Grasping with the Press of a Button: Grasp-selective Responses in the Human Anterior Intraparietal Sulcus Depend on Nonarbitrary Causal Relationships between Hand Movements and End-effector Actions

Evidence implicates ventral parieto-premotor cortices in representing the goal of grasping independent of the movements or effectors involved [Umilta, M. A., Escola, L., Intskirveli, I., Grammont, F., Rochat, M., Caruana, F., et al. When pliers become fingers in the monkey motor system. Proceedings of the National Academy of Sciences, U.S.A., 105, 2209–2213, 2008; Tunik, E., Frey, S. H., & Grafton, S. T. Virtual lesions of the anterior intraparietal area disrupt goal-dependent on-line adjustments of grasp. Nature Neuroscience, 8, 505–511, 2005]. Modern technologies that enable arbitrary causal relationships between hand movements and tool actions provide a strong test of this hypothesis. We capitalized on this unique opportunity by recording activity with fMRI during tasks in which healthy adults performed goal-directed reach and grasp actions manually or by depressing buttons to initiate these same behaviors in a remotely located robotic arm (arbitrary causal relationship). As shown previously [Binkofski, F., Dohle, C., Posse, S., Stephan, K. M., Hefter, H., Seitz, R. J., et al. Human anterior intraparietal area subserves prehension: A combined lesion and functional MRI activation study. Neurology, 50, 1253–1259, 1998], we detected greater activity in the vicinity of the anterior intraparietal sulcus (aIPS) during manual grasp versus reach. In contrast to prior studies involving tools controlled by nonarbitrarily related hand movements [Gallivan, J. P., McLean, D. A., Valyear, K. F., & Culham, J. C. Decoding the neural mechanisms of human tool use. Elife, 2, e00425, 2013; Jacobs, S., Danielmeier, C., & Frey, S. H. Human anterior intraparietal and ventral premotor cortices support representations of grasping with the hand or a novel tool. Journal of Cognitive Neuroscience, 22, 2594–2608, 2010], however, responses within the aIPS and premotor cortex exhibited no evidence of selectivity for grasp when participants employed the robot. Instead, these regions showed comparable increases in activity during both the reach and grasp conditions. Despite equivalent sensorimotor demands, the right cerebellar hemisphere displayed greater activity when participants initiated the robot's actions versus when they pressed a button known to be nonfunctional and watched the very same actions undertaken autonomously. This supports the hypothesis that the cerebellum predicts the forthcoming sensory consequences of volitional actions [Blakemore, S. J., Frith, C. D., & Wolpert, D. M. The cerebellum is involved in predicting the sensory consequences of action. NeuroReport, 12, 1879–1884, 2001]. We conclude that grasp-selective responses in the human aIPS and premotor cortex depend on the existence of nonarbitrary causal relationships between hand movements and end-effector actions.

[1]  R. C. Oldfield The assessment and analysis of handedness: the Edinburgh inventory. , 1971, Neuropsychologia.

[2]  A. Bastian,et al.  ‘Motor cognition’ — what is it and is the cerebellum involved? , 2008, The Cerebellum.

[3]  Scott T. Grafton,et al.  Virtual lesions of the anterior intraparietal area disrupt goal-dependent on-line adjustments of grasp , 2005, Nature Neuroscience.

[4]  U. Castiello,et al.  The Human Premotor Cortex Is 'Mirror' Only for Biological Actions , 2004, Current Biology.

[5]  Stephen M. Smith,et al.  General multilevel linear modeling for group analysis in FMRI , 2003, NeuroImage.

[6]  G Rizzolatti,et al.  When pliers become fingers in the monkey motor system , 2008, Proceedings of the National Academy of Sciences.

[7]  G. Schalk,et al.  Evolution of brain-computer interfaces : going beyond classic motor physiology , 2009 .

[8]  J. Haxby,et al.  Parallel Visual Motion Processing Streams for Manipulable Objects and Human Movements , 2002, Neuron.

[9]  Miguel A. L. Nicolelis,et al.  Actions from thoughts , 2001, Nature.

[10]  Leonardo Fogassi,et al.  Mirror Neurons Responding to Observation of Actions Made with Tools in Monkey Ventral Premotor Cortex , 2005, Journal of Cognitive Neuroscience.

[11]  Pascal Boyer,et al.  How the brain perceives causality: an event-related fMRI study , 2001, Neuroreport.

[12]  R. Buckner,et al.  Human Brain Mapping 6:373–377(1998) � Event-Related fMRI and the Hemodynamic Response , 2022 .

[13]  Keith J. Worsley,et al.  Statistical analysis of activation images , 2001 .

[14]  N Ramnani,et al.  A probabilistic MR atlas of the human cerebellum , 2009, NeuroImage.

