Your search keyword '"neuronal modeling"' showing total 5 results

1. Corrigendum: Complex Dynamics in Simplified Neuronal Models: Reproducing Golgi Cell Electroresponsiveness

Author

Alice Geminiani, Claudia Casellato, Francesca Locatelli, Francesca Prestori, Alessandra Pedrocchi, and Egidio D'Angelo

Subjects

neuronal modeling, point neuron, leaky integrate-and-fire, model simplification, neuronal electroresponsiveness, Golgi cell, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Published

2019

2. Complex Dynamics in Simplified Neuronal Models: Reproducing Golgi Cell Electroresponsiveness

Author

Alice Geminiani, Claudia Casellato, Francesca Locatelli, Francesca Prestori, Alessandra Pedrocchi, and Egidio D'Angelo

Subjects

neuronal modeling, point neuron, leaky integrate-and-fire, model simplification, neuronal electroresponsiveness, Golgi cell, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Brain neurons exhibit complex electroresponsive properties – including intrinsic subthreshold oscillations and pacemaking, resonance and phase-reset – which are thought to play a critical role in controlling neural network dynamics. Although these properties emerge from detailed representations of molecular-level mechanisms in “realistic” models, they cannot usually be generated by simplified neuronal models (although these may show spike-frequency adaptation and bursting). We report here that this whole set of properties can be generated by the extended generalized leaky integrate-and-fire (E-GLIF) neuron model. E-GLIF derives from the GLIF model family and is therefore mono-compartmental, keeps the limited computational load typical of a linear low-dimensional system, admits analytical solutions and can be tuned through gradient-descent algorithms. Importantly, E-GLIF is designed to maintain a correspondence between model parameters and neuronal membrane mechanisms through a minimum set of equations. In order to test its potential, E-GLIF was used to model a specific neuron showing rich and complex electroresponsiveness, the cerebellar Golgi cell, and was validated against experimental electrophysiological data recorded from Golgi cells in acute cerebellar slices. During simulations, E-GLIF was activated by stimulus patterns, including current steps and synaptic inputs, identical to those used for the experiments. The results demonstrate that E-GLIF can reproduce the whole set of complex neuronal dynamics typical of these neurons – including intensity-frequency curves, spike-frequency adaptation, post-inhibitory rebound bursting, spontaneous subthreshold oscillations, resonance, and phase-reset – providing a new effective tool to investigate brain dynamics in large-scale simulations.

Published

2018

3. A flexible, interactive software tool for fitting the parameters of neuronal models.

Author

Friedrich, Péter, Vella, Michael, Gulyás, Attila I., Freund, Tamás F., and Káli, Szabolcs

Subjects

SOFTWARE development tools, PYTHON programming language, SIMULATION software, GRAPHICAL user interfaces, ALGORITHM software

Abstract

The construction of biologically relevant neuronal models as well as model-based analysis of experimental data often requires the simultaneous fitting of multiple model parameters, so that the behavior of the model in a certain paradigm matches (as closely as possible) the corresponding output of a real neuron according to some predefined criterion. Although the task of model optimization is often computationally hard, and the quality of the results depends heavily on technical issues such as the appropriate choice (and implementation) of cost functions and optimization algorithms, no existing program provides access to the best available methods while also guiding the user through the process effectively. Our software, called Optimizer, implements a modular and extensible framework for the optimization of neuronal models, and also features a graphical interface which makes it easy for even non-expert users to handle many commonly occurring scenarios. Meanwhile, educated users can extend the capabilities of the program and customize it according to their needs with relatively little effort. Optimizer has been developed in Python, takes advantage of open-source Python modules for nonlinear optimization, and interfaces directly with the NEURON simulator to run the models. Other simulators are supported through an external interface. We have tested the program on several different types of problems of varying complexity, using different model classes. As targets, we used simulated traces from the same or a more complex model class, as well as experimental data. We successfully used Optimizer to determine passive parameters and conductance densities in compartmental models, and to fit simple (adaptive exponential integrate-and-fire) neuronal models to complex biological data. Our detailed comparisons show that Optimizer can handle a wider range of problems, and delivers equally good or better performance than any other existing neuronal model fitting tool. [ABSTRACT FROM AUTHOR]

Published

2014

4. Corrigendum: Complex Dynamics in Simplified Neuronal Models: Reproducing Golgi Cell Electroresponsiveness.

Author

Geminiani, Alice, Casellato, Claudia, Locatelli, Francesca, Prestori, Francesca, Pedrocchi, Alessandra, and D'Angelo, Egidio

Subjects

CELLS

Abstract

Highlights from the article: Keywords: neuronal modeling; point neuron; leaky integrate-and-fire; model simplification; neuronal electroresponsiveness; Golgi cell; cerebellum Neuronal modeling, point neuron, leaky integrate-and-fire, model simplification, neuronal electroresponsiveness, Golgi cell, cerebellum.

Published

2019

5. A flexible, interactive software tool for fitting the parameters of neuronal models

Author

Attila I. Gulyás, Tamás F. Freund, Szabolcs Káli, Michael Vella, and Péter Friedrich

Subjects

Computer science, Biomedical Engineering, Neuroscience (miscellaneous), neuronal modeling, computer.software_genre, Extensibility, Nonlinear programming, lcsh:RC321-571, 03 medical and health sciences, 0302 clinical medicine, Software, neuronal modelling, Methods Article, parameter optimization, lcsh:Neurosciences. Biological psychiatry. Neuropsychiatry, 030304 developmental biology, Graphical user interface, computer.programming_language, 0303 health sciences, Biological data, business.industry, software, graphical user interface, Experimental data, Modular design, Python (programming language), simulation, Computer Science Applications, python, Computer engineering, Data mining, model fitting, business, computer, 030217 neurology & neurosurgery, Neuroscience

Abstract

The construction of biologically relevant neuronal models as well as model-based analysis of experimental data often requires the simultaneous fitting of multiple model parameters, so that the behavior of the model in a certain paradigm matches (as closely as possible) the corresponding output of a real neuron according to some predefined criterion. Although the task of model optimization is often computationally hard, and the quality of the results depends heavily on technical issues such as the appropriate choice (and implementation) of cost functions and optimization algorithms, no existing program provides access to the best available methods while also guiding the user through the process effectively. Our software, called Optimizer, implements a modular and extensible framework for the optimization of neuronal models, and also features a graphical interface which makes it easy for even non-expert users to handle many commonly occurring scenarios. Meanwhile, educated users can extend the capabilities of the program and customize it according to their needs with relatively little effort. Optimizer has been developed in Python, takes advantage of open-source Python modules for nonlinear optimization, and interfaces directly with the NEURON simulator to run the models. Other simulators are supported through an external interface. We have tested the program on several different types of problems of varying complexity, using different model classes. As targets, we used simulated traces from the same or a more complex model class, as well as experimental data. We successfully used Optimizer to determine passive parameters and conductance densities in compartmental models, and to fit simple (adaptive exponential integrate-and-fire) neuronal models to complex biological data. Our detailed comparisons show that Optimizer can handle a wider range of problems, and delivers equally good or better performance than any other existing neuronal model fitting tool.

Published

2014