TY - JOUR
T1 - Information in a Network of Neuronal Cells: Effect of Cell Density and Short-Term Depression
AU - Onesto, Valentina
AU - Cosentino, Carlo
AU - Di Fabrizio, Enzo M.
AU - Cesarelli, Mario
AU - Amato, Francesco
AU - Gentile, Francesco
N1 - KAUST Repository Item: Exported on 2020-10-01
Acknowledgements: This work has been partially funded from the Italian Minister
of Health (Project no. GR-2010-2320665).
PY - 2016/6/14
Y1 - 2016/6/14
N2 - Neurons are specialized, electrically excitable cells which use electrical to chemical signals to transmit and elaborate information. Understanding how the cooperation of a great many of neurons in a grid may modify and perhaps improve the information quality, in contrast to few neurons in isolation, is critical for the rational design of cell-materials interfaces for applications in regenerative medicine, tissue engineering, and personalized lab-on-a-chips. In the present paper, we couple an integrate-and-fire model with information theory variables to analyse the extent of information in a network of nerve cells. We provide an estimate of the information in the network in bits as a function of cell density and short-term depression time. In the model, neurons are connected through a Delaunay triangulation of not-intersecting edges; in doing so, the number of connecting synapses per neuron is approximately constant to reproduce the early time of network development in planar neural cell cultures. In simulations where the number of nodes is varied, we observe an optimal value of cell density for which information in the grid is maximized. In simulations in which the posttransmission latency time is varied, we observe that information increases as the latency time decreases and, for specific configurations of the grid, it is largely enhanced in a resonance effect.
AB - Neurons are specialized, electrically excitable cells which use electrical to chemical signals to transmit and elaborate information. Understanding how the cooperation of a great many of neurons in a grid may modify and perhaps improve the information quality, in contrast to few neurons in isolation, is critical for the rational design of cell-materials interfaces for applications in regenerative medicine, tissue engineering, and personalized lab-on-a-chips. In the present paper, we couple an integrate-and-fire model with information theory variables to analyse the extent of information in a network of nerve cells. We provide an estimate of the information in the network in bits as a function of cell density and short-term depression time. In the model, neurons are connected through a Delaunay triangulation of not-intersecting edges; in doing so, the number of connecting synapses per neuron is approximately constant to reproduce the early time of network development in planar neural cell cultures. In simulations where the number of nodes is varied, we observe an optimal value of cell density for which information in the grid is maximized. In simulations in which the posttransmission latency time is varied, we observe that information increases as the latency time decreases and, for specific configurations of the grid, it is largely enhanced in a resonance effect.
UR - http://hdl.handle.net/10754/617307
UR - http://www.hindawi.com/journals/bmri/2016/2769698/
UR - http://www.scopus.com/inward/record.url?scp=84976614918&partnerID=8YFLogxK
U2 - 10.1155/2016/2769698
DO - 10.1155/2016/2769698
M3 - Article
C2 - 27403421
SN - 2314-6133
VL - 2016
SP - 1
EP - 12
JO - BioMed Research International
JF - BioMed Research International
ER -