Noradrenaline Modulates Visual Perception and Late Visually Evoked Activity

Gelbard-Sagiv, Hagar; Magidov, Efrat; Sharon, Haggai; Hendler, Talma; Nir, Yuval

doi:10.1016/j.cub.2018.05.051

Cited by 102 publications

(112 citation statements)

References 80 publications

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“…Thus, a functional disconnection between primary sensory and association cortex may be a general property of LOC not only due to anesthesia, as demonstrated also by direct perturbation of cortical activity with transcranial magnetic stimulation (TMS) (52)(53)(54). In addition, our results join findings from other lines of research showing that when sensory stimuli are not perceived, activity in primary sensory regions is largely preserved whereas activity in association cortices is attenuated (55)(56)(57)(58).…”

Section: Studies In Natural Sleep Demonstrate a Similar Distinction Bsupporting

confidence: 82%

Anesthesia-induced loss of consciousness disrupts auditory responses beyond primary cortex

Krom

Marmelshtein

Gelbard-Sagiv

et al. 2018

Preprint

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AbstractDespite its ubiquitous use in medicine, and extensive knowledge of its molecular and cellular effects, how anesthesia induces loss of consciousness (LOC) and affects sensory processing remains poorly understood. Specifically, it is unclear whether anesthesia primarily disrupts thalamocortical relay or intercortical signaling. Here we recorded intracranial EEG (iEEG), local field potentials (LFPs), and single-unit activity in patients during wakefulness and light anesthesia. Propofol infusion was gradually increased while auditory stimuli were presented and patients responded to a target stimulus until they became unresponsive. We found widespread iEEG responses in association cortices during wakefulness, which were attenuated and restricted to auditory regions upon LOC. Neuronal spiking and LFP responses in primary auditory cortex (PAC) persisted after LOC, while responses in higher-order auditory regions were variable, with neuronal spiking largely attenuated. Gamma power induced by word stimuli increased after LOC while its frequency profile slowed, thus differing from local spiking activity. In summary, anesthesia-induced LOC disrupts auditory processing in association cortices while relatively sparing responses in PAC, opening new avenues for future research into mechanisms of LOC and the design of anesthetic monitoring devices.

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Section: Studies In Natural Sleep Demonstrate a Similar Distinction Bsupporting

confidence: 82%

Anesthesia-induced loss of consciousness disrupts auditory responses beyond primary cortex

Krom

Marmelshtein

Gelbard-Sagiv

et al. 2018

Preprint

Self Cite

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“…The prevailing interpretation emerging from these studies is that neuromodulators gate cortical plasticity by enhancing sensory perception, and by promoting patterns of cortical activity suitable for plasticity induction via controlling network excitability. This is consistent with a wealth of studies documenting that neuromodulators improve perception in vivo (see Gelbard-Sagiv et al, 2018;Jacob and Nienborg, 2018;McBurney-Lin et al, 2019;Nadim and Bucher, 2014 for reviews) also affect cellular intrinsic excitability and synaptic inhibition to gate the induction of Hebbian plasticity in vitro (see Brzosko et al, 2019;Palacios-Filardo and Mellor, 2019;Pawlak et al, 2010 for reviews). We propose an additional and different mode of action: direct control of the expression, not the induction, of Hebbian plasticity via the Gq/Gs based pull-push metaplasticity mechanism that we previously demonstrated in vitro, in slices.…”

Section: Discussionsupporting

confidence: 80%

Pull-Push Neuromodulation of Cortical Plasticity Enables Rapid Bi-Directional Shifts in Ocular Dominance

Hong

Huang

Severín

et al. 2019

Preprint

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Neuromodulatory systems are essential for remodeling glutamatergic connectivity during experience-dependent cortical plasticity. This permissive/enabling function of neuromodulators has been associated with their capacity to facilitate the induction of Hebbian forms of long-term potentiation (LTP) and depression (LTD) by affecting cellular and network excitability. In vitro studies indicate that neuromodulators can also affect the expression of Hebbian plasticity in a pull-push manner: receptors coupled to the G-protein Gs promote the expression of LTP at the expense of LTD, and Gq-coupled receptors promote LTD at the expense of LTD. Here we show that the pull-push mechanism can be recruited in vivo by pairing brief monocular stimulation with pharmacological or chemogenetical activation of Gs-or Gq-coupled receptors to respectively enhance or reduce visual cortical responses. These changes were stable, can be induced in adults after the termination of the critical period for juvenile ocular dominance plasticity, and can rescue deficits induced by prolonged monocular deprivation.

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“…In human patients, invasive VNS induces markers of brain arousal that are consistent with LC-NE activity such as pupil dilation (Desbeaumes Jodoin et al, 2015) that is tightly linked with LC-NE activity (Joshi et al, 2016;Reimer et al, 2016;Gelbard-Sagiv et al, 2018;Hayat et al, 2020). VNS may also lead to EEG desynchronization, but effects are subtler than pupil dilation, at least with the clinical parameters that typically employ long (30-60s) stimulation epochs.…”

Section: Introductionmentioning

confidence: 99%

Transcutaneous vagus nerve stimulation in humans induces pupil dilation and attenuates alpha oscillations

Sharon

Fahoum

Nir

2020

Preprint

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Vagus nerve stimulation (VNS) is widely used to treat drug-resistant epilepsy and depression. While the precise mechanisms mediating its long-term therapeutic effects are not fully resolved, they likely involve Locus Coeruleus (LC) stimulation via the nucleus of the solitary tract (NTS) that receives afferent vagal inputs. In rats, VNS elevates LC firing and forebrain noradrenaline (NE) levels, whereas LC lesions suppress VNS therapeutic efficacy. Non-invasive transcutaneous VNS (tVNS) employs electrical stimulation targeting the auricular branch of the vagus nerve at the Cymba Conchae of the ear, but it remains unclear to what extent tVNS mimics VNS. Here, we investigated the short-term effects of tVNS in healthy human male volunteers (n=24) using high-density EEG and pupillometry during visual fixation at rest, comparing short (3.4s) trials of tVNS to sham electrical stimulation at the earlobe (far from the vagus nerve branch) to control for somatosensory stimulation. Although tVNS and sham stimulation did not differ in subjective intensity ratings, tVNS led to robust pupil dilation (peaking 4-5s after trial onset) that was significantly higher than following sham stimulation. We further quantified how tVNS modulates idle occipital alpha (8-13Hz) activity, identified in each participant using parallel factor analysis. We found that tVNS attenuates alpha oscillations to a greater extent than does sham stimulation. Thus, tVNS reliably induces pupillary and EEG markers of arousal beyond the effects of somatosensory stimulation, supporting the hypothesis that it elevates noradrenaline and acetylcholine signaling and mimics invasive VNS.

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Noradrenaline Modulates Visual Perception and Late Visually Evoked Activity

Cited by 102 publications

References 80 publications

Anesthesia-induced loss of consciousness disrupts auditory responses beyond primary cortex

Anesthesia-induced loss of consciousness disrupts auditory responses beyond primary cortex

Pull-Push Neuromodulation of Cortical Plasticity Enables Rapid Bi-Directional Shifts in Ocular Dominance

Transcutaneous vagus nerve stimulation in humans induces pupil dilation and attenuates alpha oscillations

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