Thalamocortical excitability adjustments guide human perception under uncertainty

Kosciessa, Julian Q.; Lindenberger, Ulman; Garrett, Douglas D.

doi:10.1101/2020.06.22.165118

Cited by 8 publications

(9 citation statements)

References 194 publications

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“…We found this relationship of E/I and pupil-linked arousal in the majority of regions, thus suggesting a global and uniform effect. In sum, pupil-linked arousal may provide a window into yet another cortical circuit property, cortical E/I, relevant for cognitive computation (Cavanagh et al, 2020; Kosciessa et al, 2021; Lam et al, 2017; B. K. Murphy & Miller, 2003; Pettine et al, 2021; Pfeffer et al, 2020).…”

Section: Discussionmentioning

confidence: 99%

Coupling of pupil- and neuronal population dynamics reveals diverse influences of arousal on cortical processing

Pfeffer

Keitel

Kluger

et al. 2021

Preprint

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Fluctuations in arousal, controlled by subcortical neuromodulatory systems, continuously shape cortical state, with profound consequences for information processing. Yet, how arousal signals influence cortical population activity in detail has only been characterized for a few selected brain regions so far. Traditional accounts conceptualize arousal as a homogeneous modulator of neural population activity across the cerebral cortex. Recent insights, however, point to a higher specificity of arousal effects on different components of neural activity and across cortical regions. Here, we provide a comprehensive account of the relationships between fluctuations in arousal and neuronal population activity across the human brain. Exploiting the established link between pupil size and central arousal systems, we performed concurrent magnetoencephalographic (MEG) and pupillographic recordings in a large number of participants, pooled across three laboratories. We found a cascade of effects relative to the peak timing of spontaneous pupil dilations: Decreases in low-frequency (2-8 Hz) activity in temporal and lateral frontal cortex, followed by increased high-frequency (>64 Hz) activity in mid-frontal regions, followed by linear and non-linear relationships with intermediate frequency-range activity (8-32 Hz) in occipito-parietal regions. The non-linearity resembled an inverted U-shape whereby intermediate pupil sizes coincided with maximum 8-32 Hz activity. Pupil-linked arousal also coincided with widespread changes in the structure of the aperiodic component of cortical population activity, indicative of changes in the excitation-inhibition balance in underlying microcircuits. Our results provide a novel basis for studying the arousal modulation of cognitive computations in cortical circuits.

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Section: Discussionmentioning

confidence: 99%

Coupling of pupil- and neuronal population dynamics reveals diverse influences of arousal on cortical processing

Pfeffer

Keitel

Kluger

et al. 2021

Preprint

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“…Another possibility is that already subcortical sources – particularly in the thalamus – may play a role in modulating sensory excitability and hence shape the perceptual outcome (Kosciessa et al, 2020). Yet, our analyses of the thalamus-related P15 component did not support this notion.…”

Section: Discussionmentioning

confidence: 99%

Neural excitability and sensory input determine intensity perception with opposing directions in initial cortical responses

Stephani

Hodapp

Idaji

et al. 2020

Preprint

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Perception of sensory information is determined by stimulus features (e.g., intensity) and instantaneous neural states (e.g., excitability). Commonly, it is assumed that both are reflected similarly in evoked brain potentials, that is, higher evoked activity leads to a stronger percept of a stimulus. We tested this assumption in a somatosensory discrimination task in humans, simultaneously assessing (i) single-trial excitatory post-synaptic currents inferred from short-latency somatosensory evoked potentials (SEP), (ii) pre-stimulus alpha oscillations (8-13 Hz), and (iii) peripheral nerve measures. Fluctuations of neural excitability shaped the perceived stimulus intensity already during the very first cortical response (at ∼20 ms) yet demonstrating opposite neural signatures as compared to the effect of presented stimulus intensity. We reconcile this discrepancy via a common framework based on modulations of electro-chemical membrane gradients linking neural states and responses, which calls for reconsidering conventional interpretations of brain potential magnitudes in stimulus intensity encoding.

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“…Specifically, uncertainty about the stimulus features (e.g. orientations of lines in the image) was directly linked to neural variability in monkeys' visual area (Orbán et al, 2016) and human EEG (Kosciessa et al, 2021): wider inferred range of possible feature combinations in the input stimulus corresponded to wider distribution of neural responses. This could be applied to both within-and across-trial variability (Orbán et al, 2016).…”

Section: Introductionmentioning

confidence: 99%

Temporal variabilities provide additional category-related information in object category decoding: a systematic comparison of informative EEG features

Karimi-Rouzbahani

2020

Preprint

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Humans are remarkably efficent at recognizing objects. Understanding how the brain performs object recognition has been challenging. Our understanding has been advanced substantially in recent years with the development of multivariate pattern analysis or brain decoding methods. Most start-of-the-art decoding procedures, make use of the mean signal activation to extract object category information, which overlooks temporal variability in the signals. Here, we studied category-related information in 30 mathematically different features from the electroencephalography (EEG; the largest set ever) across three independent and highly-varied datasets using multi-variate pattern analyses. While the event-related potential (ERP) components of N1 and P2a were among the most informative features, the informative original signal samples and Wavelet coefficients, down-sampled through principal component analysis, outperformed them. Informative features showed more pronounced effects in the Theta frequency band, which has been shown to support feed-forward processing of visual information. Correlational analyses showed that the features which provided the most information about object categories, could predict participants’ performance (reaction time) more accurately than the less informative features. These results provide researchers with new avenues to study how the brain encodes object category information and how we can read out object category to study the temporal dynamics of the neural code.

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Thalamocortical excitability adjustments guide human perception under uncertainty

Cited by 8 publications

References 194 publications

Coupling of pupil- and neuronal population dynamics reveals diverse influences of arousal on cortical processing

Coupling of pupil- and neuronal population dynamics reveals diverse influences of arousal on cortical processing

Neural excitability and sensory input determine intensity perception with opposing directions in initial cortical responses

Temporal variabilities provide additional category-related information in object category decoding: a systematic comparison of informative EEG features

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