Your search keyword '"CORTICAL NETWORKS"' showing total 4 results

1. Hippocampal gamma and sharp wave/ripples mediate bidirectional interactions with cortical networks during sleep.

Author

Pedrosa, Rafael, Nazari, Mojtaba, Mohajerani, Majid H., Knöpfel, Thomas, Stella, Federico, and Battaglia, Francesco P.

Subjects

*CINGULATE cortex, *DEFAULT mode network, *HIPPOCAMPUS (Brain), *NEOCORTEX, *SLEEP

Abstract

Hippocampus-neocortex interactions during sleep are critical for memory processes: Hippocampally initiated replay contributes to memory consolidation in the neocortex and hippocampal sharp wave/ripples modulate cortical activity. Yet, the spatial and temporal patterns of this interaction are unknown. With voltage imaging, electrocorticography, and laminarly resolved hippocampal potentials, we characterized cortico-hippocampal signaling during anesthesia and nonrapid eye movement sleep. We observed neocortical activation transients, with statistics suggesting a quasi-critical regime, may be helpful for communication across remote brain areas. From activity transients, we identified, in a data-driven fashion, three functional networks. A network overlapping with the default mode network and centered on retrosplenial cortex was the most associated with hippocampal activity. Hippocampal slow gamma rhythms were strongly associated to neocortical transients, even more than ripples. In fact, neocortical activity predicted hippocampal slow gamma and followed ripples, suggesting that consolidation processes rely on bidirectional signaling between hippocampus and neocortex. [ABSTRACT FROM AUTHOR]

Published

2022

2. Structural foundations of resting-state and task-based functional connectivity in the human brain.

Author

Hermundstad, Ann M., Bassett, Danielle S., Brown, Kevin S., Aminoff, Elissa M., Clewett, David, Freeman, Scott, Frithsen, Amy, Johnson, Arianne, Tipper, Christine M., Miller, Michael B., Grafton, Scott T., and Carlson, Jean M.

Subjects

*MAGNETIC resonance imaging, *BRAIN physiology, *DIFFUSION tensor imaging, *OXYGENATION (Chemistry), *EUCLIDEAN distance

Abstract

Magnetic resonance imaging enables the noninvasive mapping of both anatomical white matter connectivity and dynamic patterns of neural activity in the human brain. We examine the relationship between the structural properties of white matter streamlines (structural connectivity) and the functional properties of correlations in neural activity (functional connectivity) within 84 healthy human subjects both at rest and during the performance of attentionand memory-demanding tasks. We show that structural properties, including the length, number, and spatial location of white matter streamlines, are indicative of and can be inferred from the strength of resting-state and task-based functional correlations between brain regions. These results, which are both representative of the entire set of subjects and consistently observed within individual subjects, uncover robust links between structural and functional connectivity in the human brain. [ABSTRACT FROM AUTHOR]

Published

2013

3. Stable and dynamic cortical electrophysiology of induction and emergence with propofol anesthesia.

Author

Breshears, Jonathan D., Roland, Jarod L., Sharma, Mohit, Gaona, Charles M., Freudenburg, Zachary V., Tempelhoff, Rene, Avidan, Michael S., and Leuthardt, Eric C.

Subjects

*ELECTROPHYSIOLOGY, *PROPOFOL, *ANESTHESIA, *INTRAVENOUS anesthetics, *LOSS of consciousness

Abstract

The mechanism(s) by which anesthetics reversibly suppress consciousness are incompletely understood. Previous functional imaging studies demonstrated dynamic changes in thalamic and cortical metabolic activity, as well as the maintained presence of metabolically defined functional networks despite the loss of consciousness. However, the invasive electrophysiology associated with these observations has yet to be studied. By recording electrical activity directly from the cortical surface, electrocorticography (ECoG) provides a powerful method to integrate spatial, temporal, and spectral features of cortical electrophysiology not possible with noninvasive approaches. In this study, we report a unique comprehensive recording of invasive human cortical physiology during both induction and emergence from propofol anesthesia. Propofol-induced transitions in and out of consciousness (defined here as responsiveness) were characterized by maintained large-scale functional networks defined by correlated fluctuations of the slow cortical potential (<0.5 Hz) over the somatomotor cortex, present even in the deeply anesthetized state of burst suppression. Similarly, phase-power coupling between θ- and γ-range frequencies persisted throughout the induction and emergence from anesthesia. Superimposed on this preserved functional architecture were alterations in frequency band power, variance, covariance, and phase-power interactions that were distinct to different frequency ranges and occurred in separable phases. These data support that dynamic alterations in cortical and thalamocortical circuit activity occur in the context of a larger stable architecture that is maintained despite anesthetic-induced alterations in consciousness. [ABSTRACT FROM AUTHOR]

Published

2010

4. Cortical network models of impulse firing in the resting and active states predict cortical energetics.

Author

Bennett MR, Farnell L, Gibson WG, and Lagopoulos J

Subjects

Action Potentials, Animals, Axons metabolism, Cerebral Cortex metabolism, Cerebral Cortex physiology, Humans, Models, Animal, Models, Neurological, Nerve Net, Poisson Distribution, Synaptic Transmission, Thalamus physiology, Anesthesia, Glucose metabolism, Neurons physiology, Oxygen metabolism, Sleep

Abstract

Measurements of the cortical metabolic rate of glucose oxidation [CMR(glc(ox))] have provided a number of interesting and, in some cases, surprising observations. One is the decline in CMR(glc(ox)) during anesthesia and non-rapid eye movement (NREM) sleep, and another, the inverse relationship between the resting-state CMR(glc(ox)) and the transient following input from the thalamus. The recent establishment of a quantitative relationship between synaptic and action potential activity on the one hand and CMR(glc(ox)) on the other allows neural network models of such activity to probe for possible mechanistic explanations of these phenomena. We have carried out such investigations using cortical models consisting of networks of modules with excitatory and inhibitory neurons, each receiving excitatory inputs from outside the network in addition to intermodular connections. Modules may be taken as regions of cortical interest, the inputs from outside the network as arising from the thalamus, and the intermodular connections as long associational fibers. The model shows that the impulse frequency of different modules can differ from each other by less than 10%, consistent with the relatively uniform CMR(glc(ox)) observed across different regions of cortex. The model also shows that, if correlations of the average impulse rate between different modules decreases, there is a concomitant decrease in the average impulse rate in the modules, consistent with the observed drop in CMR(glc(ox)) in NREM sleep and under anesthesia. The model also explains why a transient thalamic input to sensory cortex gives rise to responses with amplitudes inversely dependent on the resting-state frequency, and therefore resting-state CMR(glc(ox)).

Published

2015