Item does not contain fulltextActivated neuronal groups typically engage in rhythmic synchronization in the gamma-frequency range (30-100 Hz). Experimental and modeling studies demonstrate that each gamma cycle is framed by synchronized spiking of inhibitory interneurons. Here, we review evidence suggesting that the resulting rhythmic network inhibition interacts with excitatory input to pyramidal cells such that the more excited cells fire earlier in the gamma cycle. Thus, the amplitude of excitatory drive is recoded into phase values of discharges relative to the gamma cycle. This recoding enables transmission and read out of amplitude information within a single gamma cycle without requiring rate integration. Furthermore, variation of ph...
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 ...
Contains fulltext : 153184.PDF (publisher's version ) (Open Access)Fine-scale temp...
GABAergic interneurones are necessary for the emergence of hippocampal gamma-frequency network oscil...
GABAergic interneurones are necessary for the emergence of hippocampal gamma-frequency network oscil...
Networks of synchronized fast-spiking interneurons are thought to be key elements in the generation ...
Local gamma-band (~30-100Hz) oscillations in the brain, produced by feedback inhibition on a charact...
Neuronal oscillations at various frequency bands play an important role in neuronal information proc...
†Andrea Hasenstaub and Stephani Otte equally contributed to this work. Many lines of theoretical and...
SummaryNeurons recruited for local computations exhibit rhythmic activity at gamma frequencies. The ...
Gamma (30-80 Hz) rhythms in hippocampus and neocortex resulting from the interaction of excitatory a...
Cortical circuits are thought to multiplex firing rate codes with temporal codes that rely on oscill...
Contains fulltext : 161819.pdf (publisher's version ) (Open Access)The visual syst...
Gamma rhythms (30-100 Hz) are an extensively studied synchronous brain state responsible for a numbe...
<div><p>In networks of excitatory and inhibitory neurons with mutual synaptic coupling, specific dri...
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 ...
Contains fulltext : 153184.PDF (publisher's version ) (Open Access)Fine-scale temp...
GABAergic interneurones are necessary for the emergence of hippocampal gamma-frequency network oscil...
GABAergic interneurones are necessary for the emergence of hippocampal gamma-frequency network oscil...
Networks of synchronized fast-spiking interneurons are thought to be key elements in the generation ...
Local gamma-band (~30-100Hz) oscillations in the brain, produced by feedback inhibition on a charact...
Neuronal oscillations at various frequency bands play an important role in neuronal information proc...
†Andrea Hasenstaub and Stephani Otte equally contributed to this work. Many lines of theoretical and...
SummaryNeurons recruited for local computations exhibit rhythmic activity at gamma frequencies. The ...
Gamma (30-80 Hz) rhythms in hippocampus and neocortex resulting from the interaction of excitatory a...
Cortical circuits are thought to multiplex firing rate codes with temporal codes that rely on oscill...
Contains fulltext : 161819.pdf (publisher's version ) (Open Access)The visual syst...
Gamma rhythms (30-100 Hz) are an extensively studied synchronous brain state responsible for a numbe...
<div><p>In networks of excitatory and inhibitory neurons with mutual synaptic coupling, specific dri...
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 ...
Contains fulltext : 153184.PDF (publisher's version ) (Open Access)Fine-scale temp...