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Literature DB >> 6722270

Impulse responses of automaticity in the Purkinje fiber.

Abstract

We examined the effects of brief current pulses on the pacemaker oscillations of the Purkinje fiber using the model of McAllister , Noble, and Tsien (1975. J. Physiol. [Lond.]. 251:1-57). This model was used to construct phase-response curves for brief electric stimuli to find "black holes," where rhythmic activity of the Purkinje fiber ceases. In our computer simulation, a brief current stimulus of the right magnitude and timing annihilated oscillations in membrane potential. The model also revealed a sequence of alternating periodic and chaotic regimes as the strength of a steady bias current is varied. We compared the results of our computer simulations with experimental work on Purkinje fibers and pointed out the importance of modeling results of this kind for understanding cardiac arrhythmias.

Entities: Disease

Mesh：

Year: 1984 PMID： 6722270 PMCID： PMC1434904 DOI： 10.1016/S0006-3495(84)84228-9

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

18 in total

Review 9. Nonlinear dynamics in cardiology.

Authors: Trine Krogh-Madsen; David J Christini
Journal: Annu Rev Biomed Eng Date: 2012-04-18 Impact factor: 9.590

9 in total

Impulse responses of automaticity in the Purkinje fiber.

Review 1. Unclocklike behaviour of biological clocks.

2. A quantitative description of membrane current and its application to conduction and excitation in nerve.

Review 3. Cellular mechanisms for cardiac arrhythmias.

4. On repetitive activity in nerve.

5. Control of repetitive firing in squid axon membrane as a model for a neuroneoscillator.

6. Pacemaker annihilation: diagnostic and therapeutic implications.

7. Phase resetting and annihilation of pacemaker activity in cardiac tissue.

8. Computer simulation of arrhythmias in a network of coupled excitable elements.

9. Characteristics of reflection as a mechanism of reentrant arrhythmias and its relationship to parasystole.

Review 10. A comparative survey of the function, mechanism and control of cellular oscillators.

1. Bistability dynamics in simulations of neural activity in high-extracellular-potassium conditions.

2. Annihilation of single cell neural oscillations by feedforward and feedback control.

3. Phase resetting of embryonic chick atrial heart cell aggregates. Experiment and theory.

4. Effect of syncytium structure of receptor systems on stochastic resonance induced by chaotic potential fluctuation.

5. Phase resetting in a model of cardiac Purkinje fiber.

6. Parameter-dependent transitions and the optimal control of dynamical diseases.

7. In vitro study of phase resetting and phase locking in a time-comparison circuit in the electric fish, Eigenmannia.

8. Phase resetting and bifurcation in the ventricular myocardium.

Review 9. Nonlinear dynamics in cardiology.