Cellular and Network Mechanisms of Slow Oscillatory Activity (<1 Hz) and Wave Propagations in a Cortical Network Model
- 1 May 2003
- journal article
- Published by American Physiological Society in Journal of Neurophysiology
- Vol. 89 (5), 2707-2725
- https://doi.org/10.1152/jn.00845.2002
Abstract
Slow oscillatory activity (+-dependent K+ current). Consistent with in vivo data, the input resistance of a model neuron, on average, is the largest at the end of the down state and the smallest during the initial phase of the up state. An activity wave is initiated by spontaneous spike discharges in a minority of neurons, and propagates across the network at a speed of 3–8 mm/s in control and 20–50 mm/s with inhibition block. Our work suggests that long-range excitatory patchy connections contribute significantly to this wave propagation. Finally, we show with this model that various known physiological effects of neuromodulation can switch the network to tonic firing, thus simulating a transition to the waking state.Keywords
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