A prefrontal–temporal network underlying state changes between Stimulus-Driven and Stimulus-Independent Cognition / Un réseau temporo-frontal soutenant des états cognitifs indépendant des stimulus ou induite par les stimulus

Ossandon Valdes, Tomas

14 December 2010

Le cerveau présente des fluctuations de son activité qui reflètent différents niveaux d’engagement avec le monde extérieur. Le traitement des stimuli externes n’est pas seulement associé avec une augmentation du métabolisme cérébrale, mais également avec une désactivation importante dans un ensemble des structures spécifiques connus sous le nom de ‘Default-Mode Network’ (DMN, réseau par défaut). Le rôle du DMN reste énigmatique en partie parce que ses corrélats électrophysiologiques et sa dynamique temporelle sont encore mal compris. En utilisant des enregistrements éléctrophysiologiques intracrânien chez le patient épileptique, nous démontrons que la population neuronale de ce réseau montre des suppressions de l’activité gamma (60-140 Hz). Plus important, nous montrons de quelle manière le profil temporale (en millisecondes) et l’amplitude de cette désactivation sont étroitement corrélés avec la difficulté de la tâche et la performance individuelle. Les résultats mettent également en évidence que pendant une tâche attentionnelle, une activation soutenue dans le temps de la bande gamma est présente dans un large réseau, alors que des activations transitoires sont spécifiques aux régions temporale et occipitale. Nos résultats révèlent ainsi un rôle essentiel des mécanismes d’activation et de désactivation des oscillations large bande gamma dans l’exécution d’un comportement orienté vers un but. / The brain displays moment-to-moment activity fluctuations that reflect various levels of engagement with the outside world. Processing external stimuli is not only associated with increased brain metabolism but also with prominent deactivation in specific structures, collectively known as the default-mode network (DMN). The role of the DMN remains enigmatic partly because its electrophysiological correlates and temporal dynamics are still poorly understood. Using unprecedented wide-spread depth recordings in epileptic patients, undergoing intracranial EEG during pre-surgical evaluation, we reveal that DMN neural populations display task-related suppressions of gamma (60-140 Hz) power and, critically, we show how millisecond temporal profile and amplitude of gamma deactivation tightly correlate with task demands and subject performance. The results show also that during an attentional task, sustained activations in the gamma band power are presented across large cortical networks, while transient activations are mostly specific to occipital and temporal regions. Our findings reveal a pivotal role for broadband gamma modulations in the interplay between activation and deactivation networks mediating efficient goal-directed behavior

Electro-encephalogramme intracrânien

Oscillation Gamma

Désactivation gamma

Epilepsie

Attention

Recherche visuelle

Default-mode network

Gamma-band activity

Gamma-band suppression

Goal-directed behavior

Attention

Visuel search

Epilepsy

612.8

On the link between saccadic adaptation and visuospatial attention / Adaptation oculomotrice comme outils d'étude de l'attention spatiale

Nicolas, Judith

13 March 2019

L’attention et l’Adaptation Saccadique (AS) sont des composants essentiels de la perception visuelle, le premier renforce le traitement sensoriel des items sélectionnés, le second maintient la précision des mouvements des yeux vers ceux-ci. Ils partagent aussi une dichotomie : les saccades volontaires et l’orientation endogène de l’attention suivent nos buts internes tandis que les saccades réactives et l’orientation exogène répondent aux changements soudains dans l’espace visuel. Leurs substrats neuronaux se superposent en partie. Enfin, chacun impacte l’autre au niveau comportemental. Ce travail de doctorat étudie l’hypothèse d’un couplage fonctionnel entre attention et AS.Toutes nos études chez l’humain sain reposent sur la mesure des performances attentionnelles avant et après l’exposition à l’AS (ou contrôle). Dans la première nous avons exploré les bases neurophysiologiques du couplage réactif/exogène en magnétoencéphalographie. Dans la suivante nous avons comparé l’orientation exogène mesurée par un paradigme de Posner avant et après AS réactive. La dernière, basée sur le même modèle, explorait la modalité volontaire/endogène. Nos résultats montrent que l’AS augmente l’activité oscillatoire gamma et renforce l’orientation de l’attention spatiale. Nous proposons que le couplage repose sur la co-activation de populations neuronales par la plasticité oculomotrice et l’attention au niveau du Cortex Pariétal Postérieur (CPP). Cette activation émerge initialement d’un double effet du cervelet qui inhibe le CPP gauche et active le CPP droit. Cet effet augmente la dominance hémisphérique droite et le biais attentionnel vers la gauche. Notre travail ouvre des perspectives de rééducation des déficits visuo-attentionels / Attention and Saccadic Adaptation (SA) are critical components of visual perception, the former enhancing sensory processing of selected objects, the latter maintaining the eye movements accuracy towards them. Also, a similar dichotomy could be applied to both: voluntary saccades and endogenous attentional shifts follow internal goals while reactive saccades and exogenous shifts are elicited by sudden changes in the environment. Further, their neural substrates partially overlap and they impact each other behaviorally. This PhD work investigates the hypothesis of a functional coupling linking attention and SA in healthy humans. Our experimental contributions all rely on the measurement of attentional performances before and after an exposure to SA (or control). In the first study, we recorded brain magnetic fields to investigate neurophysiological bases of the reactive/exogenous coupling. In the second study, we compared exogenous orienting measured in a Posner-like paradigm before and after reactive SA. Finally, using the same design, the third experiment investigated the voluntary/endogenous modality. We found that SA increased gamma band activity and boosted the orienting of spatial attention. We thus propose that this functional coupling relies on neuronal populations co-activated by both oculomotor plasticity and attention in the Posterior Parietal Cortex (PPC). The initial activation would emerge from a dual effect of the cerebellum inhibiting the left PPC and activating the right PPC. This effect would increase the right hemispheric dominance and the leftward attentional bias. This work opens new perspectives for the rehabilitation of visuoattentional deficits

