| P2093 | author name string | Gelsy Torres-Oviedo | |
| | Randy Sargent | |
| | Yashar Aucie | |
| | Xunjie Zhang | |
| P2860 | cites work | Effect of boot weight and sole flexibility on gait and physiological responses of firefighters in stepping over obstacles | Q23921289 |
| | Learning of action through adaptive combination of motor primitives | Q24642866 |
| | Temporal structure of motor variability is dynamically regulated and predicts motor learning ability. | Q28647120 |
| | A simple computational principle predicts vocal adaptation dynamics across age and error size | Q28655307 |
| | Adaptation motor learning of arm movements in patients with cerebellar disease | Q30495732 |
| | Interacting adaptive processes with different timescales underlie short-term motor learning | Q33243411 |
| | Savings upon Re-Aiming in Visuomotor Adaptation | Q33361749 |
| | Stimulus generalization, context change, and forgetting | Q33543984 |
| | Muscle activation patterns are bilaterally linked during split-belt treadmill walking in humans | Q33673224 |
| | Thinking about walking: effects of conscious correction versus distraction on locomotor adaptation | Q33783799 |
| | Comparison of the passive dynamics of walking on ground, tied-belt and split-belt treadmills, and via the Gait Enhancing Mobile Shoe (GEMS). | Q51145246 |
| | Learning of visuomotor transformations for vectorial planning of reaching trajectories. | Q52171871 |
| | Accelerating locomotor savings in learning: compressing four training days to one. | Q52656208 |
| | Reliability and Minimal Detectible Change values for gait kinematics and kinetics in healthy adults. | Q53090685 |
| | Characteristics of the gait adaptation process due to split-belt treadmill walking under a wide range of right-left speed ratios in humans. | Q53402113 |
| | Shaping neuroplasticity by using powered exoskeletons in patients with stroke: a randomized clinical trial. | Q55190425 |
| | Gait Asymmetry in Community-Ambulating Stroke Survivors | Q57271958 |
| | Interlimb Coordination During Locomotion: What Can be Adapted and Stored? | Q61764005 |
| | Corrective Muscle Activity Reveals Subject-Specific Sensorimotor Recalibration | Q64078497 |
| | Large Propulsion Demands Increase Locomotor Adaptation at the Expense of Step Length Symmetry | Q64244627 |
| | Analyzing Gait in the Real World Using Wearable Movement Sensors and Frequently Repeated Movement Paths | Q64253871 |
| | The multiple effects of practice: skill, habit and reduced cognitive load. | Q64935578 |
| | Human neuronal interlimb coordination during split-belt locomotion | Q72534328 |
| | Local dynamic stability versus kinematic variability of continuous overground and treadmill walking | Q73690683 |
| | Adaptive control of dynamic balance in human gait on a split-belt treadmill | Q88721200 |
| | Cerebral Contribution to the Execution, But Not Recalibration, of Motor Commands in a Novel Walking Environment | Q89453532 |
| | Time-dependent competition between goal-directed and habitual response preparation | Q90390358 |
| | Movement and perception recalibrate differently across multiple days of locomotor learning | Q91295959 |
| | Using Gait Variability to Predict Inter-individual Differences in Learning Rate of a Novel Obstacle Course | Q92064331 |
| | Explicit Control of Step Timing During Split-Belt Walking Reveals Interdependent Recalibration of Movements in Space and Time | Q92105050 |
| | New neural activity patterns emerge with long-term learning | Q92641695 |
| | Is conservation of center of mass mechanics a priority in human walking? Insights from leg-length asymmetry experiments | Q92986479 |
| | How does the motor system correct for errors in time and space during locomotor adaptation? | Q33816586 |
| | Intact ability to learn internal models of arm dynamics in Huntington's disease but not cerebellar degeneration | Q34380485 |
| | Bilateral Adaptation During Locomotion Following a Unilaterally Applied Resistance to Swing in Nondisabled Adults | Q34430298 |
| | Seeing is believing: effects of visual contextual cues on learning and transfer of locomotor adaptation | Q34513227 |
| | Motion controlled gait enhancing mobile shoe for rehabilitation | Q35697978 |
| | A marching-walking hybrid induces step length adaptation and transfers to natural walking | Q35781115 |
| | Spatial and Temporal Control Contribute to Step Length Asymmetry During Split-Belt Adaptation and Hemiparetic Gait | Q35850644 |
| | Natural error patterns enable transfer of motor learning to novel contexts | Q35951427 |
| | Effects of a wearable exoskeleton stride management assist system (SMA®) on spatiotemporal gait characteristics in individuals after stroke: a randomized controlled trial | Q35985967 |
| | Reach adaptation: what determines whether we learn an internal model of the tool or adapt the model of our arm? | Q36893123 |
| | Effective reinforcement learning following cerebellar damage requires a balance between exploration and motor noise | Q37104896 |
| | Explicit Action Switching Interferes with the Context-Specificity of Motor Memories in Older Adults | Q37681126 |
| | Influence of different safety shoes on gait and plantar pressure: a standardized examination of workers in the automotive industry | Q37709640 |
| | A soft robotic exosuit improves walking in patients after stroke. | Q38651374 |
| | Knee orthosis with variable stiffness and damping that simulates hemiparetic gait | Q38749428 |
| | Longitudinal changes in poststroke spatiotemporal gait asymmetry over inpatient rehabilitation. | Q39192917 |
| | A Portable Gait Asymmetry Rehabilitation System for Individuals with Stroke Using a Vibrotactile Feedback. | Q40751691 |
| | The critical phase for visual control of human walking over complex terrain | Q41433258 |
| | Adaptive control of saccades via internal feedback | Q42538076 |
| | Action history influences subsequent movement via two distinct processes. | Q45778559 |
| | Gait assessment during the initial fitting of an ankle foot orthosis in individuals with stroke | Q47587987 |
| | Adaptive representation of dynamics during learning of a motor task | Q48126188 |
| | Cerebellar contributions to locomotor adaptations during splitbelt treadmill walking. | Q48427661 |
| | Mosaic model for sensorimotor learning and control | Q48779493 |
| P275 | copyright license | Creative Commons Attribution 4.0 International | Q20007257 |
| P6216 | copyright status | copyrighted | Q50423863 |
| P304 | page(s) | 174 | |
| P577 | publication date | 2020-03-06 | |
| P1433 | published in | Frontiers in Neuroscience | Q2177807 |
| P1476 | title | Motorized Shoes Induce Robust Sensorimotor Adaptation in Walking | |
| P478 | volume | 14 | |