Multiple timescale mixed bursting dynamics in a respiratory neuron model

AbstractExperimental results in rodent medullary slices containing the pre-B ötzinger complex (pre-BötC) have identified multiple bursting mechanisms based on persistent sodium current (INaP) and intracellular Ca2+. The classic two-timescale approach to the analysis of pre-B ötC bursting treats the inactivation ofINaP, the calcium concentration, as well as the Ca2+-dependent inactivation of IP3 as slow variables and considers other evolving quantities as fast variables. Based on its time course, however, it appears that a novel mixed bursting (MB) solution, observed both in recordings and in model pre-B ötC neurons, involves at least three timescales. In this work, we consider a single-compartment model of a pre-BötC inspiratory neuron that can exhibit bothINaP and Ca2+ oscillations and has the ability to produce MB solutions. We use methods of dynamical systems theory, such as phase plane analysis, fast-slow decomposition, and bifurcation analysis, to better understand the mechanisms underlying the MB solution pattern. Rather surprisingly, we discover that a third timescale is not actually required to generate mixed bursting solutions. Through our analysis of timescales, we also elucidate how the pre-B ötC neuron model can be tuned to improve the robustness of the MB solution.
Source: Journal of Computational Neuroscience - Category: Neuroscience Source Type: research