Understanding how the human brain cortex behaves when the dynamical balance is unexpectedly challenged can be useful to enable fall prevention strategies during daily activities. In this respect, we designed and tested a novel methodological approach to early detect modifications of the scalp-level signals when steady walking is perturbed.Four young adults were asked to manage unexpected bilateral slippages while steadily walking at their self-selected speed. Lower limb kinematics, electromyographic (EMG) and electroencephalographic (EEG; 13 channels from motor and sensory-motor cortex areas) signals were synchronously recorded.EMG signals from Vastus Medialis (both sides) were used to trigger the analysis of the EEG before and after the pe...
Cortical control during walking is most pronounced when the person is perturbed. Although seated loc...
IntroductionRecent advancements in functional near-infrared spectroscopy technology have offered a p...
Walking on two legs is inherently unstable. Still, we humans perform remarkable well at it, mostly w...
Understanding how the human brain cortex behaves when the dynamical balance is unexpectedly challeng...
Background: Behavioral evidence for cortical involvement in reactive balance control in response to ...
Falling is one of the major causes of unintentional death or injury worldwide. People older than 65 ...
Slips and falls are a major cause of injury and death in the United States. During a human slip resp...
Perturbation-based balance training has shown to induce adaptation of reactive balance responses tha...
Abstract: Ageing seems to affect the gait initiation phase thus increasing the risk of falls. Elect...
The contributions of the cerebral cortex to human balance control are clearly demonstrated by the pr...
Heightened reliance on the cerebral cortex for postural stability with aging is well-known, yet the ...
In this paper, we propose the preliminary version of a novel pre-impact fall detection (PIFD) strate...
Background: Slips and falls account for large rates of injury and mortality in multiple populations....
Human bipedal balance is a complex sensorimotor task controlled by the central nervous system. Balan...
The role of sensory systems in the cortical control of dynamic balance was examined using electroenc...
Cortical control during walking is most pronounced when the person is perturbed. Although seated loc...
IntroductionRecent advancements in functional near-infrared spectroscopy technology have offered a p...
Walking on two legs is inherently unstable. Still, we humans perform remarkable well at it, mostly w...
Understanding how the human brain cortex behaves when the dynamical balance is unexpectedly challeng...
Background: Behavioral evidence for cortical involvement in reactive balance control in response to ...
Falling is one of the major causes of unintentional death or injury worldwide. People older than 65 ...
Slips and falls are a major cause of injury and death in the United States. During a human slip resp...
Perturbation-based balance training has shown to induce adaptation of reactive balance responses tha...
Abstract: Ageing seems to affect the gait initiation phase thus increasing the risk of falls. Elect...
The contributions of the cerebral cortex to human balance control are clearly demonstrated by the pr...
Heightened reliance on the cerebral cortex for postural stability with aging is well-known, yet the ...
In this paper, we propose the preliminary version of a novel pre-impact fall detection (PIFD) strate...
Background: Slips and falls account for large rates of injury and mortality in multiple populations....
Human bipedal balance is a complex sensorimotor task controlled by the central nervous system. Balan...
The role of sensory systems in the cortical control of dynamic balance was examined using electroenc...
Cortical control during walking is most pronounced when the person is perturbed. Although seated loc...
IntroductionRecent advancements in functional near-infrared spectroscopy technology have offered a p...
Walking on two legs is inherently unstable. Still, we humans perform remarkable well at it, mostly w...