Title :
Revealing Ensemble State Transition Patterns in Multi-Electrode Neuronal Recordings Using Hidden Markov Models
Author :
Xydas, Dimitris ; Downes, Julia H. ; Spencer, Matthew C. ; Hammond, Mark W. ; Nasuto, Slawomir J. ; Whalley, Benjamin J. ; Becerra, Victor M. ; Warwick, Kevin
Author_Institution :
Cybern. Res. Group, Univ. of Reading, Reading, UK
Abstract :
In order to harness the computational capacity of dissociated cultured neuronal networks, it is necessary to understand neuronal dynamics and connectivity on a mesoscopic scale. To this end, this paper uncovers dynamic spatiotemporal patterns emerging from electrically stimulated neuronal cultures using hidden Markov models (HMMs) to characterize multi-channel spike trains as a progression of patterns of underlying states of neuronal activity. However, experimentation aimed at optimal choice of parameters for such models is essential and results are reported in detail. Results derived from ensemble neuronal data revealed highly repeatable patterns of state transitions in the order of milliseconds in response to probing stimuli.
Keywords :
bioelectric phenomena; biomedical electrodes; biomedical measurement; complex networks; hidden Markov models; neurophysiology; pattern formation; HMM; dissociated cultured neuronal networks; dynamic spatiotemporal patterns; electrically stimulated neuronal cultures; ensemble neuronal data; ensemble state transition patterns; hidden Markov models; mesoscopic neuronal connectivity; mesoscopic neuronal dynamics; multichannel spike trains; multielectrode neuronal recordings; neuronal activity state pattern progression; Biological neural networks; Electrodes; Hidden Markov models; In vitro; In vivo; Neurons; Training; Cultured neuronal networks; hidden Markov models; multi-channel recordings; neuronal state transitions; Algorithms; Cells, Cultured; Choice Behavior; Electrodes; Markov Chains; Models, Neurological; Models, Statistical; Neural Networks (Computer); Neurons; User-Computer Interface;
Journal_Title :
Neural Systems and Rehabilitation Engineering, IEEE Transactions on
DOI :
10.1109/TNSRE.2011.2157360
