PLoS ONE (Jan 2013)

Prediction of three-dimensional arm trajectories based on ECoG signals recorded from human sensorimotor cortex.

  • Yasuhiko Nakanishi,
  • Takufumi Yanagisawa,
  • Duk Shin,
  • Ryohei Fukuma,
  • Chao Chen,
  • Hiroyuki Kambara,
  • Natsue Yoshimura,
  • Masayuki Hirata,
  • Toshiki Yoshimine,
  • Yasuharu Koike

DOI
https://doi.org/10.1371/journal.pone.0072085
Journal volume & issue
Vol. 8, no. 8
p. e72085

Abstract

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Brain-machine interface techniques have been applied in a number of studies to control neuromotor prostheses and for neurorehabilitation in the hopes of providing a means to restore lost motor function. Electrocorticography (ECoG) has seen recent use in this regard because it offers a higher spatiotemporal resolution than non-invasive EEG and is less invasive than intracortical microelectrodes. Although several studies have already succeeded in the inference of computer cursor trajectories and finger flexions using human ECoG signals, precise three-dimensional (3D) trajectory reconstruction for a human limb from ECoG has not yet been achieved. In this study, we predicted 3D arm trajectories in time series from ECoG signals in humans using a novel preprocessing method and a sparse linear regression. Average Pearson's correlation coefficients and normalized root-mean-square errors between predicted and actual trajectories were 0.44~0.73 and 0.18~0.42, respectively, confirming the feasibility of predicting 3D arm trajectories from ECoG. We foresee this method contributing to future advancements in neuroprosthesis and neurorehabilitation technology.