Abstract
The Hodgkin-Huxley model, decades after its first presentation, is still a reference model in neuroscience as it has successfully reproduced the electrophysiological activity of many organisms. The primary signal in the model represents the membrane potential of a neuron. A simple representation of this signal is presented in this paper. The new proposal is an adapted Frequency Modulated Möbius multicomponent model defined as a signal plus error model in which the signal is decomposed as a sum of waves. The main strengths of the method are the simple parametric formulation, the interpretability and flexibility of the parameters that describe and discriminate the waveforms, the estimators’ identifiability and accuracy, and the robustness against noise. The approach is validated with a broad simulation experiment of Hodgkin-Huxley signals and real data from squid giant axons. Interesting differences between simulated and real data emerge from the comparison of the parameter configurations. Furthermore, the potential of the FMM parameters to predict Hodgkin-Huxley model parameters is shown using different Machine Learning methods. Finally, promising contributions of the approach in Spike Sorting and cell-type classification are detailed.
Highlights
Neuroscience is an interdisciplinary science that studies the cellular, functional, behavioral, evolutionary, computational, molecular, and medical aspects of the nervous system
Python simulates Action Potential curves (APs) signals using a modified HH model implementation based on the one available in the Neurodynex package [21]
It is shown that the squid giant axon signals exhibit simpler waveforms and are faithfully described with a simpler model than the simulated HH signals
Summary
Neuroscience is an interdisciplinary science that studies the cellular, functional, behavioral, evolutionary, computational, molecular, and medical aspects of the nervous system. The mathematical approach is one of the most preferred ones, in studying the electrophysiological activity between neurons. The signal that has received most of the attention is the neuron membrane potential, which is the difference in electric potential between the cell’s interior and exterior. This signal is composed of various Action Potential curves (APs). APs are of special importance: they are the informational unit between neurons, and their number and shape determine the morphological, functional, and genetic profile of the cell. For more detail see, [1,2,3,4,5]
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