PCMI Project: Resetting Reentrant Excitation Oscillations in Different Geometries

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PCMI Project: Resetting Reentrant Excitation Oscillations in Different Geometries Elizabeth Doman mentor: John Milton summer 2005 PCMI Project:Resetting Reentrant ExcitationOscillations in Different Geometries p.1/9

motivation... normal rhythm is set by cells in SA node excitation spreads via conduction system cardiac tissue is excitable... large enough perturbation from rest = action potential = refractory period Reentrant Tachycardia... a conduction pathway loops onto itself self-sustained oscillation of excitation rapid heart rate determined by time it takes excitation to travel around the loop Goal... deliver stimulus to area, utilizing refractory properties, to annihilate tachycardia PCMI Project:Resetting Reentrant ExcitationOscillations in Different Geometries p.2/9

mechanism for annihilation of tachycardia... consequences of refractory property of 1D excitable media... a stimulus delivered... early in the refractory period will produce 0 new waves after the refractory period will produce 2 new waves in just the right spot will produce only 1 new wave two waves colliding head on will be annihilated by the refractory periods simple picture of tachycardia... represent the loop in the conduction system as a 1D ring of excitable media the tachycardia is a traveling wave of excitation on the 1D ring the above observations provide a mechanism for both the annihilation and phase resetting of tachycardia can create phase resetting curves to characterize and study the behavior PCMI Project:Resetting Reentrant ExcitationOscillations in Different Geometries p.3/9

the project... Goal: to explore this phenomena on different geometries ring with a tail ring with a chord Fitzhugh-Nagumo was the suggested model for excitability boundary conditions will be challenging for complicated geometries = so, we took a different approach in modeling excitability... PCMI Project:Resetting Reentrant ExcitationOscillations in Different Geometries p.4/9

Red-Blue-White model of excitation... a number of discrete cells on a ring each cell can be in one of four states the state of each cell is updated every discrete time step each state is assigned an arbitrary numerical value resting: 0 excited: +10 absolutely refractory: relatively refractory: c.. 1 input variables... b = length of absolute refractory period c = length of relative refractory period N = how many cells on a ring show movie of pulse on a ring with N = 50, b = 5, c = 5 PCMI Project:Resetting Reentrant ExcitationOscillations in Different Geometries p.5/9

adding a stimulus... s = strength of the stimulus (note: s 1) ts = time, or phase, at which the stimulus is applied to the ring if the stimulus is delivered to... (i) absolutely refractory cell no response (ii) resting cell 2 new waves propagate in opposite directions (iii) relatively refractory cell... early in the relative refractory period no response late in the relative refractory period 1 new wave propagates back show movies for various t s with N = 50, b = 5, c = 5, s = 4, and threshold=+1 PCMI Project:Resetting Reentrant ExcitationOscillations in Different Geometries p.6/9

phase resetting curve... T0 = time it takes the original pulse to travel around the ring once φs = phase of the stimulus (with respect to a reference cell) φs = 1/N stim is applied to ref cell when the orig pulse is also at that point φs = 1/2 stimulus is applied when original pulse is halfway around the ring φs = 3/4 stimulus is applied when original pulse is a 3 4 φs = (N + 1)/N same result as φ s = 1/N the way around if a stimulus is applied at a given phase... T1 is the time since the ref point last saw a pulse to when it sees another in general.. Tj is the time at which the ref point has seen another j pulses PCMI Project:Resetting Reentrant ExcitationOscillations in Different Geometries p.7/9

phase resetting curve... 2 phase resetting curve for N=20, b=2, c=2 T 1 /T 0 1 for a given N, b, c, and s, stimulate the reference cell at various phases, and calculate T 1 we get the same type of curves generated by Fitzhugh-Nagumo excitability (Glass,1995) 0 φ stim 0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1 PCMI Project:Resetting Reentrant ExcitationOscillations in Different Geometries p.8/9

so what... why did we take this approach... wanted to develop a simple way to observe the behavior found in FN annihilation and phase resetting reproduce the phase resetting curves modify this simple code for different for geometries perhaps examine periodic stimulation then, moving into a continuous PDE model, we might know what to look for of course, there might be more interesting behavior in the PDE model, but... this simple discrete model is a good way to investigate the complicated problem and gets us (me) thinking about the behavior of excitable media in general, and the corresponding rules that govern its behavior PCMI Project:Resetting Reentrant ExcitationOscillations in Different Geometries p.9/9

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