Intersegmental dynamics are controlled by sequential anticipatory, error correction, and postural mechanisms. - Wikidata - wikimedia - TriplyDB

Intersegmental dynamics are controlled by sequential anticipatory, error correction, and postural mechanisms.

Intersegmental dynamics are controlled by sequential anticipatory, error correction, and postural mechanisms.

http://www.wikidata.org/entity/Q48258123

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A gain-field encoding of limb position and velocity in the internal model of arm dynamics A brief review of the role of training in near-tool effects Long-latency reflexes account for limb biomechanics through several supraspinal pathways.Motor adaptation to single force pulses: sensitive to direction but insensitive to within-movement pulse placement and magnitude Mechanisms of motor adaptation in reactive balance control Auditory-motor adaptation to frequency-altered auditory feedback occurs when participants ignore feedback Contextual cuing contributes to the independent modification of multiple internal models for vocal control.Interaction of Visual and Proprioceptive Feedback During Adaptation of Human Reaching Movements Control of multi-joint arm movements for the manipulation of touch in keystroke by expert pianists Expressions of multiple neuronal dynamics during sensorimotor learning in the motor cortex of behaving monkeys Differences in context and feedback result in different trajectories and adaptation strategies in reaching The effects of neuromuscular fatigue on task performance during repetitive goal-directed movements.Proprioception from a spinocerebellar perspective.Linear hypergeneralization of learned dynamics across movement speeds reveals anisotropic, gain-encoding primitives for motor adaptation.Unconstrained three-dimensional reaching in rhesus monkeys Adaptation and generalization in acceleration-dependent force fields Deficient recovery response and adaptive feedback potential in dynamic gait stability in unilateral peripheral vestibular disorder patients.Dissociation of initial trajectory and final position errors during visuomotor adaptation following unilateral stroke.Role of Robotics in Neurorehabilitation.Critical neural substrates for correcting unexpected trajectory errors and learning from them.The role of motor learning in spatial adaptation near a tool.Generalization of Dexterous Manipulation Is Sensitive to the Frame of Reference in Which It Is Learned.Impaired anticipatory control of fingertip forces in patients with a pure motor or sensorimotor lacunar syndrome The effects of brain lateralization on motor control and adaptation Hemispheric differences in the control of limb dynamics: a link between arm performance asymmetries and arm selection patterns Differentiating between two models of motor lateralization.Reach adaptation: what determines whether we learn an internal model of the tool or adapt the model of our arm?Long-latency reflexes of elbow and shoulder muscles suggest reciprocal excitation of flexors, reciprocal excitation of extensors, and reciprocal inhibition between flexors and extensors Interaction torque contributes to planar reaching at slow speed.Learning a visuomotor rotation: simultaneous visual and proprioceptive information is crucial for visuomotor remapping Characterization of age-related modifications of upper limb motor control strategies in a new dynamic environment.Dynamic dominance persists during unsupported reaching.Coordination deficits in ideomotor apraxia during visually targeted reaching reflect impaired visuomotor transformations.Sensorimotor performance asymmetries predict hand selection Actions and consequences in bimanual interaction are represented in different coordinate systems.Sequential processes for controlling distance in multijoint movements.Immediate compensation for variations in self-generated Coriolis torques related to body dynamics and carried objects.Adjustments of motor pattern for load compensation via modulated activations of muscle synergies during natural behaviors.Differential activity-dependent development of corticospinal control of movement and final limb position during visually guided locomotion Hemispheric specialization and functional impact of ipsilesional deficits in movement coordination and accuracy.

P2860

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P2860

Intersegmental dynamics are controlled by sequential anticipatory, error correction, and postural mechanisms.

http://www.wikidata.org/entity/Q48258123

description

1999 nî lūn-bûn

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1999年学术文章

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1999年學術文章

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1999年學術文章

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1999年學術文章

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Journal of Neurophysiology

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C Ghez

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P2860

Initial agonist burst duration changes with movement amplitude in a deafferented patient.

A computational model of four regions of the cerebellum based on feedback-error learning.

The cerebellum and VOR/OKR learning models.

Motor learning by field approximation.

Loss of proprioception produces deficits in interjoint coordination.

Characteristics of motor programs underlying arm movements in monkeys.

Analysis of response properties of deefferented mammalian spindle receptors based on frequency response.

Evolving views on the internal operation and functional role of the muscle spindle.

Changes in limb dynamics during the practice of rapid arm movements.

Muscle activity for initiation of planar, two-joint arm movements in different directions.

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1045-1056

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