State-Dependent Cortical Unit Activity Reflects Dynamic Brain State Transitions in Anesthesia

Lee, Heonsoo; Wang, Shiyong; Hudetz, Anthony G.

doi:10.1523/jneurosci.0601-20.2020

Cited by 25 publications

(19 citation statements)

References 67 publications

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“…Our previous study with the same data discovered that, during desflurane anesthesia, most frequently at a 6% concentration, spontaneous spike activity was occasionally desynchronous while showing a low firing rate (Lee et al, 2020). This unexpected, paradoxical desynchronized brain state has not been reported before and contends with the generally presumed dosedependent effect of anesthesia.…”

Section: Anesthesia Experimentssupporting

confidence: 57%

“…The study was approved by the Institutional Animal Care and Use Committee in accordance with the Guide for the Care and Use of Laboratory Animals of the Governing Board of the National Research Council (National Academy Press, Washington, DC, 2011). The experimental data used in this study were previously analyzed and published in a different context (Lee et al, 2020(Lee et al, , 2021. A multi-electrode array consisting of 64-contact silicon probes (shank length 2 mm, width 28-60 µm, probe thickness 15 µm, shank spacing 200 µm, row separation 100 µm, contact size 413 µm 2 ; custom design 8 × 8_edge_2 mm 100_200_413; Neuronexus Technologies, Ann Arbor, MI, United States) was chronically implanted in the primary visual cortex of each animal (eight adult male Long-Evans rats).…”

Section: Anesthesia Experimentsmentioning

confidence: 99%

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Network Model With Reduced Metabolic Rate Predicts Spatial Synchrony of Neuronal Activity

Joo

Lee

Wang

et al. 2021

Front. Comput. Neurosci.

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In a cerebral hypometabolic state, cortical neurons exhibit slow synchronous oscillatory activity with sparse firing. How such a synchronization spatially organizes as the cerebral metabolic rate decreases have not been systemically investigated. We developed a network model of leaky integrate-and-fire neurons with an additional dependency on ATP dynamics. Neurons were scattered in a 2D space, and their population activity patterns at varying ATP levels were simulated. The model predicted a decrease in firing activity as the ATP production rate was lowered. Under hypometabolic conditions, an oscillatory firing pattern, that is, an ON-OFF cycle arose through a failure of sustainable firing due to reduced excitatory positive feedback and rebound firing after the slow recovery of ATP concentration. The firing rate oscillation of distant neurons developed at first asynchronously that changed into burst suppression and global synchronization as ATP production further decreased. These changes resembled the experimental data obtained from anesthetized rats, as an example of a metabolically suppressed brain. Together, this study substantiates a novel biophysical mechanism of neuronal network synchronization under limited energy supply conditions.

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Section: Anesthesia Experimentssupporting

confidence: 57%

Section: Anesthesia Experimentsmentioning

confidence: 99%

Network Model With Reduced Metabolic Rate Predicts Spatial Synchrony of Neuronal Activity

Joo

Lee

Wang

et al. 2021

Front. Comput. Neurosci.

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“…Working under anesthesia allowed us to investigate well-controlled and repeated robust activation of whiskers. Nevertheless, both the anesthesia and the circumstance that the rats were not actively performing the task may have influenced the activity and synchronization ( Constantinople and Bruno, 2011 ; Lissek et al, 2016 ; Lee et al, 2020 ). Future experiments are required to corroborate our findings in awake behaving rodents.…”

Section: Discussionmentioning

confidence: 99%

State-Dependent Synchrony and Functional Connectivity in the Primary and Secondary Whisker Somatosensory Cortices

Khateb

Schiller

2021

Front. Syst. Neurosci.

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Synchronized activity plays an important role in sensory coding and memory and is a hallmark of functional network connectivity. However, the effect of sensory activation on synchronization and cortical functional connectivity is largely unknown. In this study, we investigated the effect of whisker activation on synchronization and functional connectivity of the primary (wS1) and secondary (wS2) whisker somatosensory cortices at the single-cell level. The results showed that during the spontaneous pre-stimulus state, neurons tended to be functionally connected with nearby neurons which shared similar tuning characteristics. Whisker activation using either ramp-and-hold stimulation or artificial whisking against sandpaper has significantly reduced the average overall pairwise synchronization and functional connectivity within the wS1 barrel and wS2 cortices. Whisker stimulation disconnected approximately a third of neuronal pairs that were functionally connected during the unstimulated state. Nearby neurons with congruent tuning properties were more likely to remain functionally connected during whisker activation. The findings of this study indicated that cortical somatosensory networks are organized in non-random small world networks composed of neurons sharing relatively similar tuning properties. Sensory whisker activation intensifies these properties and further subdivides the cortical network into smaller more functionally uniform subnetworks, which possibly serve to increase the computational capacity of the network.

