Title :
Complex oscillations and chaos in a simple neuron model
Author_Institution :
Dept. of Biol. Sci., Pittsburgh Univ., PA, USA
Abstract :
To study the factors that contribute to the changes of burst patterns, the author formulates a four-variable neuronal model. The model contains (i) a voltage-dependent fast Na+ current that is responsible for the upstroke of spikes; (ii) a delayed rectifying voltage-gated K+ current which is responsible for the repolarization of spikes; (iii) a voltage-activated slow Ca2+ current which brings about a slow underlying wave; and (iv) the intracellular Ca2+ concentration which inactivates the Ca2+ current. With this model, the author shows how the model neuron can transform simple oscillations to bursting, to chaos, and to multi-peaked oscillations, as the opening of the gates of K+ and Ca2+ channels slows down. The present simulation thus indicates that the channel gating variables are very important in the generation of chaotic signaling
Keywords :
bioelectric phenomena; cellular biophysics; chaos; neural nets; neurophysiology; oscillations; physiological models; burst patterns; channel gating variables; chaos; chaotic signaling; delayed rectifying voltage-gated K+ current; intracellular Ca2+ concentration; neural nets; neuron model; neurophysiology; oscillations; repolarization; spikes; voltage-activated slow Ca2+ current; voltage-dependent fast Na+ current; Biological system modeling; Biology; Biomembranes; Cells (biology); Chaos; Independent component analysis; Mathematical model; Neurons; Propagation delay; Voltage;
Conference_Titel :
Neural Networks, 1991., IJCNN-91-Seattle International Joint Conference on
Conference_Location :
Seattle, WA
Print_ISBN :
0-7803-0164-1
DOI :
10.1109/IJCNN.1991.155414
