HomeNewIntroductionQuantum Mind BlogQuantum Mind TheoriesRelated TopicsKey ArticlesReferencesContact UsOnline Book

Related Topics
aesthetics
Anterior cingulate
Anterior cingulate and rewards foregone
Attention versus consciousness
Blindsight & qualia
Busaki: Neural oscillations
Conscious & unconscious vision
Consciousness and executive function
Consciousness as crosstalk
Consciousness v. information
Consciousness, the self & altered states
Coordination and cognition
Coordination between brain regions
Coordination in neural circuits
Correlates of consciousness
Decision making in the frontal cortex
Dendritic spines
Descartes Error
Dopamine and decision making
Dopamine and motivation
Dreams, embodiment & consciousness
Eagleman, the orbitofrontal and Libet
Edmund Rolls: DEcision making
Edmund Rolls: Decision making and consciousness
Empathy circuit
Flexibility in the brain
Flexibility of preferences
Free won't
Gamma and other rhythms
Gamma oscillations
Gamma synchrony and consciousness
Gestalt view of consciousness
Glial cells
I of the Vortex
Implications of anaesthesia
Individual neuron spiking and gamma synchrony
Invalidation of thalamocortical theories
Joseph Le Doux
Machine consciousness
Microtubules and coherent excitations
Nanoneuroscience
Neural circuits weight the options
Neural integration
Neural mechanism that radomnises behaviour
Neurobiology of preferences
Neuronal explosions and perceptual awareness
Neuronal selectivity
Neuronal selectivity and invariance
Neuronal synchronisation and consciousness
Neurons not a switch
Neurophysics of consciousness
Neuroplasticity & mental force
Neuroscience: Short notes
Neurotransmitter release
Oscillation supported information processing
Pain and emotional assessment
Perception and action paths
Perception without perceiver
Perception, action and consciousness
Perception, reporting & neurons
Positive emotionality and the orbitofrontal
Predicting emotional reactions
Protophenomena
Reward and decision circuits
Reward and decision making
Reward value and the orbitofrontal
Selective neurons
Self-organisation
Single cells, proteins & ions
Single-neuron responses
Single-neurons and subjective vision
Small world and chaos
Subcortical structures & cognition
Subjective response and the orbitofrontal
Subjective values in the ventromedial
Subjectivity and the brain
Susan Greenfield: The singularity
Test for entanglement
The amygdala
The Emotional Brain
The Executive Brain
The orbitofrontal cortex
The water melon story
Two visual systems model
Whole Brain

Coordination between brain regions

Coordination in brain systems

Moser, E. I. et al

In:- Dynamic Coordination in the Brain: From Neurons to Mind – Eds. Christoph von der Malsburg, William Phillips & Wolf Singer

Neuroimaging of the human brain indicates coordination of activity between different brain regions. Large scale coordination is shown to span the entire brain. Rhythmic modulation of electrical activity is seen as a possible mechanism to change the couplings amongst neurons. Networks undergoing electrical oscillation facilitate the establishment of synchrony through entrainment and resonance. The precision of synchronisation increases with the frequency of the oscillation. Synchronisation increases the influence of the output of cell assemblies on target neurons.

In synchronised cell populations response to strong excitatory inputs will occur earlier than weak inputs on the rising phase of the oscillation, and this acts as a code to indicate the relative strength of signals. Studies of the retina show that this process indicates that relative strength of visual stimuli. Moser's group considered that oscillation-based synchronisation has a role in cognitive processing. Studies have shown that visual attention correlates with increases in coherence between the parietal and the frontal cortex. They also show an increase in coherence between two different frequency bands, 35-55 Hz (gamma) for bottom-up attention and a lower frequency band for top-down attention.

Coupling between neuron populations depends on the phase relationship between the different groups. Oscillations in different frequency bands such as theta, beta and gamma can coexist. The point in the phase of an input can code for whether it is processed or suppressed. Brain activity has been shown to be organised in spatiotemporal patterns corresponding to gamma fluctuations. These appear to be related to learnt activity, and may represent an attractor that recruits particular brain networks. The role of neuromodulators is suggested to be one of providing the necessary conditions for oscillations rather than directing the oscillations.

This chapter also discusses the question of the zero-phase lag between oscillations in different populations of neurons. This zero-phase lag is ubiquitous in the brain, manifesting over large spatial separations and even between the hemispheres. This is despite significant conduction times between the separated populations. However, it is admitted that the mechanism for the synchronous gamma firing is not well understood.