<div><p>Even in the absence of sensory stimulation the brain is spontaneously active. This background “noise” seems to be the dominant cause of the notoriously high trial-to-trial variability of neural recordings. Recent experimental observations have extended our knowledge of trial-to-trial variability and spontaneous activity in several directions: 1. Trial-to-trial variability systematically decreases following the onset of a sensory stimulus or the start of a motor act. 2. Spontaneous activity states in sensory cortex outline the region of evoked sensory responses. 3. Across development, spontaneous activity aligns itself with typical evoked activity patterns. 4. The spontaneous brain activity prior to the presentation of an ambiguous s...
Throughout our everyday experience, we are continuously exposed to dynamic and highly complex stream...
Neural populations respond to the repeated presentations of a sensory stimulus with correlated varia...
<p>The network self-organizes during repeated presentations of the sequences “AXXX_ _ _ …” (33%) and...
Even in the absence of sensory stimulation the brain is spontaneously active. This background “noise...
Even in the absence of sensory stimulation the brain is spontaneously active. This background “noise...
The brain is a highly dynamic and variable system: when the same stimulus is presented to the same a...
<div><p>Spontaneous activity is commonly observed in a variety of cortical states. Experimental evid...
Behavior is controlled by complex neural networks in which neurons process thousands of inputs. Howe...
Neuronal responses to repeated presentations of identical visual stimuli are variable. The source of...
Cortical networks exhibit intrinsic dynamics that drive coordinated, large-scale fluctuations across...
Animals rely on different decision strategies when faced with ambiguous or uncertain cues. Depending...
Neuronal responses to repeated presentations of identical visual stimuli are variable. The source of...
Typical responses of cortical neurons to identical sensory stimuli appear highly variable. It has th...
SummaryNeocortical assemblies produce complex activity patterns both in response to sensory stimuli ...
Understanding the relation between spontaneously active and stimulus evoked cortical dynamics is a r...
Throughout our everyday experience, we are continuously exposed to dynamic and highly complex stream...
Neural populations respond to the repeated presentations of a sensory stimulus with correlated varia...
<p>The network self-organizes during repeated presentations of the sequences “AXXX_ _ _ …” (33%) and...
Even in the absence of sensory stimulation the brain is spontaneously active. This background “noise...
Even in the absence of sensory stimulation the brain is spontaneously active. This background “noise...
The brain is a highly dynamic and variable system: when the same stimulus is presented to the same a...
<div><p>Spontaneous activity is commonly observed in a variety of cortical states. Experimental evid...
Behavior is controlled by complex neural networks in which neurons process thousands of inputs. Howe...
Neuronal responses to repeated presentations of identical visual stimuli are variable. The source of...
Cortical networks exhibit intrinsic dynamics that drive coordinated, large-scale fluctuations across...
Animals rely on different decision strategies when faced with ambiguous or uncertain cues. Depending...
Neuronal responses to repeated presentations of identical visual stimuli are variable. The source of...
Typical responses of cortical neurons to identical sensory stimuli appear highly variable. It has th...
SummaryNeocortical assemblies produce complex activity patterns both in response to sensory stimuli ...
Understanding the relation between spontaneously active and stimulus evoked cortical dynamics is a r...
Throughout our everyday experience, we are continuously exposed to dynamic and highly complex stream...
Neural populations respond to the repeated presentations of a sensory stimulus with correlated varia...
<p>The network self-organizes during repeated presentations of the sequences “AXXX_ _ _ …” (33%) and...