Dynamical System Study Of The Hodgkin-Huxley, Fitzhugh-Nagumo And Morris-Lecar Models Of Nerve Membranes

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Date
2019-05
Authors
Razali, Nur Shafika Abel
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Publisher
Universiti Sains Malaysia
Abstract
The mechanism of signals transmitting in a single neuron has been modelled in mathematical neuroscience since the past few decades. One of the well-known mathematical neuronal models is the Hodgkin-Huxley (HH) model that models the dynamics of ionic channels embedded along the axon. When parameter values are varied, the HH model can show a variety of different qualitative behaviours. This means that the nervous system has been altered and this might relate to some neuronal diseases. New medical diagnosis can be made by bringing the parameter values back to its reasonable range. Thus, it is very important to analyse the dynamical systems of a single neuron model in one- and two-parameters bifurcation diagrams, and to study the stabilities of each parameter regions using computer simulations XPPAut and MatCont. Since a HH model consists of 4-differential equations, scientists have reduced the HH model to two-parameters differential equations to reduce the computational load of a more complex neuronal study. Reduced models such as the FitzHugh-Nagumo (FHN) and Morris-Lecar (ML) models are supposed to be able to explain the dynamical view of the mechanism of a single neuron in a better or simpler way without losing any dynamical properties from the original modelling. Unfortunately, in the reducing process, some variables need to be eliminated and this means that some qualitative links to biological data are lost.
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Keywords
Hodgkin-Huxley , Nerve Membranes
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