Journal Article10.1146/ANNUREV-NEURO-062111-150509
Cortical control of arm movements: a dynamical systems perspective.
TL;DR: How a dynamical systems perspective may help to understand why neural activity evolves the way it does, how neural activity relates to movement parameters, and how a unified conceptual framework may result are reviewed.
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Abstract: Our ability to move is central to everyday life Investigating the neural control of movement in general, and the cortical control of volitional arm movements in particular, has been a major research focus in recent decades Studies have involved primarily either attempts to account for single-neuron responses in terms of tuning for movement parameters or attempts to decode movement parameters from populations of tuned neurons Even though this focus on encoding and decoding has led to many seminal advances, it has not produced an agreed-upon conceptual framework Interest in understanding the underlying neural dynamics has recently increased, leading to questions such as how does the current population response determine the future population response, and to what purpose? We review how a dynamical systems perspective may help us understand why neural activity evolves the way it does, how neural activity relates to movement parameters, and how a unified conceptual framework may result
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Citations
Drifting representation with transient resets characterizes sensorimotor transformation in the monkey superior colliculus
TL;DR: In this article , the authors search for a neural correlate of sensorimotor transformation in the activity patterns of simultaneously recorded neurons in the superior colliculus (SC) of rhesus monkeys performing a standard delayed saccade task.
Role of mouse motor cortex in the behavioral response to unpredictable visual feedback
Matthias Heindorf
- 01 Jan 2017
TL;DR: It is found that motor cortex is a critical brain area for execution of visually guided behavior which mediates the learning of the navigation task and is discussed in the context of recent theories of brain function suggesting that the nervous system not only predicts the dynamics of the subject's environment but also generates movement in reaction to future predicted body states.
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•Dissertation
Effects of clinically-relevant electrical stimulation of macaque sensorimotor cortex on neural activity and behavior
Andrew R. Bogaard
- 01 Jan 2018
TL;DR: The monkey model provides direct physiological evidence that is often lacking in human research, and reveals that, under certain conditions, CS produces repeatable changes in brain activity by facilitating or disrupting natural physiological processes.
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The impact of task context on predicting finger movements in a brain-machine interface
TL;DR: In this paper , two rhesus macaques were trained to control a virtual hand with their physical hand while they added springs to each finger group (index or middle-ring-small) or altered their wrist posture.
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Volitional control of movement interacts with proprioceptive feedback in motor cortex during brain-computer interface control in humans
M. F. Liu,Robert A. Gaunt,Jennifer L. Collinger,J. E. Downey,A. P. Batista,M. L. Boninger,D. J. Weber +6 more
TL;DR: Volitional control of movement interacts with proprioceptive feedback in motor cortex during BCI control, demonstrating the importance of sensory input in motor control.
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