An inhibitory gate for state transition in cortex

Zucca, Stefano; D’Urso, Giulia; Pasquale, Valentina; Vecchia, Dania; Pica, Giuseppe; Bovetti, Serena; Moretti, Claudio; Varani, Stefano; Molano-Mazón, Manuel; Chiappalone, Michela; Panzeri, Stefano; Fellin, Tommaso

doi:10.7554/elife.26177

Cited by 100 publications

(133 citation statements)

References 77 publications

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“…The hallmark of physiological sleep is the occurrence of slow waves and OFF-periods, often referred to in the sleep literature as cortical bistability (7,10). OFF-periods are caused by the enhancement of adaptation (or activity-dependent) K+ currents, brought about by decreased levels of neuromodulation from brainstem activating systems (36)(37)(38)(39) and/or by increased inhibition (40)(41)(42). Due to these mechanisms, cortical neurons tend to plunge into a silent, hyperpolarized state, lasting few hundred milliseconds, after an initial activation (10).…”

Section: Discussionmentioning

confidence: 99%

Local sleep-like cortical reactivity in the awake brain after focal injury

Sarasso

D’Ambrosio

Fecchio

et al. 2019

Preprint

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One Sentence Summary: Focal cortical injuries are associated with local intrusion of sleep-like dynamics over the perilesional areas which disrupt local signal complexity and coexist with typical wakefulness cortical reactivity patterns within the same brain. AbstractThe functional consequences of brain injury are known to depend on neuronal alterations extending beyond the area of structural damage. Although a lateralized EEG slowing over the injured hemisphere was known since the early days of clinical neurophysiology, its electrophysiological mechanisms were not systematically investigated. In parallel, basic sleep research has thoroughly characterized the neuronal events underlying EEG slow waves in physiological conditions. These EEG events reflect brief interruptions of neuronal firing (OFF-periods) that can occur locally and have prominent consequences on network and behavioral functions. Notably, the EEG slow waves observed following focal brain injury have been never explicitly connected to local sleep-like neuronal events. In previous works, probing cortical circuits with transcranial magnetic stimulation coupled with EEG (TMS/EEG) proved as an effective way to reveal the tendency of cortical circuits to transiently plunge into silent OFF-periods. Here, using this approach, we show that the intact cortex surrounding focal brain injuries engages locally in pathological sleep-like dynamics. Specifically, we employed TMS/EEG in a cohort of thirty conscious awake patients with chronic focal and multifocal brain injuries of various etiologies. TMS systematically evoked prominent slow waves associated with sleep-like OFF-periods in the area surrounding focal cortico-subcortical lesions. These events were associated with a local disruption of signal complexity and were absent when stimulating the contralateral hemisphere. Perilesional sleep-like OFF-periods may represent a valid read-out of the electrophysiological state of discrete cortical circuits following brain injury as well as a potential target of interventions aimed at fostering functional recovery.

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Section: Discussionmentioning

confidence: 99%

Local sleep-like cortical reactivity in the awake brain after focal injury

Sarasso

D’Ambrosio

Fecchio

et al. 2019

Preprint

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“…In persistent state, which can occur during but is not limited to awake periods, neurons are rather depolarized, sparsely active, leading to temporally dynamic, modality specific, network configurations 18 . In contrast to the persistent state, stands the bimodal activity pattern of slow oscillations, or slow wave state which has been extensively described 5,11,[19][20][21][22][23][24][25] , but only most recently in the framework of BOLD fMRI 11,26,27 . The corresponding low-frequency component ranges at 0.2-1 Hz, reflecting alternating activity patterns: active ("up") periods in which cells are depolarized and fire action potentials in temporally restricted periods, and silence ("down") periods with rather hyperpolarized membrane potentials and an almost complete absence of neuronal activity 28,29 .…”

Section: Introductionmentioning

confidence: 99%

Brain states govern the spatio-temporal dynamics of resting state functional connectivity

Aedo-Jury

Schwalm

Hamzehpour

et al. 2019

Preprint

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Previously, using simultaneous task-free fMRI and optic-fiber-based neuronal calcium recordings in the anesthetized rat, we identified BOLD responses directly related to slow calcium waves, revealing a cortex-wide and spatially organized BOLD correlate (Schwalm et al. 2017). Here, with these bimodal recordings, we reveal two distinct brain states: persistent state, in which compartmentalized network activity was observed, including defined subsets such as the default mode network; and slow wave state, dominated by a cortex-wide component, suggesting a strong functional coupling of brain activity. In slow wave state we find a correlation between slow wave events and the strength of functional connectivity. These findings suggest that indeed down-up transitions of neuronal excitability drive cortex-wide functional connectivity. This study provides strong evidence that previously reported changes in functional connectivity are highly dependent on the brain's current state and directly linked with cortical excitability and slow waves generation.

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“…53 Optogenetics 54,55 has emerged as an alternative to controlling brain waves with electromagnetic fields: photocontrolling the release of ACh, which strongly modulates the transitions between different brain states, 9,12 is possible by overexpressing photosensitive proteins in cholinergic neurons of mice neocortex. 10,56,57 However, genetic manipulation is required in this approach, and our light-dependent cholinergic muscarinic ligand is so far the only way to directly photomodulate cholinergic pathways in intact tissue. We first studied the effect of the superagonist Iperoxo 37 on isolated cortical slices ( Fig.…”

Section: Discussionmentioning

confidence: 99%

“…65 Compared to the local and often inhomogeneous expression patterns achieved with viral injections of optogenetic constructs, diffusible small molecules like PAI can be in principle applied to larger brain regions to control neuronal oscillations. 57 Thus, remote control of brain waves based on the photopharmacological manipulation of endogenous muscarinic receptors may reveal the complex 3D molecular signalling underlying brain states and their transitions, in order to link them with cognition and behavior in a diversity of wildtype organisms.…”

Section: Discussionmentioning

confidence: 99%

Control of brain state transitions with light

Almudena

Riefolo

Matera

et al. 2019

Preprint

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Human behavior is driven by specific neuronal activity and can be directly associated to characteristic brain states. The oscillatory activity of neurons contains information about the mental state of an individual, and the transition between different brain states is controlled by the neuromodulatory action of acetylcholine on nicotinic and muscarinic receptors. Manipulating brain waves bears high therapeutic interest in several neurological disorders, and can be achieved by transcranial direct current and magnetic stimulation techniques, and by optogenetics, although the clinical translation of the latter is hampered by the need of gene therapy. Here, we directly modulate brain waves with light using a photoswitchable muscarinic agonist. Synchronous slow wave activity can be disrupted in isolated cortical slices and in anesthetized mice. These results open the way to study the spatiotemporal distribution and the pharmacology of brain states, their transitions, and their links to cognition and behavior, in a diversity of wildtype organisms.

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An inhibitory gate for state transition in cortex

Cited by 100 publications

References 77 publications

Local sleep-like cortical reactivity in the awake brain after focal injury

Local sleep-like cortical reactivity in the awake brain after focal injury

Brain states govern the spatio-temporal dynamics of resting state functional connectivity

Control of brain state transitions with light

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