Contains fulltext : 161819.pdf (publisher's version ) (Open Access)The visual system receives a wealth of sensory information of which only little is relevant for behavior. We present a mechanism in which alpha oscillations serve to prioritize different components of visual information. By way of simulated neuronal networks we show that inhibitory modulation in the alpha range (~10 Hz) can serve to temporally segment the visual information to prevent information overload. Coupled excitatory and inhibitory neurons generate a gamma rhythm in which information is segmented and sorted according to excitability in each alpha cycle. Further details are coded by distributed neuronal firing patterns within each gamma cycle. The ne...
In order to understand the working brain as a network, it is essential to identify the mechanisms by...
A neural oscillator capable of processing graded inputs is studied. The oscillator has two different...
Contains fulltext : 175276.pdf (publisher's version ) (Open Access)Neuronal oscill...
Contains fulltext : 150735.pdf (publisher's version ) (Open Access)Coupling betwee...
Understanding the anatomical and functional architecture of the brain is essential for designing neu...
<div><p>Coupling between neural oscillations in different frequency bands has been proposed to coord...
Coupling between neural oscillations in different frequency bands has been proposed to coordinate ne...
Item does not contain fulltextActivated neuronal groups typically engage in rhythmic synchronization...
Alpha oscillations (8–14 Hz) are proposed to represent an active mechanism of functional inhibition ...
Coupling between neural oscillations in different frequency bands has been proposed to co-ordinate n...
Contains fulltext : 153184.PDF (publisher's version ) (Open Access)Fine-scale temp...
Contains fulltext : 89275.pdf (publisher's version ) (Open Access)In order to unde...
For a long time alpha oscillations have been functionally linked to the processing of visual informa...
Fine-scale temporal organization of cortical activity in the gamma range (*25–80Hz) may play a signi...
Synchronous gamma oscillations are believed to play a prominent role in the information processing o...
In order to understand the working brain as a network, it is essential to identify the mechanisms by...
A neural oscillator capable of processing graded inputs is studied. The oscillator has two different...
Contains fulltext : 175276.pdf (publisher's version ) (Open Access)Neuronal oscill...
Contains fulltext : 150735.pdf (publisher's version ) (Open Access)Coupling betwee...
Understanding the anatomical and functional architecture of the brain is essential for designing neu...
<div><p>Coupling between neural oscillations in different frequency bands has been proposed to coord...
Coupling between neural oscillations in different frequency bands has been proposed to coordinate ne...
Item does not contain fulltextActivated neuronal groups typically engage in rhythmic synchronization...
Alpha oscillations (8–14 Hz) are proposed to represent an active mechanism of functional inhibition ...
Coupling between neural oscillations in different frequency bands has been proposed to co-ordinate n...
Contains fulltext : 153184.PDF (publisher's version ) (Open Access)Fine-scale temp...
Contains fulltext : 89275.pdf (publisher's version ) (Open Access)In order to unde...
For a long time alpha oscillations have been functionally linked to the processing of visual informa...
Fine-scale temporal organization of cortical activity in the gamma range (*25–80Hz) may play a signi...
Synchronous gamma oscillations are believed to play a prominent role in the information processing o...
In order to understand the working brain as a network, it is essential to identify the mechanisms by...
A neural oscillator capable of processing graded inputs is studied. The oscillator has two different...
Contains fulltext : 175276.pdf (publisher's version ) (Open Access)Neuronal oscill...