns of human brain activity. Annu Rev Psychol 2012, 63:483-509.
7. Haynes J.D., Rees G. Decoding mental states from brain activity in humans. Nat Rev Neurosci 2006, 7:523-534.
8. Haxby J.V., Connolly A.C., Guntupalli J.S. Decoding neural representational spaces using multivariate pattern analysis. Annu Rev Neurosci 2014, 37:435-456.
9. Kriegeskorte N., Mur M., Bandettini P. Representational similarity analysis-connecting the branches of systems neuroscience. Front Syst Neurosci 2008, 2:4.
10. Picard N., Strick P.L. Imaging the premotor areas. Curr Opin Neurobiol 2001, 11:663-672.
11. Amiez C., Petrides M. Neuroimaging evidence of the anatomo-functional organization of the human cingulate motor areas. Cereb Cortex 2014, 24:563-578.
12. Goodale M.A., Milner A.D. Separate visual pathways for perception and action. Trends Neurosci 1992, 15:20-25.
13. Rizzolatti G., Matelli M. Two different streams form the dorsal visual system: anatomy and functions. Exp Brain Res 2003, 153:146-157.
14. Borra E., Belmalih A., Calzavara R., Gerbella M., Murata A., Rozzi S., et al. Cortical connections of the macaque anterior intraparietal (AIP) area. Cereb Cortex 2008, 18:1094-1111.
15. Van Essen D.C., Dierker D.L. Surface-based and probabilistic atlases of primate cerebral cortex. Neuron 2007, 56:209-225.
16. Johnson-Frey S.H. The neural bases of complex tool use in humans. Trends Cogn Sci 2004, 8:71-78.
17. Tomassini V., Jbabdi S., Klein J.C., Behrens T.E., Pozzilli C., Matthews P.M., et al. Diffusion-weighted imaging tractography-based parcellation of the human lateral premotor cortex identifies dorsal and ventral subregions with anatomical and functional specializations. J Neurosci 2007, 27:10259-10269.
18. Talairach J., Tournoux P. Co-planar stereotaxic atlas of the human brain 1988, Thieme Medical Publishers, New York, NY.
19. Margulies D.S., Vincent J.L., Kelly C., Lohmann G., Uddin L.Q., Biswal B.B., et al. Precuneus shares intrinsic functional architecture in humans and monkeys. Proc Natl Acad Sci USA 2009, 106:20069-20074.
20. Amiez C., Kostopoulos P., Champod A.S., Petrides M. Local morphology predicts functional organization of the dorsal premotor region in the human brain. J Neurosci 2006, 26:2724-2731.
21. Singhal A., Monaco S., Kaufman L.D., Culham J.C. Human fMRI reveals that delayed action re-recruits visual perception. PLoS ONE 2013, 8:e73629.
22. Gallivan J.P., McLean D.A., Flanagan J.R., Culham J.C. Where one hand meets the other: limb-specific and action-dependent movement plans decoded from preparatory signals in single human frontoparietal brain areas. J Neurosci 2013, 33:1991-2008.
23. Gallivan J.P., McLean D.A., Smith F.W., Culham J.C. Decoding effector-dependent and effector-independent movement intentions from human parieto-frontal brain activity. J Neurosci 2011, 31:17149-17168.
24. Gallivan J.P., McLean D.A., Valyear K.F., Culham J.C. Decoding the neural mechanisms of human tool use. Elife 2013, 2:e00425.
25. Gallivan J.P., McLean D.A., Valyear K.F., Pettypiece C.E., Culham J.C. Decoding action intentions from preparatory brain activity in human parieto-frontal networks. J Neurosci 2011, 31:9599-964
26. Leone F.T., Heed T., Toni I., Medendorp W.P. Understanding effector selectivity in human posterior parietal cortex by combining information patterns and activation measures. J Neurosci 2014, 34:7102-7112.
27. Disbrow E., Roberts T.P., Slutsky D., Krubitzer L. The use of fMRI for determining the topographic organization of cortical fields in human and nonhuman primates. Brain Res 1999, 829:167-173.
