| P50 | author | Eduardo Furtado Martins | Q105708427 |
| | Ghislain Saunier | Q105708451 |
| | Thierry Pozzo | Q41049756 |
| | Daniel Fraiman | Q42321587 |
| | Thiago Lemos | Q46575072 |
| | Claudia D. Vargas | Q59265464 |
| P2860 | cites work | Speed of human biological form and motion processing | Q21090735 |
| | The mirror neuron system and the consequences of its dysfunction | Q22251020 |
| | Cameron Prize Lectures ON SOME RESULTS OF STUDIES IN THE PHYSIOLOGY OF POSTURE. | Q105583780 |
| | Recognizing friends by their walk: Gait perception without familiarity cues | Q105584454 |
| | Recognizing the sex of a walker from a dynamic point-light display | Q105584455 |
| | From mirror neurons to imitation: Facts and speculations | Q105584618 |
| | The neural representation of postural control in humans | Q24674114 |
| | The assessment and analysis of handedness: The Edinburgh inventory | Q26778476 |
| | Neurophysiological mechanisms underlying the understanding and imitation of action | Q28215115 |
| | The assessment and treatment of postural disorders in cerebellar ataxia: a systematic review | Q28308145 |
| | Subjective perception of body sway | Q28764355 |
| | Mechanisms for the acquisition of habitual bipedality: are there biomechanical reasons for the acquisition of upright bipedal posture? | Q28767512 |
| | Visual perception of biological motion and a model for its analysis | Q29038554 |
| | The neural basis of human dance. | Q30351608 |
| | Cortical control of postural responses | Q30415413 |
| | Perceiving affect from arm movement | Q30462956 |
| | The Theory of Event Coding (TEC): A framework for perception and action planning | Q30463185 |
| | Perception and Action Planning | Q30464370 |
| | Changes in the activity of the cerebral cortex relate to postural response modification when warned of a perturbation | Q30489294 |
| | Spatio-temporal differentiation and integration in visual motion perception. An experimental and theoretical analysis of calculus-like functions in visual data processing | Q30559147 |
| | Electrophysiology and brain imaging of biological motion | Q30784643 |
| | Structural encoding and recognition of biological motion: evidence from event-related potentials and source analysis | Q33210671 |
| | Motor imagery modulation of body sway is task-dependent and relies on imagery ability | Q33611679 |
| | Does observation of postural imbalance induce a postural reaction? | Q33851373 |
| | Brain activity evoked by inverted and imagined biological motion | Q33944193 |
| | Flow of activation from V1 to frontal cortex in humans. A framework for defining "early" visual processing | Q34109954 |
| | Brain Areas Active during Visual Perception of Biological Motion | Q34152299 |
| | Superior temporal and premotor brain areas necessary for biological motion perception | Q34657011 |
| | Cerebellar engagement in an action observation network. | Q34988262 |
| | Neural mechanisms for the recognition of biological movements | Q35075740 |
| | Why and how are posture and movement coordinated? | Q35599237 |
| | Regularity of center-of-pressure trajectories depends on the amount of attention invested in postural control | Q35880988 |
| | A review of standing balance recovery from stroke. | Q36281560 |
| | Neural bases of postural control | Q36484279 |
| | Brain regions and genes affecting postural control | Q36707951 |
| | Movement, posture and equilibrium: Interaction and coordination | Q36760833 |
| | Pusher syndrome--a frequent but little-known disturbance of body orientation perception | Q36770017 |
| | Early Preferential Responses to Fear Stimuli in Human Right Dorsal Visual Stream--A Meg Study. | Q36814981 |
| | Two neurocognitive mechanisms of semantic integration during the comprehension of visual real-world events | Q37169014 |
| | Semantic integration in videos of real–world events: An electrophysiological investigation | Q38428192 |
| | Cerebellum-from J. E. Purkyně up to Contemporary Research | Q39011791 |
| | Facial motion in the perception of faces and of emotional expression | Q43524613 |
| | Electrophysiological correlates of biological motion permanence in humans | Q43841225 |
| | Electrophysiological markers of biological motion and human form recognition | Q44468040 |
| | Point-light biological motion perception activates human premotor cortex. | Q46041410 |
| | Human balance, the evolution of bipedalism and dysequilibrium syndrome | Q47297499 |
| | Impairments of trunk movements following left or right hemisphere lesions: dissociation between apraxic errors and postural instability | Q48218828 |
| | An event-related potentials study of biological motion perception in humans | Q48293219 |
| | Brain activity during observation and motor imagery of different balance tasks: an fMRI study | Q48429214 |
| | Perception of human motion | Q48449271 |
| | Do equilibrium constraints modulate postural reaction when viewing imbalance? | Q48588269 |
| | Neural basis subserving the detection of postural instability: an fMRI study | Q48600655 |
| | Walking on a line: a motor paradigm using rotation and reflection symmetry to study mental body transformations | Q48697066 |
| | Biological motion processing: the left cerebellum communicates with the right superior temporal sulcus | Q48825367 |
| | Effects of attention and emotion on face processing in the human brain: an event-related fMRI study | Q48827317 |
| | Specificity of regions processing biological motion | Q48876304 |
| | Does perception of biological motion rely on specific brain regions? | Q48915952 |
| | Biological motion processing as a hallmark of social cognition | Q49027562 |
| | Role of cerebral cortex in human postural control: an EEG study | Q49132199 |
| | Postural modulation induced by pictures depicting prosocial or dangerous contexts. | Q50921190 |
| | A freezing-like posture to pictures of mutilation. | Q50966300 |
| | Distant influences of amygdala lesion on visual cortical activation during emotional face processing. | Q50989125 |
| | Estimating the efficiency of recognizing gender and affect from biological motion. | Q51038016 |
| | Human oscillatory brain activity within gamma band (30-50 Hz) induced by visual recognition of non-stable postures. | Q52028156 |
| | Distinct neural mechanisms for body form and body motion discriminations. | Q52646703 |
| | Cerebral location of international 10-20 system electrode placement. | Q53420693 |
| | The neurophysiology of human biological motion processing: A high-density electrical mapping study | Q57784686 |
| | Postural inflexibility in parkinsonian subjects | Q61714361 |
| | Specific involvement of human parietal systems and the amygdala in the perception of biological motion | Q71106336 |
| | Cerebellar control of postural scaling and central set in stance | Q72865018 |
| | Direction-specific postural instability in subjects with Parkinson's disease | Q81712575 |
| | Kinesthetic motor imagery modulates body sway | Q84197284 |
| P921 | main subject | electroencephalography | Q179965 |
| P304 | page(s) | 217 | |
| P361 | part of | NeuroMat | Q18477654 |
| P577 | publication date | 2017-05-08 | |
| P1433 | published in | Frontiers in Human Neuroscience | Q15727054 |
| P1476 | title | Cerebral Dynamics during the Observation of Point-Light Displays Depicting Postural Adjustments | |
| P478 | volume | 11 | |