<p>Cortical representations of rhythmic and discrete movements are analyzed and used to create a novel neural decoding algorithm for brain-machine interfaces. This algorithm is then implemented to decode both cyclic movements and reach-and-hold movements in awake behaving rhesus macaques using their cortical activity alone. Finally, a healthy macaque wears and controls a lower body exoskeleton using the developed BMIas a proof of concept of a brain-controlled neuroprosthetic device for locomotion.</p>Dissertatio
As a result of improved understanding of brain mechanisms as well as unprecedented technical advance...
Abstract — Two research communities, motor systems neu-roscience and motor prosthetics, examine the ...
Objective. Neural signals can be decoded and used to move neural prostheses with the purpose of rest...
<p>In recent years, large-scale brain recordings in nonhuman primates have been a driving force for ...
The ability to walk may be critically impacted as the result of neurological injury or disease. Whil...
Neurons in the mammalian motor cortex encode physical parameters of voluntary movements during plann...
Objective: Motor neuroscience and brain-machine interface (BMI) design is based on examining how the...
Brain-machine interface (BMI) systems attempt to restore motor function lost due to injury or neurod...
<p>The loss of the ability to walk as the result of neurological injury or disease critically impact...
When it comes to helping patients with movement-related disorders (e.g. spinal cord injuries, stroke...
A brain machine interface (BMI) is a technology that makes direct connections between neural systems...
Recently, advancement of brain signal processing and neuro-technology have enabled us to interact wi...
Brain?machine interfaces (BMIs) are promising technologies for rehabilitation of upperlimb functions...
Abstract — Neural control of movement is typically studied in constrained environments where there i...
The prospect of assisting disabled patients by translating neural activity from the brain into contr...
As a result of improved understanding of brain mechanisms as well as unprecedented technical advance...
Abstract — Two research communities, motor systems neu-roscience and motor prosthetics, examine the ...
Objective. Neural signals can be decoded and used to move neural prostheses with the purpose of rest...
<p>In recent years, large-scale brain recordings in nonhuman primates have been a driving force for ...
The ability to walk may be critically impacted as the result of neurological injury or disease. Whil...
Neurons in the mammalian motor cortex encode physical parameters of voluntary movements during plann...
Objective: Motor neuroscience and brain-machine interface (BMI) design is based on examining how the...
Brain-machine interface (BMI) systems attempt to restore motor function lost due to injury or neurod...
<p>The loss of the ability to walk as the result of neurological injury or disease critically impact...
When it comes to helping patients with movement-related disorders (e.g. spinal cord injuries, stroke...
A brain machine interface (BMI) is a technology that makes direct connections between neural systems...
Recently, advancement of brain signal processing and neuro-technology have enabled us to interact wi...
Brain?machine interfaces (BMIs) are promising technologies for rehabilitation of upperlimb functions...
Abstract — Neural control of movement is typically studied in constrained environments where there i...
The prospect of assisting disabled patients by translating neural activity from the brain into contr...
As a result of improved understanding of brain mechanisms as well as unprecedented technical advance...
Abstract — Two research communities, motor systems neu-roscience and motor prosthetics, examine the ...
Objective. Neural signals can be decoded and used to move neural prostheses with the purpose of rest...