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Literature DB >> 17586567

Quasi-steady approximation for ion channel currents.

Abstract

Currents through ion channels are determined (among other parameters) by the concentration difference across the membrane containing the channel and the diffusive transport of the conducted ion toward the channel and away from it. Calculation of the current requires solving the diffusion equation around the channel. Here, we provide a quasi-steady approximation for the current and the local concentrations at the channel together with formulas linking the current and local concentrations at the channel to bulk concentrations and diffusion properties of the compartments.

Mesh：

Substances：
Ion Channels

Year: 2007 PMID： 17586567 PMCID： PMC1989719 DOI： 10.1529/biophysj.107.104299

Source DB: PubMed Journal: Biophys J ISSN： 0006-3495 Impact factor: 4.033

11 in total

10. A multiscale computational model of spatially resolved calcium cycling in cardiac myocytes: from detailed cleft dynamics to the whole cell concentration profiles.

Authors: Janine Vierheller; Wilhelm Neubert; Martin Falcke; Stephen H Gilbert; Nagaiah Chamakuri
Journal: Front Physiol Date: 2015-09-24 Impact factor: 4.566

Quasi-steady approximation for ion channel currents.

1. From calcium blips to calcium puffs: theoretical analysis of the requirements for interchannel communication.

2. Release currents of IP(3) receptor channel clusters and concentration profiles.

3. Stability of membrane bound reactions.

4. Monte Carlo analysis of obstructed diffusion in three dimensions: application to molecular diffusion in organelles.

5. Analytical steady-state solution to the rapid buffering approximation near an open Ca2+ channel.

Review 6. The endoplasmic reticulum Ca2+ store: a view from the lumen.

7. Range of messenger action of calcium ion and inositol 1,4,5-trisphosphate.

8. Unitary Ca2+ current through cardiac ryanodine receptor channels under quasi-physiological ionic conditions.

9. Buffers and oscillations in intracellular Ca2+ dynamics.

10. Microdomains with high Ca2+ close to IP3-sensitive channels that are sensed by neighboring mitochondria.

1. How does intracellular Ca2+ oscillate: by chance or by the clock?

2. Padé Approximation of a Stationary Single-Channel Ca²⁺ Nanodomain.

3. Mapping Interpuff Interval Distribution to the Properties of Inositol Trisphosphate Receptors.

4. Efficient Approximations for Stationary Single-Channel Ca²⁺ Nanodomains across Length Scales.

5. Extension of Rapid Buffering Approximation to Ca²⁺ Buffers with Two Binding Sites.

6. Calcium signals driven by single channel noise.

7. Simulating diffusion from a cluster of point sources using propagation integrals.

8. Modeling of the modulation by buffers of Ca2+ release through clusters of IP3 receptors.

9. Stationary Ca²⁺ nanodomains in the presence of buffers with two binding sites.

10. A multiscale computational model of spatially resolved calcium cycling in cardiac myocytes: from detailed cleft dynamics to the whole cell concentration profiles.