[15]  David Whitney,et al.  Visually guided reaching depends on motion area MT+. , 2007, Cerebral cortex.

[16]  Scott T. Grafton,et al.  Localization of grasp representations in humans by positron emission tomography , 1996, Experimental Brain Research.

[17]  M. Corbetta,et al.  Two attentional processes in the parietal lobe. , 2002, Cerebral cortex.

[18]  Donatella Spinelli,et al.  Similar Cerebral Motor Plans for Real and Virtual Actions , 2012, PloS one.

[19]  Nicolas Y. Masse,et al.  Reach and grasp by people with tetraplegia using a neurally controlled robotic arm , 2012, Nature.

[20]  David M. Santucci,et al.  Learning to Control a Brain–Machine Interface for Reaching and Grasping by Primates , 2003, PLoS biology.

[21]  Z Kourtzi,et al.  Representation of Perceived Object Shape by the Human Lateral Occipital Complex , 2001, Science.

[22]  Joachim Hermsdörfer,et al.  The role of the cerebellum for predictive control of grasping , 2008, The Cerebellum.

[23]  David C. Van Essen,et al.  A Population-Average, Landmark- and Surface-based (PALS) atlas of human cerebral cortex , 2005, NeuroImage.

[24]  Maneesh C. Patel,et al.  Distinct frontal systems for response inhibition, attentional capture, and error processing , 2010, Proceedings of the National Academy of Sciences.

[25]  Scott T. Grafton,et al.  Functional anatomy of pointing and grasping in humans. , 1996, Cerebral cortex.

[26]  L. Fogassi,et al.  Grasping Neurons of Monkey Parietal and Premotor Cortices Encode Action Goals at Distinct Levels of Abstraction during Complex Action Sequences , 2011, The Journal of Neuroscience.

[27]  Norio Fujimaki,et al.  Separate cerebellar areas for motor control , 1998, Neuroreport.

[28]  D. Wolpert,et al.  The cerebellum is involved in predicting the sensory consequences of action , 1999, Neuroreport.

[29]  G. Rizzolatti,et al.  Functional organization of inferior area 6 in the macaque monkey , 2004, Experimental Brain Research.

[30]  Peter L. Strick,et al.  The Cerebellum and Basal Ganglia are Interconnected , 2010, Neuropsychology Review.

[31]  R. Johansson,et al.  Prediction Precedes Control in Motor Learning , 2003, Current Biology.

[32]  Andreea C. Bostan,et al.  The basal ganglia communicate with the cerebellum , 2010, Proceedings of the National Academy of Sciences.

[33]  G. Sheean,et al.  Upper Motor Neurone Syndrome and Spasticity: Neurophysiology of spasticity , 2008 .

[34]  Stephen M. Smith,et al.  Temporal Autocorrelation in Univariate Linear Modeling of FMRI Data , 2001, NeuroImage.

[35]  Simon B. Eickhoff,et al.  A new SPM toolbox for combining probabilistic cytoarchitectonic maps and functional imaging data , 2005, NeuroImage.

[36]  Ravi S. Menon,et al.  Visually guided grasping produces fMRI activation in dorsal but not ventral stream brain areas , 2003, Experimental Brain Research.

[37]  I. Johnsrude,et al.  Somatotopic Representation of Action Words in Human Motor and Premotor Cortex , 2004, Neuron.

[38]  Christian Keysers,et al.  The anthropomorphic brain: The mirror neuron system responds to human and robotic actions , 2007, NeuroImage.

[39]  S. Huettel,et al.  A Distinct Role of the Temporal-Parietal Junction in Predicting Socially Guided Decisions , 2012, Science.

[40]  Scott T. Grafton The cognitive neuroscience of prehension: recent developments , 2010, Experimental Brain Research.

[41]  D. Wolpert,et al.  Internal models in the cerebellum , 1998, Trends in Cognitive Sciences.

[42]  M. Arbib,et al.  Tool use and the distalization of the end-effector , 2009, Psychological research.

[43]  G. Rizzolatti,et al.  The mirror-neuron system. , 2004, Annual review of neuroscience.

[44]  Scott H. Frey,et al.  Human Anterior Intraparietal and Ventral Premotor Cortices Support Representations of Grasping with the Hand or a Novel Tool , 2010, Journal of Cognitive Neuroscience.

[45]  R. Ivry,et al.  Cerebellar involvement in anticipating the consequences of self-produced actions during bimanual movements. , 2005, Journal of neurophysiology.

[46]  Richard B. Ivry,et al.  Is the cerebellum involved in learning and cognition? , 1992, Current Opinion in Neurobiology.

[47]  R. Andersen,et al.  Cognitive neural prosthetics. , 2010, Annual review of psychology.

[48]  Jörn Diedrichsen,et al.  Two Distinct Ipsilateral Cortical Representations for Individuated Finger Movements , 2012, Cerebral cortex.

