Data for: Brain control of bimanual movement enabled by recurrent neural networks

Brain-computer interfaces have so far focused largely on enabling the control of a single effector, for example a single computer cursor or robotic arm. Restoring multi-effector motion could unlock greater functionality for people with paralysis (e.g., bimanual movement). However, it may prove challenging to decode the simultaneous motion of multiple effectors, as we recently found that a compositional neural code links movements across all limbs and that neural tuning changes nonlinearly during dual-effector motion. In this study, we demonstrate the feasibility of high-quality bimanual control of two cursors via neural network (NN) decoders. This dataset represents all neural activity recorded during these experiments. This includes the neural activity corresponding to unimanual and bimanual hand movements during (1) instructed delay experiments and (2) real-time BCI control of two cursors.  Code associated with the data can be found here: https://github.com/d-r-deo/bimanualBCI The jou..., Neural signals were recorded from two 96-channel Utah microelectrode arrays using the NeuroPortTM system from Blackrock Microsystems. First, neural signals were analog filtered from 0.3 to 7.5 kHz and subsequently digitized at 30kHz with 250 nV resolution. Next, common mode noise reduction was accomplished via a common average reference filter which subtracted the average signal across the array from every electrode. Finally, a digital high-pass filter at 250 Hz was applied to each electrode prior to spike detection. Spike threshold crossing detection was implemented using a -3.5 x RMS threshold applied to each electrode, where RMS is the electrode-specific root mean square of the time series voltage recorded on that electrode. Neural data was recorded from participant T5 in 3-5 hour “sessions”, with breaks, on scheduled days. T5 either performed attempted movements of one or both hands as governed by an instructed delay task, or performed real-time brain-computer interface control of t..., , # Data from: Brain control of bimanual movement enabled by recurrent neural networks Brain-computer interfaces have so far focused largely on enabling the control of a single effector, for example a single computer cursor or robotic arm. Restoring multi-effector motion could unlock greater functionality for people with paralysis (e.g., bimanual movement). However, it may prove challenging to decode the simultaneous motion of multiple effectors, as we recently found that a compositional neural code links movements across all limbs and that neural tuning changes nonlinearly during dual-effector motion. In this study, we demonstrate the feasibility of high-quality bimanual control of two cursors via neural network (NN) decoders. Neural activity was recorded with microelectrode arrays, and neural features are provided in the form of binned threshold crossings (20 ms bins). This dataset represents all of the neural activity recorded during these experiments. This includes the neural acti...