28. Silver M.A., Kastner S. Topographic maps in human frontal and parietal cortex. Trends Cogn Sci 2009, 13:488-495.
29. Sereno M.I., Pitzalis S., Martinez A. Mapping of contralateral space in retinotopic coordinates by a parietal cortical area in humans. Science 2001, 294:1350-1354.
30. Arcaro M.J., McMains S.A., Singer B.D., Kastner S. Retinotopic organization of human ventral visual cortex. J Neurosci 2009, 29:10638-10652.
31. Mars R.B., Jbabdi S., Sallet J., O'Reilly J.X., Croxson P.L., Olivier E., et al. Diffusion-weighted imaging tractography-based parcellation of the human parietal cortex and comparison with human and macaque resting-state functional connectivity. J Neurosci 2011, 31:4087-4100.
32. Zlatkina V., Petrides M. Morphological patterns of the intraparietal sulcus and the anterior intermediate parietal sulcus of Jensen in the human brain. Proc Biol Sci 2014, 281.
33. Zilles K., Amunts K. Centenary of Brodmann's map-conception and fate. Nat Rev Neurosci 2010, 11:139-145.
34. Konen C.S., Mruczek R.E., Montora J.L., Kastner S. Functional organization of human posterior parietal cortex: grasping- and reaching-related activations relative to topographically organized cortex. J Neurophysiol 2013, 109:2897-2908.
35. Kamitani Y., Tong F. Decoding the visual and subjective contents of the human brain. Nat Neurosci 2005, 8:679-685.
36. Kriegeskorte N., Mur M., Ruff D.A., Kiani R., Bodurka J., Esteky H., et al. Matching categorical object representations in inferior temporal cortex of man and monkey. Neuron 2008, 60:1126-1141.
37. Dubois J., de Berker A.O., Tsao D.Y. Single-unit recordings in the macaque face patch system reveal limitations of fMRI MVPA. J Neurosci 2015, 35:2791-2802.
38. Epstein R.A., Morgan L.K. Neural responses to visual scenes reveals inconsistencies between fMRI adaptation and multivoxel pattern analysis. Neuropsychologia 2012, 50:530-543.
39. Astafiev S.V., Shulman G.L., Stanley C.M., Snyder A.Z., Van Essen D.C., Corbetta M. Functional organization of human intraparietal and frontal cortex for attending, looking, and pointing. J Neurosci 2003, 23:4689-4699.
40. Levy I., Schluppeck D., Heeger D.J., Glimcher P.W. Specificity of human cortical areas for reaches and saccades. J Neurosci 2007, 27:4687-4696.
41. Hagler D.J., Riecke L., Sereno M.I. Parietal and superior frontal visuospatial maps activated by pointing and saccades. NeuroImage 2007, 35:1562-1577.
42. Beurze S.M., de Lange F.P., Toni I., Medendorp W.P. Spatial and effector processing in the human parietofrontal network for reaches and saccades. J Neurophysiol 2009, 101:3053-3062.
43. Culham J.C., Danckert S.L., DeSouza J.F., Gati J.S., Menon R.S., Goodale M.A. Visually guided grasping produces fMRI activation in dorsal but not ventral stream brain areas. Exp Brain Res 2003, 153:180-189.
44. Frey S.H., Vinton D., Norlund R., Grafton S.T. Cortical topography of human anterior intraparietal cortex active during visually guided grasping. Brain Res Cogn Brain Res 2005, 23:397-405.
45. Cavina-Pratesi C., Monaco S., Fattori P., Galletti C., McAdam T.D., Quinlan D.J., et al. Functional magnetic resonance imaging reveals the neural substrates of arm transport and grip formation in reach-to-grasp actions in humans. J Neurosci 2010, 30:10306-10323.
46. Filimon F. Human cortical control of hand movements: parietofrontal networks for reaching, grasping, and pointing. Neuroscientist 2010, 16:388-407.
47. Fabbri S., Caramazza A., Lingnau A. Tuning curves for movement direction in the human visuomotor system. J Neurosci 2010, 30:13488-13498.
48. Fabbri S., Strnad L., Caramazza A., Lingnau A. Overlapping representations for grip type and reach direction. NeuroImage 2014, 94:138-146.
