The Bogdanov-Takens Normal Form: A Minimal Model for Single Neuron Dynamics
Author
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Pereira, Ulises
Author
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Coullet, Pierre
Author
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Tirapegui Zurbano, Enrique
Admission date
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2016-01-29T03:36:51Z
Available date
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2016-01-29T03:36:51Z
Publication date
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2015
Cita de ítem
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Entropy 2015, 17, 7859–7874
en_US
Identifier
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DOI: 10.3390/e17127850
Identifier
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https://repositorio.uchile.cl/handle/2250/136878
General note
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Artículo de publicación ISI
en_US
Abstract
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Conductance-based (CB) models are a class of high dimensional dynamical systems derived from biophysical principles to describe in detail the electrical dynamics of single neurons. Despite the high dimensionality of these models, the dynamics observed for realistic parameter values is generically planar and can be minimally described by two equations. In this work, we derive the conditions to have a Bogdanov-Takens (BT) bifurcation in CB models, and we argue that it is plausible that these conditions are verified for experimentally-sensible values of the parameters. We show numerically that the cubic BT normal form, a two-variable dynamical system, exhibits all of the diversity of bifurcations generically observed in single neuron models. We show that the Morris-Lecar model is approximately equivalent to the cubic Bogdanov-Takens normal form for realistic values of parameters. Furthermore, we explicitly calculate the quadratic coefficient of the BT normal form for a generic CB model, obtaining that by constraining the theoretical I-V curve's curvature to match experimental observations, the normal form appears to be naturally cubic. We propose the cubic BT normal form as a robust minimal model for single neuron dynamics that can be derived from biophysically-realistic CB models.
en_US
Patrocinador
dc.description.sponsorship
CONICYT fellowship Beca Magister Nacional
22110804
FONDECYT
1120329