Upon sensory stimulation, primary cortical areas readily engage in narrow-band rhythmic activity between 30 and 90 Hz, the so-called gamma oscillations. Here we show that, when embedded in a balanced network, type-I excitable neurons entrained to the collective rhythm show a discontinuity in their firing-rates between a slow and a fast spiking mode. This jump in the spiking frequencies is characteristic to type II neurons, but is not present in the frequency-current curve (f-I curve) of isolated type I neurons. Therefore, this rate bimodality arises as an emerging network property in type I population models. We have studied the mechanisms underlying the generation of these two firing modes, in order to reproduce the spiking activity of in ...
Gamma rhythms (30–100 Hz) are an extensively studied synchronous brain state responsible for a numbe...
Fast oscillations of the population firing rate in the gamma range (50-200 Hz), where each individua...
Item does not contain fulltextActivated neuronal groups typically engage in rhythmic synchronization...
Upon sensory stimulation, primary cortical areas readily engage in narrow-band rhythmic activity bet...
Computational studies as well as in vivo and in vitro results have shown that many cortical neurons ...
<div><p>Computational studies as well as <em>in vivo</em> and <em>in vitro</em> results have shown t...
Fast oscillations of the population firing rate in the high gamma range (50-200 Hz), where individua...
The network was a randomly connected network of excitatory and inhibitory neurons, that can exhibit ...
Gamma rhythms (30-100 Hz) are an extensively studied synchronous brain state responsible for a numbe...
Gamma rhythms (30-100 Hz) are an extensively studied synchronous brain state responsible for a numbe...
Dynamic excitatory-inhibitory (E-I) balance is a paradigmatic mechanism invoked to explain the irreg...
Fast oscillations of the population firing rate in the gamma range (50-200 Hz), where each individua...
Sensory processing is associated with gamma frequency oscillations (30–80 Hz) in sensory cortices. T...
Understanding the anatomical and functional architecture of the brain is essential for designing neu...
Oscillations are a hallmark of neural population activity in various brain regions with a spectrum c...
Gamma rhythms (30–100 Hz) are an extensively studied synchronous brain state responsible for a numbe...
Fast oscillations of the population firing rate in the gamma range (50-200 Hz), where each individua...
Item does not contain fulltextActivated neuronal groups typically engage in rhythmic synchronization...
Upon sensory stimulation, primary cortical areas readily engage in narrow-band rhythmic activity bet...
Computational studies as well as in vivo and in vitro results have shown that many cortical neurons ...
<div><p>Computational studies as well as <em>in vivo</em> and <em>in vitro</em> results have shown t...
Fast oscillations of the population firing rate in the high gamma range (50-200 Hz), where individua...
The network was a randomly connected network of excitatory and inhibitory neurons, that can exhibit ...
Gamma rhythms (30-100 Hz) are an extensively studied synchronous brain state responsible for a numbe...
Gamma rhythms (30-100 Hz) are an extensively studied synchronous brain state responsible for a numbe...
Dynamic excitatory-inhibitory (E-I) balance is a paradigmatic mechanism invoked to explain the irreg...
Fast oscillations of the population firing rate in the gamma range (50-200 Hz), where each individua...
Sensory processing is associated with gamma frequency oscillations (30–80 Hz) in sensory cortices. T...
Understanding the anatomical and functional architecture of the brain is essential for designing neu...
Oscillations are a hallmark of neural population activity in various brain regions with a spectrum c...
Gamma rhythms (30–100 Hz) are an extensively studied synchronous brain state responsible for a numbe...
Fast oscillations of the population firing rate in the gamma range (50-200 Hz), where each individua...
Item does not contain fulltextActivated neuronal groups typically engage in rhythmic synchronization...