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“…In the last two decades, several studies have performed recordings of the neuronal activity during various depths of either natural sleep or anesthesia, as well as during the process of awakening (Barttfeld et al, 2015;Bettinardi et al, 2015;Dasilva et al, 2021;Fischer et al, 2018;Hahn et al, 2012;Hudetz et al, 2015;Hudson et al, 2014;Lee et al, 2020;Li and Mashour, 2019;Liu et al, 2013;Schartner et al, 2017;Tort-Colet et al, 2019). Results from single -or a small number of simultaneously recorded -areas (including primary visual (Hudetz et al, 2015;Lee et al, 2020;Vizuete et al, 2012), cingulate (Hudson et al, 2014), retrospenial (Hudson et al, 2014), temporo-parieto-occipital (Fischer et al, 2018) cortices and the thalamus (Hudson et al, 2014)), as well as from the whole cortex (Barttfeld et al, 2015;Bettinardi et al, 2015;Dasilva et al, 2021;Grandjean et al, 2014;Li and Mashour, 2019;Liu et al, 2013;Schartner et al, 2017), showed that during the emergence from deep anesthesia (NREM sleep) the network activity increases its integration and complexity dynamical properties, possibly starting to wander among so-called micro-states (Brodbeck et al, 2012;Hudson et al, 2014;Lee et al, 2020;Liu et al, 2013). These studies strengthened the hypothesis that the anesthetized (sleeping) brain is not confined in a static dynamical state, but actually explores a more complex landscape, eventually operating a rather progressive state transition to wakefulness (Barttfeld et al, 2015;Dasilva et al, 2021;Li and Mashour, 2019;…”

Section: Introductionmentioning

confidence: 99%

“…These include cortico-thalamic loops (Crunelli et al, 2015;Crunelli and Hughes, 2010;Destexhe and Sejnowski, 2003;Grenier et al, 1998;Merica and Fortune, 2004;Sheroziya and Timofeev, 2014;Steriade et al, 1993b) and the balance between local dynamical features and global connectivity of the brain network shaping its integration and segregation capabilities (Barttfeld et al, 2015;Deco et al, 2015Deco et al, , 2014Mohajerani et al, 2013). At the cellular and local cortical assembly level, various experimental and modelling studies pointed at two main players playing a critical role in the process of awakening: firing adaptation of excitatory cortical neurons, and neuronal excitability (Compte et al, 2003;Lee et al, 2020;Levenstein et al, 2019;Mattia and Sanchez-Vives, 2012;Muller and Destexhe, 2012;Sanchez-Vives and McCormick, 2000). However, the cellular and network mechanisms underlying this state transitions remain to be conclusively elucidated.…”

Section: Introductionmentioning

confidence: 99%

Slow waves form expanding, memory-rich mesostates steered by local excitability in fading anesthesia

Pazienti

Galluzzi

Dasilva

et al. 2021

Preprint

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During sleep and anesthesia, large groups of neurons throughout the entire cortex activate rhythmically producing wavefronts of activity referred to as slow-wave activity (SWA). In the arousal process, the brain restores its integrative and complex activity. The network mechanisms underlying this global state transition remain however to be elucidated. Here we investigated the network features shaping the SWA under fading anesthesia. Using electrocorticographical recordings of wide cortical areas of the mouse brain, we developed a quantitative measure of the anesthesia level based on slow-wave frequency and complexity. At deep anesthesia, we document a stringent alternation of posterior-anterior-posterior modes of propagation. With fading anesthesia, SWA evolves to produce a plethora of metastable spatiotemporal patterns. A network model of spiking neurons reproduced the data using short-range connectivity, subcortical input and a local activity-dependent adaptation. The emergence from deep anesthesia does not require modifying the connectivity, but small changes in the local excitability of cortical cell assemblies, further supporting the hypothesis of a tight bound between scales in the brain.

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State-Dependent Cortical Unit Activity Reflects Dynamic Brain State Transitions in Anesthesia

Cited by 25 publications

References 67 publications

Network Model With Reduced Metabolic Rate Predicts Spatial Synchrony of Neuronal Activity

Network Model With Reduced Metabolic Rate Predicts Spatial Synchrony of Neuronal Activity

State-Dependent Synchrony and Functional Connectivity in the Primary and Secondary Whisker Somatosensory Cortices

Slow waves form expanding, memory-rich mesostates steered by local excitability in fading anesthesia

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