Online adaptive group-wise sparse NPLS for ECoG neural signal decoding

TL;DR

This paper introduces an online adaptive sparse decoder for brain-computer interfaces that reduces neural feature space, maintains high decoding accuracy, and is suitable for portable, low-power applications.

Contribution

The paper presents the PREW-NPLS algorithm, a novel online adaptive sparse decoder that improves BCI decoding efficiency and reduces electrode usage compared to existing methods.

Findings

PREW-NPLS achieves comparable decoding performance to REW-NPLS.

Sparse models with up to 75% electrode reduction maintain accuracy.

Suitable for portable BCI applications with low computational resources.

Abstract

Objective. Brain-computer interfaces (BCIs) create a new communication pathway between the brain and an effector without neuromuscular activation. BCI experiments highlighted high intra and inter-subjects variability in the BCI decoders. Although BCI model is generally relying on neurological markers generalizable on the majority of subjects, it requires to generate a wide range of neural features to include possible neurophysiological patterns. However, the processing of noisy and high dimensional features, such as brain signals, brings several challenges to overcome such as model calibration issues, model generalization and interpretation problems and hardware related obstacles. Approach. An online adaptive group-wise sparse decoder named Lp-Penalized REW-NPLS algorithm (PREW-NPLS) is presented to reduce the feature space dimension employed for BCI decoding. The proposed decoder was designed to create BCI systems with low computational cost suited for portable applications and tested during offline pseudo-online study based on online closed-loop BCI control of the left and right 3D arm movements of a virtual avatar from the ECoG recordings of a tetraplegic patient. Main results. PREW-NPLS algorithm highlight at least as good decoding performance as REW-NPLS algorithm. However, the decoding performance obtained with PREW-NPLS were achieved thanks to sparse models with up to 64% and 75% of the electrodes set to 0 for the left and right hand models respectively using L1-PREW-NPLS. Significance. The designed solution proposed an online incremental adaptive algorithm suitable for online adaptive decoder calibration which estimate sparse decoding solutions. The PREW-NPLS models are suited for portable applications with low computational power using only small number of electrodes with degrading the decoding performance.