| scholarly article | Q13442814 |
| P2093 | author name string | S F Giszter | |
| W J Kargo | |||
| P2860 | cites work | From basis functions to basis fields: vector field approximation from sparse data | Q30887491 |
| Linear combinations of primitives in vertebrate motor control | Q34331717 | ||
| Quantization of continuous arm movements in humans with brain injury. | Q35136154 | ||
| Low dimensionality of supraspinally induced force fields | Q36506964 | ||
| Computations Underlying the Execution of Movement: A Biological Perspective | Q37200119 | ||
| Central pattern generators for locomotion, with special reference to vertebrates | Q39493569 | ||
| A biomechanical perspective on spinal mechanisms of coordinated muscular action: an architecture principle | Q40605819 | ||
| Modular organization of motor behavior in the frog's spinal cord | Q40937319 | ||
| Spinal cord segments containing key elements of the central pattern generators for three forms of scratch reflex in the turtle | Q41315531 | ||
| Kinematic strategies and sensorimotor transformations in the wiping movements of frogs | Q44978901 | ||
| Adaptive control for backward quadrupedal walking. III. Stumbling corrective reactions and cutaneous reflex sensitivity | Q46807363 | ||
| The construction of movement by the spinal cord | Q48242419 | ||
| Convergent force fields organized in the frog's spinal cord. | Q48339929 | ||
| Spinal cord modular organization and rhythm generation: an NMDA iontophoretic study in the frog | Q48348920 | ||
| Three-dimensional kinematic analysis of frog hindlimb movement in reflex wiping | Q48374156 | ||
| Vector field approximation: a computational paradigm for motor control and learning | Q48580265 | ||
| The intermediate cerebellum may function as a wave-variable processor | Q48939223 | ||
| The control of rapid limb movement in the cat. IV. Updating of ongoing isometric responses. | Q50847518 | ||
| Neuromuscular responses to gait perturbations in freely moving cats. | Q51878878 | ||
| Afferent roles in hindlimb wipe-reflex trajectories: free-limb kinematics and motor patterns. | Q52123648 | ||
| Quantization of human motions and learning of accurate movements. | Q52186333 | ||
| Stumbling corrective reaction: a phase-dependent compensatory reaction during locomotion | Q52474775 | ||
| A kinematic and electromyographic study of cutaneous reflexes evoked from the forelimb of unrestrained walking cats. | Q52493831 | ||
| Output units of motor behavior: an experimental and modeling study. | Q53913739 | ||
| Motoneurone task groups: coping with kinematic heterogeneity | Q67918588 | ||
| Wipe and flexion reflexes of the frog. I. Kinematics and EMG patterns | Q70756864 | ||
| The vertebrate scratch reflex | Q71220699 | ||
| Force path curvature and conserved features of muscle activation | Q71558118 | ||
| Kinematic analysis of reaching in the cat | Q72210072 | ||
| Intermittency in preplanned elbow movements persists in the absence of visual feedback | Q77410041 | ||
| Muscle activation patterns during two types of voluntary single-joint movement | Q77410062 | ||
| Segmental afferent regulation of hindlimb wiping in the spinal frog | Q77935731 | ||
| P433 | issue | 1 | |
| P304 | page(s) | 409-426 | |
| P577 | publication date | 2000-01-01 | |
| P1433 | published in | Journal of Neuroscience | Q1709864 |
| P1476 | title | Rapid correction of aimed movements by summation of force-field primitives | |
| P478 | volume | 20 |
| Q55322332 | A Systematic Review on Muscle Synergies: From Building Blocks of Motor Behavior to a Neurorehabilitation Tool. |
| Q30488480 | A compact representation of drawing movements with sequences of parabolic primitives |
| Q41875154 | A computational analysis of motor synergies by dynamic response decomposition. |
| Q46394020 | A neural basis for motor primitives in the spinal cord. |
| Q33593627 | A simple experimentally based model using proprioceptive regulation of motor primitives captures adjusted trajectory formation in spinal frogs |
| Q37152428 | Adjustments of motor pattern for load compensation via modulated activations of muscle synergies during natural behaviors. |
| Q36162180 | An Optogenetic Demonstration of Motor Modularity in the Mammalian Spinal Cord |
| Q36254024 | Brain Connectivity Associated with Muscle Synergies in Humans |
| Q42661696 | Central and sensory contributions to the activation and organization of muscle synergies during natural motor behaviors. |
| Q74227749 | Choosing a wavelet for single-trial EMG |
| Q34174517 | Combinations of muscle synergies in the construction of a natural motor behavior. |
| Q37009395 | Combining modules for movement |
| Q35160405 | Common muscle synergies for control of center of mass and force in nonstepping and stepping postural behaviors. |
| Q40155107 | Consequences of biomechanically constrained tasks in the design and interpretation of synergy analyses |
| Q42692857 | Control of fast-reaching movements by muscle synergy combinations. |
| Q73009661 | Coordination and localization in spinal motor systems |
| Q57868829 | Coordination of Locomotion with Voluntary Movements in Humans |
| Q48333886 | Differential activation of neuromuscular compartments in the rabbit masseter muscle during different oral behaviors |
| Q37612063 | Dimensionality of joint torques and muscle patterns for reaching. |
| Q40545473 | Distinguishing synchronous and time-varying synergies using point process interval statistics: motor primitives in frog and rat. |
