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PNP Cyclic Peptide Ion Channel Model

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Last 12 Months: Updated 16 May, 2008 more ›
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Contributor(s) Brian Radak
Northwestern University, Evanston

Hyonseok Hwang
Kangwon National University, Kangwon-do, Rep. of Korea

George C. Schatz, Mark A. Ratner
Northwestern University, Evanston
At a glance Simulate ion flow in a system modeled after cyclic peptide ion channels using Poisson-Nernst-Planck (PNP) theory.
Screenshots
  • Screenshot #1
  • Screenshot #2
  • Screenshot #3
Description

Poisson-Nernst-Planck (PNP) theory couples the Poisson (describing the electrostatic potential of a system of fixed charges) and Smoluchowski equations (describing the diffusion of charged particles) to describe ion flow. Using complex boundary conditions, these equations can be used to model an ion channel. This model approximates proteins as cylindrical tubes embedded in a lipid membrane. The ions, lipids, protein, and water molecules are all described as dielectric continuums, exchanging the electronic and nuclear polarizations of molecules for dielectric constants and the ion distributions for number density functions. The system of equations in PNP theory is solved simultaneously and self-consistently via the finite difference method, whereby continuous functions are mapped onto a discrete grid. Using several different input parameters, the electrostatic potential, ion concentrations, ion flux, and ion current of the system can be found.
Credits
Brian Radak... GUI development/parallel processing
Hyonseok Hwang... original application programmer

This work was suppored by the Network for Computational Nanotechnology through a grant from the National Science Foundation.
References
  • H. Hwang, G. Schatz, and M. Ratner. J. Phys. Chem. B Vol. 110, No. 13 p 6999-7008 (2006).
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    Cite this work

    If you reference this work in a publication, please cite as follows:

    • H. Hwang, G. Schatz, and M. Ratner. J. Phys. Chem. B Vol. 110, No. 13 p 6999-7008 (2006).

    • Radak, Brian; Hwang, Hyonseok; Schatz, George C.; Ratner, Mark A. (2007), "PNP Cyclic Peptide Ion Channel Model", http://www.nanohub.org/tools/pnppeptide/, accessed on 2008-05-17 02:23:25.

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    In addition, we would appreciate it if you would add the following acknowledgment to your publication:

    • Simulation services for results presented here were provided by the Network for Computational Nanotechnology (NCN) at nanoHUB.org
    Date posted 04 Apr, 2007
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