Abstract
The time spent in collecting current samples for decoder calibration and the computational burden brought by high-dimensional neural recordings remain two challenging problems in intracortical brain-machine interfaces (iBMIs). Decoder calibration optimization approaches have been proposed, and neuron selection methods have been used to reduce computational burden. However, few methods can solve both problems simultaneously. In this article, we present a symmetrical-uncertainty-based transfer learning (SUTL) method that combines transfer learning with feature selection. The proposed method uses symmetrical uncertainty to quantitatively measure three indices for feature selection: stationarity, importance and redundancy of the feature. By selecting the stationary features, the disparities between the historical data and current data can be diminished, and the historical data can be effectively used for decoder calibration, thereby reducing the demand for current data. After selecting the important and non-redundant features, only the channels corresponding to them need to work; thus, the computational burden is reduced. The proposed method was tested on neural data recorded from two rhesus macaques to decode the reaching position or grasping gesture. The results showed that the SUTL method diminished the disparities between the historical data and current data, while achieving superior decoding performance with the needs of only ten current samples each category, less than 10% the number of features and 30% the number of neural recording channels. Additionally, unlike most studies on iBMIs, feature selection was implemented instead of neuron selection, and the average decoding accuracy achieved by the former was 6.6% higher.
Highlights
I NTRACORTICAL brain-machine interfaces aim to help paralysed patients and amputees regain motor functions, by translating neural activities directly into motor commands to control assistive devices [1]–[4]
Neural activities are recorded by implanting neural electrodes into various brain regions, such as the primary motor cortex (M1) [1], the premotor cortex (PM) [5] and the posterior parietal cortex (PPC) [6]
The data processed using the symmetrical-uncertainty-based transfer learning (SUTL) method achieved significantly lower Davies-Bouldin index (DBI) values than those that were processed without applying it for both monkeys. These results indicated that the disparities between historical data and current data have been effectively diminished, which is the key that the SUTL method could be effective
Summary
I NTRACORTICAL brain-machine interfaces aim to help paralysed patients and amputees regain motor functions, by translating neural activities directly into motor commands to control assistive devices [1]–[4]. Neural activities are recorded by implanting neural electrodes into various brain regions, such as the primary motor cortex (M1) [1], the premotor cortex (PM) [5] and the posterior parietal cortex (PPC) [6]. IBMIs have achieved great progress [7], [8], and have been deployed in clinical research [9], [10]. With the development of micro-electronics technology, electrodes with more channels have been developed, and more neurons from different brain regions can be recorded synchronously [13], [14]. More channels guarantee more information, which, corresponds to greater computational burden. Our first question is, how can the computational burden be reduced while ensuring decoding performance?
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