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Difference between revisions of "Cardiac arrhythmias in ion channel dysregulation"

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==Background reading==
==Background reading==


http://rudylab.wustl.edu/research/cell/methodology/index.html
* http://rudylab.wustl.edu/research/cell/methodology/index.html
** Provides C++ and Matlab sources code for very detailed single cell models of canine and guinea pig cardiac ventricular myocytes.  These single cell models include descriptions of


==Possibly related==
 
==Brainstorming ideas==
 
* Want to avoid using an overt 3D model if possible.  2D with wraparound edges can provide a cylindrical sheet of cells which may provide a useful starting point, with more complicated topology or iterations if necessary.
* "Modular" model as opposed to use of differential equation methods

Revision as of 13:04, 6 June 2007

CSSS Santa Fe 2007

Concept

Hi everyone, this is a project related to modeling cardiac tissue with the aim of attempting to understand the conditions under which pathological arrhythmias are evoked. These would include ventricular fibrillation and/or torsades de pointes. Specifically, it would be interesting to look at the the systemic effect of modulating myocyte function by altering specific ion channel parameters, though it would also be interesting to model the effects of myocardial infarction (dead/dying tissue in the heart due to heart attack).

Who's interested (add your name!)

  • Vikas Shah
  • Nathan Menke
  • Kathryn Cooper
  • Simon Angus
  • John Mahoney

Questions to answer

  • Can we create a minimal but useful model of cardiac tissue that appears to have normal function?
  • What are the effects of perturbing ionic concentrations?
  • What are the effects of perturbing ion channel functions?
  • What are the effects of perturbing topological characteristics of the model (e.g. "damaging" part of the "heart")?

Background reading


Brainstorming ideas

  • Want to avoid using an overt 3D model if possible. 2D with wraparound edges can provide a cylindrical sheet of cells which may provide a useful starting point, with more complicated topology or iterations if necessary.
  • "Modular" model as opposed to use of differential equation methods