The contributions of the cerebral cortex to human balance control are clearly demonstrated by the profound impact of cortical lesions on the ability to maintain standing balance. The cerebral cortex is thought to regulate subcortical postural centers to maintain upright balance and posture under varying environmental conditions and task demands. However, the cortical mechanisms that support standing balance remain elusive. Here, we present an EEG-based analysis of cortical oscillatory dynamics during the preparation and execution of balance responses with distinct postural demands. In our experiment, participants responded to backward movements of the support surface either with one forward step or by keeping their feet in place. To challen...
Recent studies demonstrated that the corticospinal pathway is one of the key nodes for the feedback ...
Human movement requires adequate postural control. Stimulation of the sensory systems induces altera...
In standing, corticospinal excitability increases and primary motor cortex (M1) inhibition decreases...
The contributions of the cerebral cortex to human balance control are clearly demonstrated by the pr...
For almost 150 years, researchers have been intrigued by the complex neural control of standing bala...
Postural control is a complex feedback system that relies on vast array of sensory inputs in order t...
Heightened reliance on the cerebral cortex for postural stability with aging is well-known, yet the ...
Background: Although previous studies suggest that postural control requires attention and other cog...
When humans are asked to stand normally, they are not completely motionless. Rather, small amounts o...
Posture control is one of the most fundamental motor tasks; however, the underlying mechanisms are s...
Falling is one of the major causes of unintentional death or injury worldwide. People older than 65 ...
International audienceObjective. Maintaining upright posture is a complex task governed by the integ...
International audienceObjective: As highly social creatures, human beings rely part of their skills ...
Maintenance of safe upright static stance regardless of sensory input is imperative for completing a...
Recent studies demonstrated that the corticospinal pathway is one of the key nodes for the feedback ...
Human movement requires adequate postural control. Stimulation of the sensory systems induces altera...
In standing, corticospinal excitability increases and primary motor cortex (M1) inhibition decreases...
The contributions of the cerebral cortex to human balance control are clearly demonstrated by the pr...
For almost 150 years, researchers have been intrigued by the complex neural control of standing bala...
Postural control is a complex feedback system that relies on vast array of sensory inputs in order t...
Heightened reliance on the cerebral cortex for postural stability with aging is well-known, yet the ...
Background: Although previous studies suggest that postural control requires attention and other cog...
When humans are asked to stand normally, they are not completely motionless. Rather, small amounts o...
Posture control is one of the most fundamental motor tasks; however, the underlying mechanisms are s...
Falling is one of the major causes of unintentional death or injury worldwide. People older than 65 ...
International audienceObjective. Maintaining upright posture is a complex task governed by the integ...
International audienceObjective: As highly social creatures, human beings rely part of their skills ...
Maintenance of safe upright static stance regardless of sensory input is imperative for completing a...
Recent studies demonstrated that the corticospinal pathway is one of the key nodes for the feedback ...
Human movement requires adequate postural control. Stimulation of the sensory systems induces altera...
In standing, corticospinal excitability increases and primary motor cortex (M1) inhibition decreases...