2013
DOI: 10.1371/journal.pcbi.1003386
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Electrodiffusive Model for Astrocytic and Neuronal Ion Concentration Dynamics

Abstract: The cable equation is a proper framework for modeling electrical neural signalling that takes place at a timescale at which the ionic concentrations vary little. However, in neural tissue there are also key dynamic processes that occur at longer timescales. For example, endured periods of intense neural signaling may cause the local extracellular K+-concentration to increase by several millimolars. The clearance of this excess K+ depends partly on diffusion in the extracellular space, partly on local uptake by… Show more

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Cited by 57 publications
(95 citation statements)
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“…Whereas K + buffering currents through the glia-cell membranes are believed to be the main source of these slow potential shifts [3, 7], it has been estimated that also diffusive currents along extracellular concentration gradients could contribute by shifting ECS potentials by up to 0.4 mV [3]. As ion concentrations in the ECS typically vary on the time scale of seconds [3, 4, 28], it is nevertheless a priori unclear whether diffusion-evoked potential shifts would be picked up by the electrode measurement systems applied in most experiments, which typically have cut-off frequencies of about 0.1–0.2 Hz or higher (see e.g., [29, 30]).…”
Section: Introductionmentioning
confidence: 99%
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“…Whereas K + buffering currents through the glia-cell membranes are believed to be the main source of these slow potential shifts [3, 7], it has been estimated that also diffusive currents along extracellular concentration gradients could contribute by shifting ECS potentials by up to 0.4 mV [3]. As ion concentrations in the ECS typically vary on the time scale of seconds [3, 4, 28], it is nevertheless a priori unclear whether diffusion-evoked potential shifts would be picked up by the electrode measurement systems applied in most experiments, which typically have cut-off frequencies of about 0.1–0.2 Hz or higher (see e.g., [29, 30]).…”
Section: Introductionmentioning
confidence: 99%
“…This requires an extremely high spatiotemporal resolution, which makes PNP models computationally expensive and unsuited for predictions at the tissue/population level [52]. However, a series of modelling schemes have been developed that circumvent the charge relaxation processes, essentially by replacing Poisson’s equation by the constraint that the bulk solution is electroneutral [28, 5258]. The electroneutrality condition is a physical constraint valid at a larger spatiotemporal scale, and thus allows for a dramatic increase in the spatial and temporal grid sizes in the numerical simulations.…”
Section: Introductionmentioning
confidence: 99%
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“…Subsequently, there had been several attempts to improve the solution accuracy for small spaces by introducing fractional Nernst-Planck equations combined with the corresponding fractional cable equations, to model ion electrodiffusion in nerve cells 77,78 . Whilst the cable equation still provides a well-trodden path to study the cell membrane electrodynamics efforts are being made at adopting the Nernst-Planck equations more widely, to model electrogenic processes in neurons and glia more accurately 79,80 .[H3]Cell-impermeable anions (CIAs) and perturbation of electroneutrality. The cell cytoplasm hosts a variety of CIAs -proteins, hydrogen phosphate groups, sulphates, other organic macromolecules -that remain negatively charged at intracellular pH 81 .…”
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confidence: 99%