Abstract
Recent studies have shown that slow cortical potentials in archi-, paleo- and neocortex can phase-lock with nasal respiration. In some of these areas, gamma activity (γ: 30-100Hz) is also coupled to the animal's respiration. It has been hypothesized that these functional relationships play a role in coordinating distributed neural activity. In a similar way, inter-cortical interactions at γ frequency have also been associated as a binding mechanism by which the brain generates temporary opportunities necessary for implementing cognitive functions. The aim of the present study is to explore whether nasal respiration entrains inter-cortical functional interactions at γ frequency during both wakefulness and sleep. Six adult cats chronically prepared for electrographic recordings were employed in this study. Our results show that during wakefulness, slow cortical respiratory potentials are present in the olfactory bulb and several areas of the neocortex. We also found that these areas exhibit cross-frequency coupling between respiratory phase and γ oscillation amplitude. We demonstrate that respiratory phase modulates the inter-cortical gamma coherence between neocortical electrode pairs. On the contrary, slow respiratory oscillation and γ cortical oscillatory entrainments disappear during non-rapid eye movement and rapid eye movement sleep. These results suggest that a single unified phenomenon involves cross-frequency coupling and long-range γ coherence across the neocortex. This fact could be related to the temporal binding process necessary for cognitive functions during wakefulness.
Highlights
The brain is a complex system, in which parallel processing coexist with serial operations within highly interconnected networks, but without a single coordinating center
We determined the presence of cortical respiratory potential (CRP) in the Electrocorticogram recordings (ECoG), and its dependence on the animal’s behavioral state
During W, we observed that slow respiratory waves were accompanied by high amplitude oscillations of similar frequency in the olfactory bulb (OB); similar potentials of lower amplitude were present in the neocortex
Summary
The brain is a complex system, in which parallel processing coexist with serial operations within highly interconnected networks, but without a single coordinating center. This organ integrates neural events that occur at different times and locations into a unified perceptual experience. Neural synchronization at gamma frequency band (γ: 30-100 Hz) is hypothesized as a binding mechanism through which the brain generates transient opportunities for communication and integration of the distributed neural activity necessary for cognitive functions[1,3,4,5,6,7]. Γ synchronization between distant areas of the brain (γ coherence) increases during several cognitive functions in both animals and humans. It was shown that slow oscillations such as the theta rhythm of the hippocampal networks[18,19], the cortical potentials caused by the rhythmic movement of the eyes[20,21] and respiration[19,22,23], can modulate γ activity
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