[49]  R. J. Seitz,et al.  A fronto‐parietal circuit for object manipulation in man: evidence from an fMRI‐study , 1999, The European journal of neuroscience.

[50]  Byron M. Yu,et al.  Neural constraints on learning , 2014, Nature.

[51]  Jonathan R Wolpaw,et al.  Control of a two-dimensional movement signal by a noninvasive brain-computer interface in humans. , 2004, Proceedings of the National Academy of Sciences of the United States of America.

[52]  R. Ilmoniemi,et al.  Functional links between motor and language systems , 2005, The European journal of neuroscience.

[53]  Scott H. Frey,et al.  Handedness-dependent and -independent cerebral asymmetries in the anterior intraparietal sulcus and ventral premotor cortex during grasp planning , 2011, NeuroImage.

[54]  R. J. Seitz,et al.  The role of V5 (hMT+) in visually guided hand movements: an fMRI study , 2004, The European journal of neuroscience.

[55]  Umberto Castiello,et al.  The Cortical Control of Visually Guided Grasping , 2008, The Neuroscientist : a review journal bringing neurobiology, neurology and psychiatry.

[56]  S. Keele,et al.  Does the Cerebellum Provide a Common Computation for Diverse Tasks? A Timing Hypothesis a , 1990, Annals of the New York Academy of Sciences.

[57]  J. Haxby,et al.  fMRI Responses to Video and Point-Light Displays of Moving Humans and Manipulable Objects , 2003, Journal of Cognitive Neuroscience.

[58]  Kristen L. Macuga,et al.  Neural representations involved in observed, imagined, and imitated actions are dissociable and hierarchically organized , 2012, NeuroImage.

[59]  M. Desmurget,et al.  Basal ganglia contributions to motor control: a vigorous tutor , 2010, Current Opinion in Neurobiology.

[60]  Scott T. Grafton,et al.  Goal Representation in Human Anterior Intraparietal Sulcus , 2006, The Journal of Neuroscience.

[61]  Scott T. Grafton,et al.  Beyond grasping: Representation of action in human anterior intraparietal sulcus , 2007, NeuroImage.

[62]  Scott T. Grafton,et al.  Cortical topography of human anterior intraparietal cortex active during visually guided grasping. , 2005, Brain research. Cognitive brain research.

[63]  Ravi S. Menon,et al.  Distinguishing subregions of the human MT+ complex using visual fields and pursuit eye movements. , 2001, Journal of neurophysiology.

[64]  Jody C Culham,et al.  Decoding the neural mechanisms of human tool use , 2013, eLife.

[65]  Dewen Hu,et al.  Intratask and intertask asymmetry analysis of motor function , 2006, Neuroreport.

[66]  Richard B. Ivry,et al.  Consensus Paper: Roles of the Cerebellum in Motor Control—The Diversity of Ideas on Cerebellar Involvement in Movement , 2011, The Cerebellum.

[67]  Mattia Marangon,et al.  Evidence for context sensitivity of grasp representations in human parietal and premotor cortices. , 2011, Journal of neurophysiology.

[68]  Michael Brady,et al.  Improved Optimization for the Robust and Accurate Linear Registration and Motion Correction of Brain Images , 2002, NeuroImage.

[69]  Mark W. Woolrich,et al.  Advances in functional and structural MR image analysis and implementation as FSL , 2004, NeuroImage.

[70]  Andrew B. Schwartz,et al.  Brain-Controlled Interfaces: Movement Restoration with Neural Prosthetics , 2006, Neuron.

[71]  C Dohle,et al.  Human anterior intraparietal area subserves prehension , 1998, Neurology.

[72]  Stephen M. Smith,et al.  Functional MRI : an introduction to methods , 2002 .

[73]  Scott T. Grafton,et al.  Actions or Hand-Object Interactions? Human Inferior Frontal Cortex and Action Observation , 2003, Neuron.

[74]  C. Gonzalez,et al.  The contributions of vision and haptics to reaching and grasping , 2015, Front. Psychol..

[75]  Mark W. Woolrich,et al.  Multilevel linear modelling for FMRI group analysis using Bayesian inference , 2004, NeuroImage.

[76]  Jessie Chen,et al.  Neurophysiology of prehension. I. Posterior parietal cortex and object-oriented hand behaviors. , 2007, Journal of neurophysiology.

[77]  Stephen M Smith,et al.  Fast robust automated brain extraction , 2002, Human brain mapping.

[78]  Tutis Vilis,et al.  The lateral occipital complex subserves the perceptual persistence of motion-defined groupings. , 2003, Cerebral cortex.

[79]  M. Corbetta,et al.  Control of goal-directed and stimulus-driven attention in the brain , 2002, Nature Reviews Neuroscience.