| scholarly article | Q13442814 |
| P50 | author | David M. Huberdeau | Q41048576 |
| P2093 | author name string | John W Krakauer | |
| Adrian M Haith | |||
| P2860 | cites work | Temporal structure of motor variability is dynamically regulated and predicts motor learning ability. | Q28647120 |
| Cerebellar Purkinje cell activity drives motor learning | Q30424303 | ||
| Gone in 0.6 seconds: the encoding of motor memories depends on recent sensorimotor states. | Q30457468 | ||
| Consolidation of motor memory | Q30493252 | ||
| Distinct contribution of the cortico-striatal and cortico-cerebellar systems to motor skill learning | Q30750434 | ||
| Interacting adaptive processes with different timescales underlie short-term motor learning | Q33243411 | ||
| Multiple motor learning strategies in visuomotor rotation | Q33535811 | ||
| Learning from sensory and reward prediction errors during motor adaptation | Q33851547 | ||
| Patterned ballistic movements triggered by a startle in healthy humans | Q33858570 | ||
| A mechanism for savings in the cerebellum. | Q33947133 | ||
| Cerebellar and prefrontal cortex contributions to adaptation, strategies, and reinforcement learning | Q33988055 | ||
| Rapid motor responses quickly integrate visuospatial task constraints | Q83901104 | ||
| Purkinje-cell plasticity and cerebellar motor learning are graded by complex-spike duration | Q34044827 | ||
| Forward Models for Physiological Motor Control. | Q34186618 | ||
| A novel task for the investigation of action acquisition | Q34295609 | ||
| Declarative and nondeclarative memory: multiple brain systems supporting learning and memory | Q34365553 | ||
| An explicit strategy prevails when the cerebellum fails to compute movement errors | Q34376610 | ||
| Central mechanisms of motor skill learning | Q34641548 | ||
| The serial reaction time task: implicit motor skill learning? | Q34690920 | ||
| A spatial explicit strategy reduces error but interferes with sensorimotor adaptation | Q35055989 | ||
| Rethinking motor learning and savings in adaptation paradigms: model-free memory for successful actions combines with internal models. | Q35099932 | ||
| Neural control of on-line guidance of hand reaching movements | Q35106313 | ||
| Extinction interferes with the retrieval of visuomotor memories through a mechanism involving the sensorimotor cortex. | Q35596251 | ||
| Cerebellar contributions to reach adaptation and learning sensory consequences of action | Q35889719 | ||
| A shared resource between declarative memory and motor memory | Q36045353 | ||
| Learning to predict the future: the cerebellum adapts feedforward movement control | Q36637284 | ||
| Long-term retention explained by a model of short-term learning in the adaptive control of reaching | Q36978570 | ||
| Specificity of reflex adaptation for task-relevant variability | Q37086085 | ||
| Goal-directed control and its antipodes | Q37441947 | ||
| Explicit and implicit contributions to learning in a sensorimotor adaptation task. | Q37597261 | ||
| Procedural learning is impaired in Huntington's disease: Evidence from the serial reaction time task | Q41152465 | ||
| Preserved learning and retention of pattern-analyzing skill in amnesia: dissociation of knowing how and knowing that | Q41645910 | ||
| Cognitive neuroscience and the study of memory | Q41737195 | ||
| Model-based and model-free mechanisms of human motor learning | Q42256178 | ||
| Relation between reaction time and reach errors during visuomotor adaptation. | Q44146580 | ||
| Conditions determining early modification of motor programmes in response to changes in target location | Q48150200 | ||
| Sensory prediction errors drive cerebellum-dependent adaptation of reaching. | Q48165542 | ||
| Reflexive Limb Selection and Control of Reach Direction to Moving Targets in Cats, Monkeys, and Humans | Q48186463 | ||
| Mirror reversal and visual rotation are learned and consolidated via separate mechanisms: recalibrating or learning de novo? | Q48262649 | ||
| Discrete and continuous planning of hand movements and isometric force trajectories | Q48691005 | ||
| Startle reduces recall of a recently learned internal model. | Q50771429 | ||
| Startle stimuli reduce the internal model control in discrete movements. | Q51770833 | ||
| Attention control and the antisaccade task: a response time distribution analysis. | Q51873632 | ||
| Rapid motor responses are appropriately tuned to the metrics of a visuospatial task. | Q51891049 | ||
| The cerebellum updates predictions about the visual consequences of one's behavior. | Q51955985 | ||
| Adaptation to visuomotor transformations: consolidation, interference, and forgetting. | Q51995201 | ||
| An implicit plan overrides an explicit strategy during visuomotor adaptation. | Q52021388 | ||
| Procedural learning in Parkinson's disease and cerebellar degeneration. | Q52060966 | ||
| Learning of visuomotor transformations for vectorial planning of reaching trajectories. | Q52171871 | ||
| Adaptive spatial alignment and strategic perceptual-motor control. | Q52202074 | ||
| Serial reaction time learning and Parkinson's disease: Evidence for a procedural learning deficit | Q52208672 | ||
| Cerebral Changes during Performance of Overlearned Arbitrary Visuomotor Associations | Q63930283 | ||
| Voluntary modification of automatic arm movements evoked by motion of a visual target | Q73443389 | ||
| P433 | issue | 13 | |
| P407 | language of work or name | English | Q1860 |
| P304 | page(s) | 5109-5117 | |
| P577 | publication date | 2015-04-01 | |
