Functional Anatomy of Nonvisual Feedback Loops during Reaching: A Positron Emission Tomography Study

Desmurget, Michel; Gréa, Hélène; Grethe, Jeff S.; Prablanc, Claude; Alexander, Garrett E.; Grafton, Scott T.

doi:10.1523/jneurosci.21-08-02919.2001

Cited by 189 publications

(134 citation statements)

References 59 publications

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“…Whereas on-line corrections in the double-step paradigm are performed even if the target displacement is not consciously detected (Prablanc and Martin, 1992), the error-correction mechanism studied in the present investigation is related to conscious detection and the intentional release of a corrective motor command using the contralateral limb. The anterior cingulate cortex is clearly involved in the type of paradigm used in the present investigation (Carter et al, 1998) but not in the on-line corrections in the double-step paradigm (Desmurget et al, 2001).…”

Section: The Nature Of the Ern Componentmentioning

confidence: 62%

“…This is clearly different from paradigms in the motor domain, such as so-called double-step experiments involving subliminal target displacements (Prablanc and Martin, 1992). In a recent brain imaging study using this paradigm, a neural network including the cerebellum, posterior parietal cortex (PPC), and primary motor cortex was demonstrated to be involved in error correction (Desmurget et al, 2001). PPC has also been demonstrated to be important the correction of hand trajectories (Desmurget et al, 1999;Pisella et al, 2000).…”

Section: The Nature Of the Ern Componentmentioning

confidence: 90%

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Time Course of Error Detection and Correction in Humans: Neurophysiological Evidence

2002

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Using event-related brain potentials, the time course of error detection and correction was studied in healthy human subjects. A feedforward model of error correction was used to predict the timing properties of the error and corrective movements. Analysis of the multichannel recordings focused on (1) the error-related negativity (ERN) seen immediately after errors in response-and stimulus-locked averages and (2) on the lateralized readiness potential (LRP) reflecting motor preparation. Comparison of the onset and time course of the ERN and LRP components showed that the signs of corrective activity preceded the ERN. Thus, error correction was implemented before or at least in parallel with the appearance of the ERN component. Also, the amplitude of the ERN component was increased for errors, followed by fast corrective movements. The results are compatible with recent views considering the ERN component as the output of an evaluative system engaged in monitoring motor conflict.

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Section: The Nature Of the Ern Componentmentioning

confidence: 62%

Section: The Nature Of the Ern Componentmentioning

confidence: 90%

Time Course of Error Detection and Correction in Humans: Neurophysiological Evidence

2002

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“…Imaging methods have been described in previous publications (Desmurget et al, 1998a, b;Turner et al, 1998;Desmurget et al, 2001). In brief, regional cerebral blood¯ow (rCBF) images were acquired with a Siemens ECAT Exact scanner, using a modi®ed autoradiographic method in 3-D mode.…”

Section: Imagingmentioning

confidence: 99%

“…The effects (and source of variance) in the statistical model were subject, task and repetition. Given the subjects' consistent task performance and the randomization procedure, repetition could be treated as replication, resulting in a two-way ANOVA (Turner et al, 1998;Desmurget et al, 2001). Because the present experiment is bounded by an explicit question, namely whether or not BG is selectively involved in the planning of movement amplitude, a planned approach was used for statistical analysis and the search volume was restricted to the BG complex.…”

Section: Imagingmentioning

confidence: 99%

Basal ganglia network mediates the control of movement amplitude

Desmurget

Grafton

Vindras

et al. 2003

Experimental Brain Research

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This study addresses the hypothesis that the basal ganglia (BG) are involved speci®cally in the planning of movement amplitude (or covariates). Although often advanced, based on observations that Parkinson's disease (PD) patients exhibit hypokinesia in the absence of signi®cant directional errors, this hypothesis has been challenged by a recent alternative, that parkinsonian hypometria could be caused by dysfunction of on-line feedback loops. To re-evaluate this issue, we conducted two successive experiments. In the ®rst experiment we assumed that if BG are involved in extent planning then PD patients (who exhibit a major dysfunction within the BG network) should exhibit a preserved ability to use a direction precue with respect to normals, but an impaired ability to use an amplitude precue. Results were compatible with this prediction. Because this evidence did not prove conclusively that the BG is involved in amplitude planning (functional de®cits are not restricted to the BG network in PD), a second experiment was conducted using positron emission tomography (PET). We hypothesized that if the BG is important for planning movement amplitude, a task requiring increased amplitude planning should produce increased activation in the BG network. In agreement with this prediction, we observed enhanced activation of BG structures under a precue condition that emphasized extent planning in comparison with conditions that emphasized direction planning or no planning. Considered together, our results are consistent with the idea that BG is directly involved in the planning of movement amplitude or of factors that covary with that parameter.

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“…While rhythmic movements can be programmed by low level Central Pattern Generators (CPGs) (see e.g. Cohen, Rossignol, and Grillner (1988), Duysens and Van de Crommert (1998) and Swinnen (2002)), discrete movements also recruit higher cortical areas, that have been shown to play a role in the processing of sensory feedback (Desmurget et al, 2001). The level of feedback processing thus appears to be different in both kinds of movements.…”

Section: Figmentioning

confidence: 99%

Robotics and neuroscience: A rhythmic interaction

2008

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a b s t r a c tAt the crossing between motor control neuroscience and robotics system theory, the paper presents a rhythmic experiment that is amenable both to handy laboratory implementation and simple mathematical modeling. The experiment is based on an impact juggling task, requiring the coordination of two upper-limb effectors and some phase-locking with the trajectories of one or several juggled objects. We describe the experiment, its implementation and the mathematical model used for the analysis. Our underlying research focuses on the role of sensory feedback in rhythmic tasks. In a robotic implementation of our experiment, we study the minimum feedback that is required to achieve robust control. A limited source of feedback, measuring only the impact times, is shown to give promising results. A second field of investigation concerns the human behavior in the same impact juggling task. We study how a variation of the tempo induces a transition between two distinct control strategies with different sensory feedback requirements. Analogies and differences between the robotic and human behaviors are obviously of high relevance in such a flexible setup.

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Functional Anatomy of Nonvisual Feedback Loops during Reaching: A Positron Emission Tomography Study

Cited by 189 publications

References 59 publications

Time Course of Error Detection and Correction in Humans: Neurophysiological Evidence

Time Course of Error Detection and Correction in Humans: Neurophysiological Evidence

Basal ganglia network mediates the control of movement amplitude

Robotics and neuroscience: A rhythmic interaction

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