49. Eisenberg M., Shmuelof L., Vaadia E., Zohary E. The representation of visual and motor aspects of reaching movements in the human motor cortex. J Neurosci 2011, 31:12377-12384.
50. Beurze S.M., de Lange F.P., Toni I., Medendorp W.P. Integration of target and effector information in the human brain during reach planning. J Neurophysiol 2007, 97:188-199.
51. Barany D.A., Della-Maggiore V., Viswanathan S., Cieslak M., Grafton S.T. Feature interactions enable decoding of sensorimotor transformations for goal-directed movement. J Neurosci 2014, 34:6860-6873.
52. Buneo C.A., Andersen R.A. The posterior parietal cortex: sensorimotor interface for the planning and online control of visually guided movements. Neuropsychologia 2006, 44:2594-2606.
53. Chen Y., Monaco S., Byrne P., Yan X., Henriques D.Y., Crawford J.D. Allocentric versus egocentric representation of remembered reach targets in human cortex. J Neurosci 2014, 34:12515-12526.
54. Bernier P.M., Grafton S.T. Human posterior parietal cortex flexibly determines reference frames for reaching based on sensory context. Neuron 2010, 68:776-788.
55. Monaco S., Cavina-Pratesi C., Sedda A., Fattori P., Galletti C., Culham J.C. Functional magnetic resonance adaptation reveals the involvement of the dorsomedial stream in hand orientation for grasping. J Neurophysiol 2011, 106:2248-2263.
56. Monaco S., Chen Y., Medendorp W.P., Crawford J.D., Fiehler K., Henriques D.Y. Functional magnetic resonance imaging adaptation reveals the cortical networks for processing grasp-relevant object properties. Cereb Cortex 2014, 24:1540-1550.
57. Gallivan J.P., Cant J.S., Goodale M.A., Flanagan J.R. Representation of object weight in human ventral visual cortex. Curr Biol 2014, 24:1866-1873.
58. Fattori P., Raos V., Breveglieri R., Bosco A., Marzocchi N., Galletti C. The dorsomedial pathway is not just for reaching: grasping neurons in the medial parieto-occipital cortex of the macaque monkey. J Neurosci 2010, 30:342-349.
59. Steele C.J., Penhune V.B. Specific increases within global decreases: a functional magnetic resonance imaging investigation of five days of motor sequence learning. J Neurosci 2010, 30:8332-8341.
60. Wiestler T., Diedrichsen J. Skill learning strengthens cortical representations of motor sequences. Elife 2013, 2:e00801.
61. Kornysheva K., Diedrichsen J. Human premotor areas parse sequences into their spatial and temporal features. Elife 2014, 3:e03043.
62. Botvinick M.M. Hierarchical models of behavior and prefrontal function. Trends Cogn Sci 2008, 12:201-208.
63. Uithol S., van Rooij I., Bekkering H., Haselager P. Hierarchies in action and motor control. J Cogn Neurosci 2012, 24:1077-1086.
64. Arbib M.A., Bonaiuto J.B., Jacobs S., Frey S.H. Tool use and the distalization of the end-effector. Psychol Res 2009, 73:441-462.
65. Umilta M.A., Escola L., Instkirvell I., Grammont F., Rochat M., Caruana F., et al. When pliers become fingers in the monkey motor system. Proc Natl Acad Sci USA 2008, 105:2209-2213.
66. Brandi M.L., Wohlschlager A., Sorg C., Hermsdorfer J. The neural correlates of planning and executing actual tool use. J Neurosci 2014, 34:13183-13194.
67. Valyear K.F., Gallivan J.P., McLean D.A., Culham J.C. fMRI repetition suppression for familiar but not arbitrary actions with tools. J Neurosci 2012, 32:4247-4259.
68. Peeters R., Simone L., Nelissen K., Fabbri-Destro M., Vanduffel W., Rizzolatti G., et al. The representation of tool use in humans and monkeys: common and uniquely human features. J Neurosci 2009, 29:11523-11539.
69. Martin A., Wiggs C.L., Ungerleider L.G., Haxby J.V. Neural correlates of category-specific knowledge. Nature 1996, 379:649-652.
