A general pattern of non-spiking neuron dynamics under the effect of potassium and calcium channel modifications

Naudin, Loïs; Raison-Aubry, Laetitia; Buhry, Laure

doi:10.1007/s10827-022-00840-w

Cited by 2 publications

(12 citation statements)

References 78 publications

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“…In this model, every individual parameter and state variable has an established electrophysiological meaning. Therefore, CBMs are broadly used to understand 'low-level' functions of neural systems (Eliasmith and Trujillo, 2014;O'Leary et al, 2015), such as monitoring the effects of specific conductance variations on neuronal dynamics (Giovannini et al, 2017;Poirazi and Papoutsi, 2020;Naudin et al, 2022c), or modeling gain-or loss-of-function mutations in genes encoding ion channels (Lemaire et al, 2021).…”

Section: Introductionmentioning

confidence: 99%

“…This type of neuron is found in a wide variety of nervous tissues (Davis and Stretton, 1989b;Goodman et al, 1998;Field and Chichilnisky, 2007), encodes neuronal information in an analog manner through graded responses (Lockery et al, 2009), and plays a crucial role in the functioning of many nervous systems (Roberts and Bush, 1981;Burrows et al, 1988;Laurent and Burrows, 1989;Davis and Stretton, 1989a;Bidaye et al, 2018). Further, three phenotypes of non-spiking neurons can be distinguished (Figure S2), each with its own computational properties (Naudin et al, 2022c): (i) near-linear, defined by smooth depolarizations or hyperpolarizations from the resting potential (phenotype 1), (ii) bistable, characterized by nonlinear transitions between the resting potential and a depolarized potential, with one resting potential (phenotype 2), and (iii) bistable with two resting potentials (phenotype 3). Naudin et al (2022c) described a general pattern of the phenotypic evolution of non-spiking neurons as a function of changes in calcium and potassium conductances.…”

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confidence: 99%

“…Further, three phenotypes of non-spiking neurons can be distinguished (Figure S2), each with its own computational properties (Naudin et al, 2022c): (i) near-linear, defined by smooth depolarizations or hyperpolarizations from the resting potential (phenotype 1), (ii) bistable, characterized by nonlinear transitions between the resting potential and a depolarized potential, with one resting potential (phenotype 2), and (iii) bistable with two resting potentials (phenotype 3). Naudin et al (2022c) described a general pattern of the phenotypic evolution of non-spiking neurons as a function of changes in calcium and potassium conductances. As an example, Figure 1 illustrates the phenotypic transitions of non-spiking neurons as calcium conductance (g Ca ) decreases through a well-posed retinal cone non-spiking CBM (Kourennyi et al, 2004).…”

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confidence: 99%

“…The remainder of the paper is organized as follows. Section 2 describes the evolution of the computational characteristics of the retinal cone CBM as g Ca decreases, that is representative of an ubiquitous and general pattern in non-spiking neurons (Naudin et al, 2022c). Section 3 proposes a numerical procedure to build a phenomenological model 3 that reproduces the computational characteristic evolution of the retinal cone CBM as g Ca reduces, as described in Section 2.…”

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confidence: 99%

“…g Ca Figure 1: Phenotypic transitions of the voltage dynamics as g Ca decreases (Naudin et al, 2022c). A well-posed retinal cone model, with a wild-type phenotype 3, was used as an illustration.…”

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Conductance-Based Phenomenological Nonspiking Model: A Dimensionless and Simple Model That Reliably Predicts the Effects of Conductance Variations on Nonspiking Neuronal Dynamics

2023

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The modeling of single neurons has proven to be an indispensable tool in deciphering the mechanisms underlying neural dynamics and signal processing. In that sense, two types of single-neuron models are extensively used: the conductance-based models (CBMs) and the so-called phenomenological models, which are often opposed in their objectives and their use. Indeed, the first type aims to describe the biophysical properties of the neuron cell membrane that underlie the evolution of its potential, while the second one describes the macroscopic behavior of the neuron without taking into account all of its underlying physiological processes. Therefore, CBMs are often used to study “low-level” functions of neural systems, while phenomenological models are limited to the description of “high-level” functions. In this letter, we develop a numerical procedure to endow a dimensionless and simple phenomenological nonspiking model with the capability to describe the effect of conductance variations on nonspiking neuronal dynamics with high accuracy. The procedure allows determining a relationship between the dimensionless parameters of the phenomenological model and the maximal conductances of CBMs. In this way, the simple model combines the biological plausibility of CBMs with the high computational efficiency of phenomenological models, and thus may serve as a building block for studying both high-level and low-level functions of nonspiking neural networks. We also demonstrate this capability in an abstract neural network inspired by the retina and C. elegans networks, two important nonspiking nervous tissues.

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Section: Introductionmentioning

confidence: 99%

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confidence: 99%

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confidence: 99%

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confidence: 99%

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Conductance-Based Phenomenological Nonspiking Model: A Dimensionless and Simple Model That Reliably Predicts the Effects of Conductance Variations on Nonspiking Neuronal Dynamics

2023

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Biophysical modeling of the whole-cell dynamics of C. elegans motor and interneurons families

Nicoletti,

Chiodo,

Loppini

et al. 2024

PLoS ONE

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The nematode Caenorhabditis elegans is a widely used model organism for neuroscience. Although its nervous system has been fully reconstructed, the physiological bases of single-neuron functioning are still poorly explored. Recently, many efforts have been dedicated to measuring signals from C. elegans neurons, revealing a rich repertoire of dynamics, including bistable responses, graded responses, and action potentials. Still, biophysical models able to reproduce such a broad range of electrical responses lack. Realistic electrophysiological descriptions started to be developed only recently, merging gene expression data with electrophysiological recordings, but with a large variety of cells yet to be modeled. In this work, we contribute to filling this gap by providing biophysically accurate models of six classes of C. elegans neurons, the AIY, RIM, and AVA interneurons, and the VA, VB, and VD motor neurons. We test our models by comparing computational and experimental time series and simulate knockout neurons, to identify the biophysical mechanisms at the basis of inter and motor neuron functioning. Our models represent a step forward toward the modeling of C. elegans neuronal networks and virtual experiments on the nematode nervous system.

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A general pattern of non-spiking neuron dynamics under the effect of potassium and calcium channel modifications

Cited by 2 publications

References 78 publications

Conductance-Based Phenomenological Nonspiking Model: A Dimensionless and Simple Model That Reliably Predicts the Effects of Conductance Variations on Nonspiking Neuronal Dynamics

Conductance-Based Phenomenological Nonspiking Model: A Dimensionless and Simple Model That Reliably Predicts the Effects of Conductance Variations on Nonspiking Neuronal Dynamics

Biophysical modeling of the whole-cell dynamics of C. elegans motor and interneurons families

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