Decoding Hindlimb Movement for a Brain Machine Interface after a Complete Spinal Transection
TL;DR: Neural control is a general feature of the motor cortex, not restricted to forelimb movements, and can be regained after spinal injury.
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Abstract: Stereotypical locomotor movements can be made without input from the brain after a complete spinal transection. However, the restoration of functional gait requires descending modulation of spinal circuits to independently control the movement of each limb. To evaluate whether a brain-machine interface (BMI) could be used to regain conscious control over the hindlimb, rats were trained to press a pedal and the encoding of hindlimb movement was assessed using a BMI paradigm. Off-line, information encoded by neurons in the hindlimb sensorimotor cortex was assessed. Next neural population functions, or weighted representations of the neuronal activity, were used to replace the hindlimb movement as a trigger for reward in real-time (on-line decoding) in three conditions: while the animal could still press the pedal, after the pedal was removed and after a complete spinal transection. A novel representation of the motor program was learned when the animals used neural control to achieve water reward (e.g. more information was conveyed faster). After complete spinal transection, the ability of these neurons to convey information was reduced by more than 40%. However, this BMI representation was relearned over time despite a persistent reduction in the neuronal firing rate during the task. Therefore, neural control is a general feature of the motor cortex, not restricted to forelimb movements, and can be regained after spinal injury.
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Long term, stable brain machine interface performance using local field potentials and multiunit spikes
TL;DR: It is demonstrated that LFPs can be used in a biomimetic BMI to control a computer cursor, and the results suggest that the monkeys were able to stabilize the relationship between neural activity and cursor movement during online BMI control, despite variability in the relationship Between Neural activity and hand movements.
Brain-controlled modulation of spinal circuits improves recovery from spinal cord injury
Marco Bonizzato,Galyna Pidpruzhnykova,Jack DiGiovanna,Polina Shkorbatova,N. V. Pavlova,Silvestro Micera,Silvestro Micera,Grégoire Courtine,Grégoire Courtine +8 more
TL;DR: The authors show in rats that a proportional stimulation interface permits voluntary movement and augments recovery in conjunction with rehabilitation, demonstrating the relevance of brain-controlled neuromodulation therapies to augment recovery from motor disorders.
Engagement of the Rat Hindlimb Motor Cortex across Natural Locomotor Behaviors.
Jack DiGiovanna,Nadia Dominici,Lucia Friedli,Jacopo Rigosa,Simone Duis,Julie Kreider,Janine Beauparlant,Rubia van den Brand,Marco Schieppati,Silvestro Micera,Grégoire Courtine +10 more
TL;DR: Robust task-specific neuronal population responses revealed that the rat motor cortex displays similar modulation as other mammals during locomotion, which emphasizes the importance of the behavioral procedure to engage the motor cortex during motor control studies, gait rehabilitation, and locomotor neuroprosthetic developments in rats.
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Brain-controlled neuromuscular stimulation to drive neural plasticity and functional recovery
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