scholarly article | Q13442814 |
P50 | author | John Rothwell | Q6255756 |
P2093 | author name string | G Cossu | |
E Muñoz | |||
J Valls-Solé | |||
F Goulart | |||
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P407 | language of work or name | English | Q1860 |
P304 | page(s) | 931-938 | |
P577 | publication date | 1999-05-01 | |
P1433 | published in | Journal of Physiology | Q7743612 |
P1476 | title | Patterned ballistic movements triggered by a startle in healthy humans | |
P478 | volume | 516 ( Pt 3) |
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Q34358373 | Can prepared responses be stored subcortically? |
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Q48423900 | Defective sensorimotor integration in preparation for reaction time tasks in patients with multiple sclerosis |
Q30405628 | Deficits in startle-evoked arm movements increase with impairment following stroke |
Q30377599 | Degraded expression of learned feedforward control in movements released by startle. |
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Q30484365 | Differential effects of startle on reaction time for finger and arm movements. |
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Q30385327 | Does the StartReact Effect Apply to First-Trial Reactive Movements? |
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Q30429826 | Evidence for reticulospinal contributions to coordinated finger movements in humans |
Q53685400 | Evidence for startle as a measurable behavioral indicator of motor learning. |
Q80735430 | Exaggerated auditory startle responses in patients with spinal cord injury |
Q48704989 | Excitability of the pathways mediating the startle reaction before execution of a voluntary movement |
Q46165652 | Excitatory and inhibitory processes in primary motor cortex during the foreperiod of a warned reaction time task are unrelated to response expectancy |
Q48094202 | Fast visuomotor processing made faster by sound |
Q51900676 | First trial postural reactions to unexpected balance disturbances: a comparison with the acoustic startle reaction. |
Q47644863 | Foreknowledge of an impending startling stimulus does not affect the proportion of startle reflexes or latency of StartReact responses. |
Q30359068 | Fractionation of muscle activity in rapid responses to startling cues |
Q47373751 | Go-activation endures following the presentation of a stop-signal: evidence from startle. |
Q61798713 | Gradient-Based Multi-Objective Feature Selection for Gait Mode Recognition of Transfemoral Amputees |
Q47192558 | Haptic Cues for Balance: Use of a Cane Provides Immediate Body Stabilization |
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Q92323898 | High-intensity transcranial magnetic stimulation reveals differential cortical contributions to prepared responses |
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Q92622904 | Imbalanced Corticospinal and Reticulospinal Contributions to Spasticity in Humans with Spinal Cord Injury |
Q91747464 | Impaired posture, movement preparation, and execution during both paretic and nonparetic reaching following stroke |
Q51865061 | Improvements in rate of development and magnitude of force with intense auditory stimuli in patients with Parkinson's disease. |
Q47443978 | Independence of Movement Preparation and Movement Initiation. |
Q50995050 | Influence of postural anxiety on postural reactions to multi-directional surface rotations. |
Q30431795 | Instruction-dependent modulation of the long-latency stretch reflex is associated with indicators of startle |
Q51999241 | Interaction between acoustic startle and habituated neck postural responses in seated subjects. |
Q37155572 | Interaction between startle and voluntary reactions in humans. |
Q26823813 | Interactions between stretch and startle reflexes produce task-appropriate rapid postural reactions |
Q48361359 | Investigation of timing preparation during response initiation and execution using a startling acoustic stimulus |
Q27011466 | Long-latency reflexes account for limb biomechanics through several supraspinal pathways |
Q30480423 | Mechanical perturbations applied during impending movement evoke startle-like responses |
Q47963588 | Mechanical perturbations can elicit triggered reactions in the absence of a startle response |
Q48218973 | More gain less pain: balance control learning shifts the activation patterns of leg and neck muscles and increases muscular parsimony |
Q34427197 | Motor Planning |
Q49048392 | Motor preparation in an anticipation-timing task |
Q30476128 | Motor preparation is modulated by the resolution of the response timing information |
Q64926167 | Neural Constraints Affect the Ability to Generate Hip Abduction Torques When Combined With Hip Extension or Ankle Plantarflexion in Chronic Hemiparetic Stroke. |
Q30384113 | Neural processes mediating the preparation and release of focal motor output are suppressed or absent during imagined movement |
Q36453071 | Neurophysiological aids to the diagnosis of progressive supranuclear palsy (PSP). |
Q34147035 | Neurophysiological characterization of parkinsonian syndromes |
Q42182152 | Not so fast: taste stimulus coding time in the rat revisited |
