Principal Dynamic Mode Analysis of the Hodgkin–Huxley Equations

Eikenberry, Steffen E.; Marmarelis, Vasilis Z.

doi:10.1142/s012906571550001x

Cited by 9 publications

(7 citation statements)

References 28 publications

(32 reference statements)

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“…Its scientific significance is that the evolution of neural energy at subthreshold state is directly related to the changes in the neural dark energy in the default mode network, so whether neural energy can modulate the state of neural activity as well as the study of the nature of consciousness has an important scientific significance [23,24]. As far as our current literature is concerned, this problem has not attracted enough attention from neuroscientists, which is because the widely used H-H model is based on a basic assumption that the operation of the ion pump can ensure that the Nernst potential is constant [25]. In addition, modern experimental techniques are also difficult to directly detect the consumed energy in firing procedure of an action potential for a single neuron.…”

Section: Introductionmentioning

confidence: 99%

The essence of neuronal activity from the consistency of two different neuron models

Wang

Zhu

2018

Nonlinear Dyn

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Based on the H-H equation, this study has proposed the calculation and analysis of energy expenditure for a single neuron which is activated at supthreshold and subthreshold, as well as the criterion of the energy expenditure of neurons activated supthreshold and subthreshold, which was the maximum power of a sodium ion pump. Results of the study showed that not only the electrophysiological activities of neurons were strictly restricted by the energy levels in the brain, but also the activities of neurons also had dual nature, meaning that subthreshold neurons were mainly with energy expenditure, while sup-threshold neurons were with both energy absorption and energy expenditure. These new findings were compared with the novel neuro-biophysical models that we have published last year, uncovering that the two models were essentially equivalent.

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Section: Introductionmentioning

confidence: 99%

The essence of neuronal activity from the consistency of two different neuron models

Wang

Zhu

2018

Nonlinear Dyn

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“…The data-based nonparametric methods using the Volterra-Wiener formulation of nonlinear input-output models have been used over the last 40 years to study the dynamics of neural systems [5][6][21][35][36]. One key challenge for these methods has been the parsimonious model representation that allows computational efficiency, estimation accuracy and physiological interpretation of the obtained models.…”

Section: Introductionmentioning

confidence: 99%

“…A significant advance in this regard has been the practicable use of Laguerre expansions of the Volterra kernels [14]. Subsequent methodologies such as Principal Dynamic Modes [23] and Laguerre-Volterra Networks [24] are developed to achieve model parsimony, estimation efficiency and model interpretation, as demonstrated in various physiological systems [15] and, more recently, in the study of cerebral hemodynamics and neuronal dynamics [6][18–22]. …”

Section: Introductionmentioning

confidence: 99%

“…Using the obtained PDMs to represent/ expand the kernels, the Associated Nonlinear Functions (ANFs) are subsequently estimated via regression to obtain the Volterra-equivalent PDM-based model of the system [15]. This approach has been successfully used in various applications [6][14–17][51–53]. …”

Section: Introductionmentioning

confidence: 99%

“…The recent development of a stochastic H-H model is trying to capture some of these variabilities by introducing noise terms in the deterministic H-H equations [41–46]. On the other hand, the data-based non-parametric methods, such as nonlinear autoregressive Volterra (NARV) modeling [5], conventional PDM analysis [6], and recurrent ANN [47] have been utilized to approximate the AP generation process. These non-parametric methods, however, cannot provide biological insights through interpretation of the obtained models.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Methodology of Recurrent Laguerre–Volterra Network for Modeling Nonlinear Dynamic Systems

Geng

Marmarelis

2017

IEEE Trans. Neural Netw. Learning Syst.

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In this paper, we have introduced a general modeling approach for dynamic nonlinear systems that utilizes a variant of the Simulated Annealing (SA) algorithm for training the Laguerre-Volterra Network (LVN) to overcome the local-minima and convergence problems, and employs a pruning technique to achieve sparse LVN representations with ℓ1 regularization. We tested this new approach with computer simulated systems and extended it to Autoregressive Sparse LVN (ASLVN) model structures that are suitable for input-output modeling of nonlinear systems that exhibit transitions in dynamic states, such as the Hodgkin-Huxley (H-H) equations of neuronal firing. Application of the proposed ASLVN to the H-H equations yields a more parsimonious input-output model with improved predictive capability that is amenable to more insightful physiological/biological interpretation.

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Brain works principle followed by neural information processing: a review of novel brain theory

Wang

et al. 2023

Artif Intell Rev

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The way the brain work and its principle of work has long been a big scientific question that scientists have dreamed of solving. However, as is known to all, the brain works at different levels, and the operation at different levels is interactional and mutually coupled. Unfortunately, until now, we still do not know how the nervous system at different levels is interacting and coupling with each other. This review provides some preliminary discussions on how to address these scientific questions, for which we propose a novel theory of the brain called neural energy. Such a theoretical and research approach can couple neural information with neural energy to address the interactions of the nervous system at various levels. Therefore, this review systematically summarizes the neural energy theories and methods proposed by our research in the field of brain science, as well as the internal relationship between mechanics and neural energy theory. Focuses on how to construct a Wang–Zhang (W–Z) neuron model equivalent to Hodgkin–Huxley (H–H) model by using the idea of analytical dynamics. Then, based on this model, we proposed a large-scale neural model and a theoretical framework of global neural coding of the brain in the field of neuroscience. It includes information processing of multiple sensory and perceptual nervous systems such as visual perception, neural mechanism of coupling between default mode network and functional network of brain, memory switching and brain state switching, brain navigation, prediction of new working mechanism of neurons, and interpretation of experimental phenomena that are difficult to be explained by neuroscience. It is proved that the new W–Z neuron model and neural energy theory have unique functions and advantages in neural modeling, neural information processing and methodology. The idea of large-scale neuroscience research with neural energy as the core will provide a potentially powerful research method for promoting the fusion of experimental neuroscience and theoretical neuroscience in the future, and propose a widely accepted brain theory system between experimental neuroscience and theoretical neuroscience. It is of great scientific significance to abandon the shortcomings of reductive and holism research methods in the field of neuroscience, and effectively integrate their respective advantages in methodology.

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Principal Dynamic Mode Analysis of the Hodgkin–Huxley Equations

Cited by 9 publications

References 28 publications

The essence of neuronal activity from the consistency of two different neuron models

The essence of neuronal activity from the consistency of two different neuron models

Methodology of Recurrent Laguerre–Volterra Network for Modeling Nonlinear Dynamic Systems

Brain works principle followed by neural information processing: a review of novel brain theory

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