| P1433 | published in | Journal of Neuroscience | Q1709864 |
| P1476 | title | The influence of movement preparation time on the expression of visuomotor learning and savings | |
| P478 | volume | 35 |
| Q90330416 | "Two sides of the same coin": constant motor learning speeds up, whereas variable motor learning stabilizes, speed-accuracy movements |
| Q57814500 | A Neural Population Mechanism for Rapid Learning |
| Q93070869 | A rapid visuomotor response on the human upper limb is selectively influenced by implicit motor learning |
| Q52656208 | Accelerating locomotor savings in learning: compressing four training days to one. |
| Q90625552 | Assessing explicit strategies in force field adaptation |
| Q92166497 | Both fast and slow learning processes contribute to savings following sensorimotor adaptation |
| Q89696220 | Causal Role of Motor Preparation during Error-Driven Learning |
| Q40959555 | Cerebellar anodal tDCS increases implicit learning when strategic re-aiming is suppressed in sensorimotor adaptation |
| Q38683878 | Computations underlying sensorimotor learning. |
| Q42081399 | Cue-related Temporal Factors Modulate Movement-related Beta Oscillatory Activity in the Human Motor Circuit |
| Q36729826 | Delayed feedback during sensorimotor learning selectively disrupts adaptation but not strategy use. |
| Q60921897 | Dissociable cognitive strategies for sensorimotor learning |
| Q41058989 | Effect of coordinate frame compatibility on the transfer of implicit and explicit learning across limbs. |
| Q64110435 | Effects of the amount of practice and time interval between practice sessions on the retention of internal models |
| Q50524383 | Eliminating Direction Specificity in Visuomotor Learning. |
| Q50544347 | Error Argumentation Enhance Adaptability in Adults With Low Motor Ability. |
| Q47395295 | Estimating properties of the fast and slow adaptive processes during sensorimotor adaptation. |
| Q38868317 | Estimating the implicit component of visuomotor rotation learning by constraining movement preparation time |
| Q36064133 | Explicit and Implicit Processes Constitute the Fast and Slow Processes of Sensorimotor Learning. |
| Q36496996 | Formation of a long-term memory for visuomotor adaptation following only a few trials of practice |
| Q49162562 | Functional Evidence for Memory Stabilization in Sensorimotor Adaptation: A 24-h Resting-State fMRI Study |
| Q37570318 | High-Frequency Intermuscular Coherence between Arm Muscles during Robot-Mediated Motor Adaptation |
| Q91344681 | How different effectors and action effects modulate the formation of separate motor memories |
| Q89938795 | Human decision making anticipates future performance in motor learning |
| Q89948717 | Implicit adaptation compensates for erratic explicit strategy in human motor learning |
| Q47443978 | Independence of Movement Preparation and Movement Initiation. |
| Q89107627 | Independent voluntary correction and savings in locomotor learning |
| Q88782757 | Interference between competing motor memories developed through learning with different limbs |
| Q90466568 | Minimizing Precision-Weighted Sensory Prediction Errors via Memory Formation and Switching in Motor Adaptation |
| Q92378170 | Motor Learning |
| Q37515342 | Motor Planning, Not Execution, Separates Motor Memories |
| Q92317398 | Movements following force-field adaptation are aligned with altered sense of limb position |
| Q47647039 | Multi-day Adaptation and Savings in Manual and Locomotor Tasks |
| Q58700290 | Neural correlates of multi-day learning and savings in sensorimotor adaptation |
| Q47222657 | Neural predictors of sensorimotor adaptation rate and savings |
| Q63888611 | Pharmacological Dopamine Manipulation Does Not Alter Reward-Based Improvements in Memory Retention during a Visuomotor Adaptation Task |
| Q48120966 | Probability differently modulating the effects of reward and punishment on visuomotor adaptation |
| Q48307997 | Rapid Automatic Motor Encoding of Competing Reach Options |
| Q37393368 | Reorganization between preparatory and movement population responses in motor cortex |
| Q27324264 | Rewarding imperfect motor performance reduces adaptive changes. |
| Q47130311 | Right prefrontal cortex transcranial direct current stimulation enhances multi-day savings in sensorimotor adaptation. |
| Q39530705 | Savings for visuomotor adaptation require prior history of error, not prior repetition of successful actions |
| Q33361749 | Savings upon Re-Aiming in Visuomotor Adaptation |
| Q37018377 | Taking Aim at the Cognitive Side of Learning in Sensorimotor Adaptation Tasks |
| Q89581612 | Task errors drive memories that improve sensorimotor adaptation |
| Q42361317 | Temporally stable adaptation is robust, incomplete and specific. |
| Q47290033 | The Neuropsychology of Movement and Movement Disorders: Neuroanatomical and Cognitive Considerations |
| Q90057851 | The Origins of Anterograde Interference in Visuomotor Adaptation |
| Q51740337 | The contribution of explicit processes to reinforcement-based motor learning. |
| Q55332417 | The relationship between reinforcement and explicit control during visuomotor adaptation. |
| Q90390358 | Time-dependent competition between goal-directed and habitual response preparation |
| Q38621976 | Upper Limb Motor Impairment After Stroke |
| Q89565724 | Using gaze behavior to parcellate the explicit and implicit contributions to visuomotor learning |
| Q91854967 | Visuomotor perturbation in a continuous circle tracing task: novel approach for quantifying motor adaptation |