Multiple local neuronal circuits support different, discrete frequencies of network rhythm in neocortex. Relationships between different frequencies correspond to mechanisms designed to minimise interference, couple activity via stable phase interactions, and control the amplitude of one frequency relative to the phase of another. These mechanisms are proposed to form a framework for spectral information processing. Individual local circuits can also transform their frequency through changes in intrinsic neuronal properties and interactions with other oscillating microcircuits. Here we discuss a frequency transformation in which activity in two co-active local circuits may combine sequentially to generate a third frequency whose period is t...
Neuronal interactions form the basis for our brain function, and oscillations and synchrony are the ...
Communication between cortical sites is mediated by long-range synaptic connections. However, these ...
Cognitive functions likely require that the routes of neural communication can be flexibly modulated...
Multiple local neuronal circuits support different, discrete frequencies of network rhythm in neocor...
The neocortex generates rhythmic electrical activity over a frequency range covering many decades. S...
The neocortex generates rhythmic electrical activity over a frequency range covering many decades. S...
Neural oscillations, including rhythms in the beta1 band (12–20 Hz), are important in various cognit...
Rhythmic voltage oscillations resulting from the summed activity of neuronal populations occur in ma...
The cerebral cortex consists of numerous, densely interconnected, functionally specialized areas tha...
Brain processing depends on the interactions between neuronal groups. Those interactions are governe...
Neuronal oscillations and their inter-areal synchronization may be instrumental in regulating neuron...
© 2018, The Author(s). Frequency-specific oscillations and phase-coupling of neuronal populations ar...
Rhythmic activity in populations of neurons is associated with cognitive and motor function. Our und...
Rhythmic voltage oscillations resulting from the summed activity of neuronal populations occur in ma...
<div><p>Oscillations in electrical activity are a characteristic feature of many brain networks and ...
Neuronal interactions form the basis for our brain function, and oscillations and synchrony are the ...
Communication between cortical sites is mediated by long-range synaptic connections. However, these ...
Cognitive functions likely require that the routes of neural communication can be flexibly modulated...
Multiple local neuronal circuits support different, discrete frequencies of network rhythm in neocor...
The neocortex generates rhythmic electrical activity over a frequency range covering many decades. S...
The neocortex generates rhythmic electrical activity over a frequency range covering many decades. S...
Neural oscillations, including rhythms in the beta1 band (12–20 Hz), are important in various cognit...
Rhythmic voltage oscillations resulting from the summed activity of neuronal populations occur in ma...
The cerebral cortex consists of numerous, densely interconnected, functionally specialized areas tha...
Brain processing depends on the interactions between neuronal groups. Those interactions are governe...
Neuronal oscillations and their inter-areal synchronization may be instrumental in regulating neuron...
© 2018, The Author(s). Frequency-specific oscillations and phase-coupling of neuronal populations ar...
Rhythmic activity in populations of neurons is associated with cognitive and motor function. Our und...
Rhythmic voltage oscillations resulting from the summed activity of neuronal populations occur in ma...
<div><p>Oscillations in electrical activity are a characteristic feature of many brain networks and ...
Neuronal interactions form the basis for our brain function, and oscillations and synchrony are the ...
Communication between cortical sites is mediated by long-range synaptic connections. However, these ...
Cognitive functions likely require that the routes of neural communication can be flexibly modulated...