We found a match
Your institution may have access to this item. Find your institution then sign in to continue.
- Title
Rhythm and Synchrony in a Cortical Network Model.
- Authors
Chariker, Logan; Shapley, Robert; Lai-Sang Young
- Abstract
We studied mechanisms for cortical gamma-band activity in the cerebral cortex and identified neurobiological factors that affect such activity. This was done by analyzing the behavior of a previously developed, data-driven, large-scale network model that simulated many visual functions of monkey V1 cortex (Chariker et al., 2016).Gammaactivity was an emergent property of the model. The model's gamma activity, like that of the real cortex, was (1) episodic, (2) variable in frequency and phase, and (3) graded in power with stimulus variables like orientation. The spike firing of the model's neuronal population was only partially synchronous during multiple firing events (MFEs) that occurred at gamma rates. Detailed analysis of the model's MFEs showed that gamma-band activity was multidimensional in its sources. Most spikes were evoked by excitatory inputs. A large fraction of these inputs came from recurrent excitation within the local circuit, but feedforward and feedback excitation also contributed, either through direct pulsing or by raising the overall baseline. Inhibition was responsible for ending MFEs, but disinhibition led directly to only a small minority of the synchronized spikes. As a potential explanation for the wide range of gamma characteristics observed in different parts of cortex, we found that the relative rise times of AMPA and GABA synaptic conductances have a strong effect on the degree of synchrony in gamma.
- Subjects
CEREBRAL cortex; SPECTRAL energy distribution; VISUAL cortex; NEUROANATOMY; INHIBITORY postsynaptic potential
- Publication
Journal of Neuroscience, 2018, Vol 38, Issue 40, p8621
- ISSN
0270-6474
- Publication type
Article
- DOI
10.1523/JNEUROSCI.0675-18.2018