Artículo
Causal information quantification of prominent dynamical features of biological neurons
Fecha de publicación:
12/2015
Editorial:
The Royal Society
Revista:
Philosophical Transactions of the Royal Society A - Mathematical Physical and Engineering Sciences
ISSN:
1364-503X
Idioma:
Inglés
Tipo de recurso:
Artículo publicado
Clasificación temática:
Resumen
Neurons tend to fire a spike when they are near a bifurcation from the resting state to spiking activity. It is a delicate balance between noise, dynamic currents and initial condition that determines the phase diagram of neural activity. Many possible ionic mechanisms can be accounted for as the source of spike generation. Moreover, the biophysics and the dynamics behind it can usually be described through a phase diagram that involves membrane voltage versus the activation variable of the ionic channel. In this paper, we present a novel methodology to characterize the dynamics of this system, which takes into account the fine temporal ‘structures’ of the complex neuronal signals. This allows us to accurately distinguish the most fundamental properties of neurophysiological neurons that were previously described by Izhikevich considering the phase-space trajectory, using a time causal space: statistical complexity versus Fisher information versus Shannon entropy.
Palabras clave:
Neurons
,
Entropy
,
Statistical Physics
,
Fisher Information Measure
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Identificadores
Colecciones
Articulos(IFLYSIB)
Articulos de INST.FISICA DE LIQUIDOS Y SIST.BIOLOGICOS (I)
Articulos de INST.FISICA DE LIQUIDOS Y SIST.BIOLOGICOS (I)
Citación
Montani, Fernando Fabián; Baravalle, Román; Montangie, Lisandro; Rosso, Osvaldo Aníbal; Causal information quantification of prominent dynamical features of biological neurons; The Royal Society; Philosophical Transactions of the Royal Society A - Mathematical Physical and Engineering Sciences; 373; 2056; 12-2015; 1-14
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