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Cultured Cortical Neurons Can Perform Blind Source Separation According to the Free-Energy Principle
by
Jimbo, Yasuhiko
, Isomura, Takuya
, Kotani, Kiyoshi
in
Action Potentials - physiology
/ Animals
/ Cell interaction
/ Cells, Cultured
/ Cerebral Cortex - cytology
/ Cerebral Cortex - physiology
/ Composting
/ Energy Transfer
/ Machine Learning
/ Models, Neurological
/ Models, Statistical
/ Nerve Net - physiology
/ Neural networks
/ Neurons
/ Neurons - physiology
/ Observations
/ Pattern Recognition, Physiological - physiology
/ Physiological aspects
/ Principal Component Analysis
/ Rats
/ Signal processing
2015
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Cultured Cortical Neurons Can Perform Blind Source Separation According to the Free-Energy Principle
by
Jimbo, Yasuhiko
, Isomura, Takuya
, Kotani, Kiyoshi
in
Action Potentials - physiology
/ Animals
/ Cell interaction
/ Cells, Cultured
/ Cerebral Cortex - cytology
/ Cerebral Cortex - physiology
/ Composting
/ Energy Transfer
/ Machine Learning
/ Models, Neurological
/ Models, Statistical
/ Nerve Net - physiology
/ Neural networks
/ Neurons
/ Neurons - physiology
/ Observations
/ Pattern Recognition, Physiological - physiology
/ Physiological aspects
/ Principal Component Analysis
/ Rats
/ Signal processing
2015
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Cultured Cortical Neurons Can Perform Blind Source Separation According to the Free-Energy Principle
by
Jimbo, Yasuhiko
, Isomura, Takuya
, Kotani, Kiyoshi
in
Action Potentials - physiology
/ Animals
/ Cell interaction
/ Cells, Cultured
/ Cerebral Cortex - cytology
/ Cerebral Cortex - physiology
/ Composting
/ Energy Transfer
/ Machine Learning
/ Models, Neurological
/ Models, Statistical
/ Nerve Net - physiology
/ Neural networks
/ Neurons
/ Neurons - physiology
/ Observations
/ Pattern Recognition, Physiological - physiology
/ Physiological aspects
/ Principal Component Analysis
/ Rats
/ Signal processing
2015
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Cultured Cortical Neurons Can Perform Blind Source Separation According to the Free-Energy Principle
Journal Article
Cultured Cortical Neurons Can Perform Blind Source Separation According to the Free-Energy Principle
2015
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Overview
Blind source separation is the computation underlying the cocktail party effect--a partygoer can distinguish a particular talker's voice from the ambient noise. Early studies indicated that the brain might use blind source separation as a signal processing strategy for sensory perception and numerous mathematical models have been proposed; however, it remains unclear how the neural networks extract particular sources from a complex mixture of inputs. We discovered that neurons in cultures of dissociated rat cortical cells could learn to represent particular sources while filtering out other signals. Specifically, the distinct classes of neurons in the culture learned to respond to the distinct sources after repeating training stimulation. Moreover, the neural network structures changed to reduce free energy, as predicted by the free-energy principle, a candidate unified theory of learning and memory, and by Jaynes' principle of maximum entropy. This implicit learning can only be explained by some form of Hebbian plasticity. These results are the first in vitro (as opposed to in silico) demonstration of neural networks performing blind source separation, and the first formal demonstration of neuronal self-organization under the free energy principle.
Publisher
Public Library of Science,Public Library of Science (PLoS)
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