Plasticité oculomotrice

Attention Visuo-spatiale

Saccades

Couplage fonctionnel

Activité oscillatoire Gamma

Oculomotor plasticity

Visuo-spatial attention

Saccades

Functional coupling

Gamma band activity

570

A prefrontal-temporal network underlying state changes between Stimulus-Driven and Stimulus-Independent Cognition

Ossandon Valdes, Tomas

14 December 2010

The brain displays moment-to-moment activity fluctuations that reflect various levels of engagement with the outside world. Processing external stimuli is not only associated with increased brain metabolism but also with prominent deactivation in specific structures, collectively known as the default-mode network (DMN). The role of the DMN remains enigmatic partly because its electrophysiological correlates and temporal dynamics are still poorly understood. Using unprecedented wide-spread depth recordings in epileptic patients, undergoing intracranial EEG during pre-surgical evaluation, we reveal that DMN neural populations display task-related suppressions of gamma (60-140 Hz) power and, critically, we show how millisecond temporal profile and amplitude of gamma deactivation tightly correlate with task demands and subject performance. The results show also that during an attentional task, sustained activations in the gamma band power are presented across large cortical networks, while transient activations are mostly specific to occipital and temporal regions. Our findings reveal a pivotal role for broadband gamma modulations in the interplay between activation and deactivation networks mediating efficient goal-directed behavior

Default-mode network

Gamma-band activity

Gamma-band suppression

Goal-directed behavior

Attention

Visuel search

Epilepsy

Low-level and high-level modulations of fixational saccades and high frequency oscillatory brain activity in a visual object classification task

Kosilo, Maciej, Würger, Sophie M., Craddock, Matt, Jennings, Ben J., Hunt, Amelia R., Martinovic, Jasna

01 August 2022

Until recently induced gamma-band activity (GBA) was considered a neural marker of cortical object representation. However, induced GBA in the electroencephalogram (EEG) is susceptible to artifacts caused by miniature fixational saccades. Recent studies have demonstrated that fixational saccades also reflect high-level representational processes. Do high-level as opposed to low-level factors influence fixational saccades? What is the effect of these factors on artifact-free GBA? To investigate this, we conducted separate eye tracking and EEG experiments using identical designs. Participants classified line drawings as objects or non-objects. To introduce low-level differences, contours were defined along different directions in cardinal color space: S-cone-isolating, intermediate isoluminant, or a full-color stimulus, the latter containing an additional achromatic component. Prior to the classification task, object discrimination thresholds were measured and stimuli were scaled to matching suprathreshold levels for each participant. In both experiments, behavioral performance was best for full-color stimuli and worst for S-cone isolating stimuli. Saccade rates 200–700 ms after stimulus onset were modulated independently by low and high-level factors, being higher for full-color stimuli than for S-cone isolating stimuli and higher for objects. Low-amplitude evoked GBA and total GBA were observed in very few conditions, showing that paradigms with isoluminant stimuli may not be ideal for eliciting such responses. We conclude that cortical loops involved in the processing of objects are preferentially excited by stimuli that contain achromatic information. Their activation can lead to relatively early exploratory eye movements even for foveally-presented stimuli.

info:eu-repo/classification/ddc/150

ddc:150