70. Beauchamp M.S., Lee K.E., Haxby J.V., Martin A. Parallel visual motion processing streams for manipulable objects and human movements. Neuron 2002, 34:149-159.
71. Bracci S., Ietswaart M., Peelen M.V., Cavina-Pratesi C. Dissociable neural responses to hands and non-hand body parts in human left extrastriate visual cortex. J Neurophysiol 2010, 103:3389-3397.
72. Bracci S., Cavina-Pratesi C., Ietswaart M., Caramazza A., Peelen M.V. Closely overlapping responses to tools and hands in left lateral occipitotemporal cortex. J Neurophysiol 2012, 107:1443-1456.
73. Bracci S., Peelen M.V. Body and object effectors: the organization of object representations in high-level visual cortex reflects body-object interactions. J Neurosci 2013, 33:18247-18258.
74. Hutchison R.M., Culham J.C., Everling S., Flanagan J.R., Gallivan J.P. Distinct and distributed functional connectivity patterns across cortex reflect the domain-specific constraints of object, face, scene, body, and tool category-selective modules in the ventral visual pathway. NeuroImage 2014, 96:216-236.
75. Orlov T., Makin T.R., Zohary E. Topographic representation of the human body in the occipitotemporal cortex. Neuron 2010, 68:586-600.
76. Astafiev S.V., Stanley C.M., Shulman G.L., Corbetta M. Extrastriate body area in human occipital cortex responds to the performance of motor actions. Nat Neurosci 2004, 7:542-548.
77. Gallivan J.P., Chapman C.S., McLean D.A., Flanagan J.R., Culham J.C. Activity patterns in the category-selective occipitotemporal cortex predict upcoming motor actions. Eur J Neurosci 2013, 38:2408-2424.
78. Orlov T., Porat Y., Makin T.R., Zohary E. Hands in motion: an upper-limb-selective area in the occipitotemporal cortex shows sensitivity to viewed hand kinematics. J Neurosci 2014, 34:4882-4895.
79. Gallivan J.P., Johnsrude I.S., Randall Flanagan J. Planning ahead: object-directed sequential actions decoded from human frontoparietal and occipitotemporal networks. Cereb Cortex 2015, PII: bhu302, Epub ahead of print.
80. Wolpert D.M., Flanagan J.R. Motor prediction. Curr Biol 2001, 11:R729-R732.
81. von Helmholtz H. Handbook of physiological optics 1866, Dover Publications, New York, NY. 3rd ed.
82. Krasovsky A., Gilron R., Yeshurun Y., Mukamel R. Differentiating intended sensory outcome from underlying motor actions in the human brain. J Neurosci 2014, 34:15446-15454.
83. Townsend B.R., Subasi E., Scherberger H. Grasp movement decoding from premotor and parietal cortex. J Neurosci 2011, 31:14386-14398.
84. Andersen R.A., Hwang E.J., Mulliken G.H. Cognitive neural prosthetics. Annu Rev Psychol 2010, 61:169-190. (C161-163).
85. Hochberg L.R., Bacher D., Jarosiewicz B., Masse N.Y., Simeral J.D., Vogel J., et al. Reach and grasp by people with tetraplegia using a neurally controlled robotic arm. Nature 2012, 485:372-375.
86. Rice G.E., Watson D.M., Hartley T., Andrews T.J. Low-level image properties of visual objects predict patterns of neural response across category-selective regions of the ventral visual pathway. J Neurosci 2014, 34:8837-8844.
87. Snyder L.H., Batista A.P., Andersen R.A. Coding of intention in the posterior parietal cortex. Nature 1997, 386:167-170.
88. Scott S.H., Kalaska J.F. Reaching movements with similar hand paths but different arm orientations. I. Activity of individual cells in motor cortex. J Neurophysiol 1997, 77:826-852.
89. Fogassi L., Ferrari P.F., Gesierich B., Rozzi S., Chersi F., Rizzolatti G. Parietal lobe: from action organization to intention understanding. Science 2005, 308:662-667.
90. Pastor-Bernier A., Cisek P. Neural correlates of biased competition in premotor cortex. J Neurosci 2011, 31:7083-7088.