Q44160548 | Pause time alters the preparation of two-component movements. |
Q24656398 | Perturbation-induced false starts as a test of the jirsa-kelso excitator model |
Q30463925 | Planning of ballistic movement following stroke: insights from the startle reflex |
Q30483127 | Position-dependent torque coupling and associated muscle activation in the hemiparetic upper extremity |
Q30224490 | Preparedness for landing after a self-initiated fall |
Q51891049 | Rapid motor responses are appropriately tuned to the metrics of a visuospatial task. |
Q38650398 | Reaction times can reflect habits rather than computations. |
Q48152933 | Reduced motor preparation during dual-task performance: evidence from startle |
Q48206928 | Response preparation and execution during intentional bimanual pattern switching |
Q48648625 | Response preparation changes during practice of an asynchronous bimanual movement |
Q49133576 | Response preparation changes following practice of an asymmetrical bimanual movement |
Q42563358 | Responses to startling acoustic stimuli indicate that movement-related activation does not build up in anticipation of action |
Q30414072 | Responses to startling acoustic stimuli indicate that movement-related activation is constant prior to action: a replication with an alternate interpretation |
Q47778097 | Reticulospinal Contributions to Gross Hand Function after Human Spinal Cord Injury |
Q55197447 | Reticulospinal Systems for Tuning Motor Commands. |
Q58050131 | Role of brainstem-spinal projections in voluntary movement |
Q48163101 | Sound-evoked vestibular stimulation affects the anticipation of gravity effects during visual self-motion. |
Q90317531 | Stabilizing stretch reflexes are modulated independently from the rapid release of perturbation-triggered motor plans |
Q58696986 | StartReact during gait initiation reveals differential control of muscle activation and inhibition in patients with corticospinal degeneration |
Q90499415 | StartReact effects in first dorsal interosseous muscle are absent in a pinch task, but present when combined with elbow flexion |
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Q30443786 | Startle auditory stimuli enhance the performance of fast dynamic contractions |
Q48802132 | Startle decreases reaction time to active inhibition |
Q30424709 | Startle evoked movement is delayed in older adults: implications for brainstem processing in the elderly |
Q57283767 | Startle evokes nearly identical movements in multi-jointed, two-dimensional reaching tasks |
Q48460519 | Startle produces early response latencies that are distinct from stimulus intensity effects. |
Q48232199 | Startle response is dishabituated during a reaction time task |
Q52130950 | Startle response of human neck muscles sculpted by readiness to perform ballistic head movements. |
Q41002386 | Startle reveals decreased response preparatory activation during a stop-signal task |
Q48864191 | Startle-induced reaction time shortening is not modified by prepulse inhibition |
Q30394657 | Startling acoustic stimuli can evoke fast hand extension movements in stroke survivors |
Q30428721 | Startling speech: eliciting prepared speech using startling auditory stimulus |
Q30479284 | Stretch sensitive reflexes as an adaptive mechanism for maintaining limb stability |
Q30430451 | Subcortical structures in humans can be facilitated by transcranial direct current stimulation |
Q30470577 | TMS perturbs saccade trajectories and unmasks an internal feedback controller for saccades |
Q48588555 | Temporal uncertainty does not affect response latencies of movements produced during startle reactions |
Q47139272 | The Reticulospinal Pathway Does Not Increase Its Contribution to the Strength of Contralesional Muscles in Stroke Survivors as Compared to Ipsilesional Side or Healthy Controls |
Q30448417 | The StartReact effect on self-initiated movements |
Q89414924 | The bottleneck of the psychological refractory period effect involves timing of response initiation rather than response selection |
Q48593917 | The early release of actions by loud sounds in muscles with distinct connectivity |
Q82714234 | The early release of planned movement by acoustic startle can be delayed by transcranial magnetic stimulation over the motor cortex |
Q30486174 | The effect of task instruction on the excitability of spinal and supraspinal reflex pathways projecting to the biceps muscle |
Q57814766 | The effect of transcranial magnetic stimulation on reaction time in progressive supranuclear palsy |
Q83173448 | The effects of a prepulse on the StartReact phenomenon |
Q60464981 | The effects of a startle on awareness of action |
Q81568795 | The effects of a startle on the sit-to-stand manoeuvre |
Q60464957 | The effects of acoustic startle on sensorimotor attenuation prior to movement |
Q81696580 | The effects of an auditory startle on obstacle avoidance during walking |
Q52171284 | The human hand motor area is transiently suppressed by an unexpected auditory stimulus. |
Q50593627 | The influence of movement preparation time on the expression of visuomotor learning and savings. |
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Q37363492 | Visual modulation of proprioceptive reflexes during movement |