about
Representation of Muscle Synergies in the Primate BrainBiomechanical Characteristics of Hand Coordination in Grasping Activities of Daily LivingAre movement disorders and sensorimotor injuries pathologic synergies? When normal multi-joint movement synergies become pathologicTransfer of piano practice in fast performance of skilled finger movementsSynergy-Based Bilateral Port: A Universal Control Module for Tele-Manipulation Frameworks Using Asymmetric Master-Slave Systems.Consensus Paper: Towards a Systems-Level View of Cerebellar Function: the Interplay Between Cerebellum, Basal Ganglia, and CortexAnalysis of hand synergies in healthy subjects during bimanual manipulation of various objectsDifferences between kinematic synergies and muscle synergies during two-digit graspingSimulating spinal border cells and cerebellar granule cells under locomotion--a case study of spinocerebellar information processingSomatosensory feedback refines the perception of hand shape with respect to external constraintsClimbing fiber receptive fields-organizational and functional aspects and relationship to limb coordination.Analysis of Hand and Wrist Postural Synergies in Tolerance Grasping of Various Objects.Generalization of motor resonance during the observation of hand, mouth, and eye movementsNo Medium-Term Spinocerebellar Input Plasticity in Deep Cerebellar Nuclear Neurons In Vivo?A Synergy-Based Optimally Designed Sensing Glove for Functional Grasp Recognition.Digit Position and Forces Covary during Anticipatory Control of Whole-Hand ManipulationJoint angles and angular velocities and relevance of eigenvectors during prehension in the monkey.Muscle synergies evoked by microstimulation are preferentially encoded during behaviorLow-Dimensional Synergistic Representation of Bilateral Reaching Movements.Elasticity improves handgrip performance and user experience during visuomotor control.Cerebellar Synaptic Plasticity and the Credit Assignment Problem.Hand synergies: Integration of robotics and neuroscience for understanding the control of biological and artificial hands.Cerebellar physiology: links between microcircuitry properties and sensorimotor functions.A synergy-based hand control is encoded in human motor cortical areasFrom reaching to reach-to-grasp: the arm posture difference and its implications on human motion control strategy.Fascicular Topography of the Human Median Nerve for Neuroprosthetic Surgery.Specific relationship between excitatory inputs and climbing fiber receptive fields in deep cerebellar nuclear neurons.Editorial: Modularity in motor control: from muscle synergies to cognitive action representation.Origins of Common Neural Inputs to Different Compartments of the Extensor Digitorum Communis Muscle.Towards a synergy framework across neuroscience and robotics: Lessons learned and open questions. Reply to comments on: "Hand synergies: Integration of robotics and neuroscience for understanding the control of biological and artificial hands".Postural Hand Synergies during Environmental Constraint Exploitation.Multidigit force control during unconstrained grasping in response to object perturbations.Neural basis for hand muscle synergies in the primate spinal cord.Improving Fine Control of Grasping Force during Hand-Object Interactions for a Soft Synergy-Inspired Myoelectric Prosthetic Hand.Grasp-Based Functional Coupling Between Reach- and Grasp-Related Components of Forelimb Muscle Activity.Effect of visual and tactile feedback on kinematic synergies in the grasping hand.Dynamical Coordination of Hand Intrinsic Muscles for Precision Grip in Diabetes Mellitus.Characterization of Hand Clenching in Human Sensorimotor Cortex Using High-, and Ultra-High Frequency Band Modulations of Electrocorticogram.
P2860
Q26786060-DB4BD38F-08C3-4796-A11E-4260AAFFAF01Q28005525-F79ACF77-B2E7-4CD3-A3EA-F997B9F7247EQ28385462-53B42BD6-8170-404A-893F-900C8127EC0AQ30355096-911758AD-8291-400F-BEA4-0DB5AE6E83B8Q30843615-63452671-EBE4-47CE-99FC-7FD2A2394ED7Q34513987-7A19A92D-A1A0-41C5-B0B6-5C130211E235Q34544763-3E1A2414-C346-4C58-83E8-A9FD8678F7B5Q35219102-B275B8DA-A20F-4102-968B-308216E9E6C4Q35255706-DD01D1CF-5874-476B-A0B4-4942A6295CC3Q35269938-7F615561-0062-4915-8617-DDC2C809D4E2Q35544441-152CB792-3227-4720-800E-FBD9D8C9DBFBQ36118629-BF65F762-A597-4738-96CC-A2ED60D968EFQ36174126-34C194B8-8ADC-4C33-BEE2-B3C176452087Q36235277-24C467F9-9FAD-45DF-8A31-9B138A4A9DD6Q37068536-7840071B-EAAA-4A01-B420-AF7F3249F0CCQ37256530-1FD37890-DB17-40A3-9506-89D29ADFB3AFQ37350445-29993688-E535-4149-A2FA-699843A5F73FQ37617594-849CC6D1-EC27-4FDF-A647-8FFAC3AA05BFQ37634658-7557E2B9-A2FB-4A8F-A0EE-60867207475CQ37722024-C0610CF5-A6A7-4D40-BF45-451B7397A21EQ38270568-D2EA4DCF-C00C-4677-B514-69E9D6E9F5D6Q38753416-FED1ACEE-71FD-49B7-B095-9DFAF4F0803CQ38889337-1B45F25E-5A48-41D5-9057-BC7FE3212F7BQ38911177-84365CDD-E993-4623-BFB7-A7C4CD365B55Q38925919-F6D6DDF3-5BDB-4656-93E0-6548A9B766F2Q39572847-7AA59227-DEAA-4A84-846B-B9F90950EFC0Q41769106-A994648A-837D-4D44-9AB3-112E5C8F5CBEQ42590793-4DD3B318-A750-4249-BC3E-46536F134498Q42639347-6E681871-CEB9-499B-913B-176B8799C1E0Q47146804-B84212AF-84BA-4DFF-B9DE-60392DB73935Q47321317-58E0BB35-2744-478C-8C1A-1FD3FC5E6FE2Q47962544-05E75111-C490-47F5-8136-6F43702CA2F6Q48355225-17CD219B-2D9C-4416-BED3-7D0FD42D5407Q49632119-333AC20D-996F-49DB-9670-DD6579C40BA3Q49773094-69F996D1-52FA-4331-9121-A5A1A03C3399Q50688561-E1B3B7A1-3EF5-43C5-B95F-6DE0B3AFDCC2Q54974129-2FB721C3-5C65-4EE4-A90B-8D7ACACEBF3FQ55346977-DD4381B4-4E11-4088-915A-9D4831686BE9
P2860
description
2013 nî lūn-bûn
@nan
2013年の論文
@ja
2013年論文
@yue
2013年論文
@zh-hant
2013年論文
@zh-hk
2013年論文
@zh-mo
2013年論文
@zh-tw
2013年论文
@wuu
2013年论文
@zh
2013年论文
@zh-cn
name
Neural bases of hand synergies
@en
type
label
Neural bases of hand synergies
@en
prefLabel
Neural bases of hand synergies
@en
P2860
P356
P1476
Neural bases of hand synergies
@en
P2093
Henrik Jörntell
Marco Santello
P2860
P356
10.3389/FNCOM.2013.00023
P577
2013-04-08T00:00:00Z