| Q47340598 | Early skill learning is expressed through selection and tuning of cortically represented muscle synergies. |
| Q57728637 | Embodied Cognition: A field guide |
| Q36978603 | Endpoint force fluctuations reveal flexible rather than synergistic patterns of muscle cooperation |
| Q75264674 | Five basic muscle activation patterns account for muscle activity during human locomotion |
| Q51719437 | Foot force direction control during leg pushes against fixed and moving pedals in persons post-stroke. |
| Q35918036 | Generalization in vision and motor control |
| Q34711638 | Hindlimb endpoint forces predict movement direction evoked by intraspinal microstimulation in cats |
| Q80825025 | Individual premotor drive pulses, not time-varying synergies, are the units of adjustment for limb trajectories constructed in spinal cord |
| Q33607614 | Interactions with compliant loads alter stretch reflex gains but not intermuscular coordination |
| Q46270159 | Intermuscular coherence reflects functional coordination |
| Q34406073 | Intrinsic musculoskeletal properties stabilize wiping movements in the spinalized frog. |
| Q43081016 | MACOP modular architecture with control primitives |
| Q57868791 | Modular Control of Limb Movements during Human Locomotion |
| Q37147494 | Modular control of varied locomotor tasks in children with incomplete spinal cord injuries |
| Q51667070 | Modular premotor drives and unit bursts as primitives for frog motor behaviors. |
| Q37152464 | Modularity of endpoint force patterns evoked using intraspinal microstimulation in treadmill trained and/or neurotrophin-treated chronic spinal cats |
| Q57284995 | Modularity speeds up motor learning by overcoming mechanical bias in musculoskeletal geometry |
| Q48905942 | Modularity, evolution, and the binding problem: a view from stability theory |
| Q35217653 | Modules in the brain stem and spinal cord underlying motor behaviors. |
| Q50859409 | Motor Neuron Pools of Synergistic Thigh Muscles Share Most of Their Synaptic Input. |
| Q42152116 | Motor cortical regulation of sparse synergies provides a framework for the flexible control of precision walking |
| Q35212958 | Motor learning through the combination of primitives |
| Q38093281 | Motor primitives and synergies in the spinal cord and after injury--the current state of play |
| Q92355413 | Motor primitives are determined in early development and are then robustly conserved into adulthood |
| Q30939835 | Motor primitives--new data and future questions |
| Q52317639 | Movement Decomposition in the Primary Motor Cortex. |
| Q52032926 | Movement smoothness changes during stroke recovery. |
| Q37617594 | Muscle synergies evoked by microstimulation are preferentially encoded during behavior |
| Q38102689 | Muscle synergies in neuroscience and robotics: from input-space to task-space perspectives |
| Q36533438 | Neuromuscular adjustments of gait associated with unstable conditions |
| Q34185503 | New perspectives on spinal motor systems |
| Q53581400 | Plasticity and alterations of trunk motor cortex following spinal cord injury and non-stepping robot and treadmill training. |
| Q48684745 | Pointing movements may be produced in different frames of reference depending on the task demand |
| Q36966335 | Primitives, premotor drives, and pattern generation: a combined computational and neuroethological perspective |
| Q41512565 | Quantitative evaluation of muscle synergy models: a single-trial task decoding approach |
| Q45140559 | Recruitment of motor neuronal persistent inward currents shapes withdrawal reflexes in the frog. |
| Q39987483 | Reorganization of muscle synergies during multidirectional reaching in the horizontal plane with experimental muscle pain |
| Q90664534 | Robot-Driven Locomotor Perturbations Reveal Synergy-Mediated, Context-Dependent Feedforward and Feedback Mechanisms of Adaptation |
| Q35902425 | Robustness of muscle synergies underlying three-dimensional force generation at the hand in healthy humans |
| Q30856425 | Shared and specific muscle synergies in natural motor behaviors |
| Q37183027 | Simplified and effective motor control based on muscle synergies to exploit musculoskeletal dynamics |
| Q35126706 | Sophisticated spinal contributions to motor control |
| Q58599103 | Spinal control of muscle synergies for adult mammalian locomotion |
| Q24652597 | Spinal cord injury: present and future therapeutic devices and prostheses |
| Q28395121 | Spinal cord modularity: evolution, development, and optimization and the possible relevance to low back pain in man |
| Q28083463 | Spinal primitives and intra-spinal micro-stimulation (ISMS) based prostheses: a neurobiological perspective on the "known unknowns" in ISMS and future prospects |
| Q35951374 | Task-level feedback can explain temporal recruitment of spatially fixed muscle synergies throughout postural perturbations |
| Q58213941 | The Construction of Movement with Behavior-Specific and Behavior-Independent Modules |
| Q24652206 | The case for and against muscle synergies |
| Q40174464 | The neural origin of muscle synergies |
| Q35785767 | The use of flexible arm muscle synergies to perform an isometric stabilization task |
| Q35572541 | Trunk robot rehabilitation training with active stepping reorganizes and enriches trunk motor cortex representations in spinal transected rats |
Search more.