Human bipedal balance is a complex sensorimotor task controlled by the central nervous system. Balance impairments, caused by aging or neuromuscular diseases, often lead to falls which are one of the leading causes of injury and subsequent increases in health care costs. Hence, understanding the mechanisms underlying human bipedal balance control has many functional and clinical implications. Traditionally, it was believed that balance control is mediated by subcortical structures. However, evidence from research in the past few decades has shown that the cerebral cortex plays a major role in bipedal balance control. Nevertheless, the cortical contributions in balance control are still unclear. Hence, the purpose of this thesis was to exten...
Maintenance of safe upright static stance regardless of sensory input is imperative for completing a...
Whereas numerous motor control theories describe the control of arm trajectory during reach, the con...
Cortical involvement in postural control is well recognized, however the role of non-visual afferent...
Human movement requires adequate postural control. Stimulation of the sensory systems induces altera...
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...
A traditional view has been that balance control occurs at a very automatic level, primarily involv...
This review examined 83 articles using neuroimaging modalities to investigate the neural correlates ...
This dissertation examined, for the first time, differences between young and elderly volunteers in ...
Safe and effective walking is a crucial part of daily human life, but the number of injuries and res...
Posture control is one of the most fundamental motor tasks; however, the underlying mechanisms are s...
When humans are asked to stand normally, they are not completely motionless. Rather, small amounts o...
Heightened reliance on the cerebral cortex for postural stability with aging is well-known, yet the ...
Understanding how the human brain cortex behaves when the dynamical balance is unexpectedly challeng...
The mechanisms of neural control of human balance, and in particular upright stance, are still not f...
Maintenance of safe upright static stance regardless of sensory input is imperative for completing a...
Whereas numerous motor control theories describe the control of arm trajectory during reach, the con...
Cortical involvement in postural control is well recognized, however the role of non-visual afferent...
Human movement requires adequate postural control. Stimulation of the sensory systems induces altera...
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...
A traditional view has been that balance control occurs at a very automatic level, primarily involv...
This review examined 83 articles using neuroimaging modalities to investigate the neural correlates ...
This dissertation examined, for the first time, differences between young and elderly volunteers in ...
Safe and effective walking is a crucial part of daily human life, but the number of injuries and res...
Posture control is one of the most fundamental motor tasks; however, the underlying mechanisms are s...
When humans are asked to stand normally, they are not completely motionless. Rather, small amounts o...
Heightened reliance on the cerebral cortex for postural stability with aging is well-known, yet the ...
Understanding how the human brain cortex behaves when the dynamical balance is unexpectedly challeng...
The mechanisms of neural control of human balance, and in particular upright stance, are still not f...
Maintenance of safe upright static stance regardless of sensory input is imperative for completing a...
Whereas numerous motor control theories describe the control of arm trajectory during reach, the con...
Cortical involvement in postural control is well recognized, however the role of non-visual afferent...