Binding Symbols and Sounds: Evidence from Event-Related Oscillatory Gamma- Band Activity

Widmann, Andreas, Gruber, Thomas, Kujala, Teija, Tervaniemi, Mari, Schröger, Erich

16 January 2019

The present study intended to examine the neural basis of audiovisual integration, hypothetically achieved by synchronized gamma-band oscillations (30--80 Hz) that have been suggested to integrate stimulus features and top--down information. To that end, we studied the impact of visual symbolic information on early auditory sensory processing of upcoming sounds. In particular, we used a symbol-to-sound--matching paradigm in which simple score-like patterns predict corresponding sound patterns. Occasionally, a single sound is incongruent with the corresponding element of the visual pattern. In response to expected sounds congruent with the corresponding visual symbol, a power increase of phase-locked (evoked) activity in the 40-Hz band was observed peaking 42-ms poststimulus onset. Thus, for the first time, we demonstrated that the comparison process between a neural model, the expectation, and the current sensory input is implemented at very early levels of auditory processing. Subsequently, expected congruent sounds elicited a broadband power increase of non--phase-locked (induced)activity peaking 152-ms poststimulus onset, which might reflect the formation of a unitary event representation including both visual and auditory aspects of the stimulation. Gamma-band responses were not present for unexpected incongruent sounds. A model explaining the anticipatory activation of cortical auditory representations and the match of experience against expectation is presented

info:eu-repo/classification/ddc/610

ddc:610

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

Study of neural correlates of attention in mice with spectro-spatio-temporal approaches / En studie om neurala korrelater av uppmärksamhet hos möss med spektro-spatio-temporala tillvägagångssätt

Ortiz, Cantin

January 2018

While signatures of attention can be observed in widespread areas within and outside of cortex, the control of attention is thought to be regulated by higher cognitive brain areas, such as the prefrontal cortex. In their recent study on mice Kim et al. could show that successful allocation of attention is characterized by increased spiking of a specific type of inhibitory interneurons, the parvalbumin neurons, and higher oscillatory activity in the gamma band in the local prefrontal network. It was recently demonstrated that encoding of working memory in prefrontal areas is linked to bursts of gamma oscillations, a discontinuous network process characterized by short periods of intense power in the gamma band. The relationship between attention and working memory is unclear, and it is possible that these two cognitive processes share encoding principles. To address this gap, the electrophysiological data collected in the Carlén Lab have been analyzed with advanced spatio-temporal approaches. In particular, we have analyzed bursting gamma activity in medial prefrontal cortex during attentional processing and investigated the similarities to gamma bursting observed during working memory. Gamma-band bursts during attention were reliably detected with several methods. We have characterized several features of the bursts, including the occurrence, duration and amplitude. The neuronal firing rates during and outside of bursts have also been computed. We investigated the correlation between different criteria characterizing the gamma burst and successful vs failed allocation of attention. Control data were generated to discuss the obtained results. The aim of the study was to explore the hypothesis that the medial prefrontal cortex encodes attention trough gamma bursts, which could reveal some similarities and differences in coding of central cognitive processes. No clear difference was found in the characterization between successful and failed allocation of attention. In addition, results were very similar in control set and original data. No underlying mechanism could be identified from this analysis. Therefore, as the bursts occurring in the gamma band in the prefrontal cortex (PFC) were not discriminative with respect to the different tested conditions, they do not seem to encode information related to attention. / Även fast flera olika hjärnområdens aktivitet kan korreleras med uppmärksamhet, anses kontrollen av uppmärksamhet regleras av högre kognitiva hjärnområden, såsom främre hjärnbarken. I en nyligen publicerad artikel studerade Kim et al. hjärnaktiviteten hos möss och kunde visa att en framgångsrik uppmärksamhet kännetecknas av en ökad aktivitet av en specifik typ av inhiberande nervceller, parvalbumin celler, och högre oscillerande aktivitet i gammafrekvens i främre hjärnbarkens lokala nätverk. Det har nyligen visats att kodning av arbetsminne i främre hjärnbarken är kopplat till utbrott av gamma-oscillationer, en diskontinuerlig nätverksprocess som kännetecknas av korta perioder av intensiva oscillationer av det lokala nätverket i gammafrekvens . Relationen mellan uppmärksamhet och arbetsminne är oklar, och det är möjligt att dessa två kognitiva processer delar kodningsprinciper. För att minska detta gap av kunskap har den elektrofysiologiska datan som samlats in i Carlén Lab analyserats med avancerade spatio-temporala tillvägagångssätt. I synnerhet har vi analyserat utbrott i gammaaktivitet i främre hjärnbarken under uppmärksamhet och undersökt likheterna med gamma- utbrott observerade under arbetsminne. Gamma-bandutbrott under uppmärksamhet påvisades på ett tillförlitligt sätt med flera metoder. Vi har karaktäriserat flera funktioner hos utbrotten, inklusive förekomsten, varaktigheten och amplituden. De enskilda cellernas aktivitet undersöktes även under och utanför utprotten av gamma-oscillationer. Vi undersökte sambandet mellan de olika kriterier som karakteriserar gamma-utbrott under framgångsrik mot misslyckad allokering av uppmärksamhet. Kontrolldata genererades för att diskutera de erhållna resultaten. Syftet med studien var att utforska hypotesen att den främre hjärnbarken kodar uppmärksamhet genom gamma-utbrott, vilket kan avslöja vissa likheter och skillnader i kodning av centrala kognitiva processer. Ingen klar skillnad hittades i karaktäriseringen mellan framgångsrik och misslyckad allokering av uppmärksamhet. Dessutom var resultaten mycket likartade i kontrolluppsättningen och den ursprungliga datan. Ingen underliggande mekanism kunde identifieras ur denna analys. Eftersom de utbrott som uppstod i gamma-bandet i främre hjärnbarken inte var unika med hänsyn till de olika testade förhållandena, tycks de därför inte koda information relaterad till uppmärksamhet.

gamma

bursts

neuroscience

attention

mice

LFP

gamma bursts

local field potential

phase randomization

cognition

cognitive process

modulation

spike

neuron

prefrontal cortex

PFC

pre-frontal

tetrode

filtering

Hilbert transform

recordings

oscillation

gamma band

Computer Sciences

Datavetenskap (datalogi)

Widerspiegelung der Sprachproduktion im Hochfrequenzbereich des EEG

Riewe, Dagmar

22 February 1999

In einer Pilotstudie sollten deutschsprachigen Probanden (n=28) in zwei Versuchsabschnitten kurze Sätze sprechen, die das Homonym "Leiter" im Sinne von "Steiggerät" bzw. "Teamchef" näher definieren. Das Homonym sollte am Satzanfang ohne Artikel genannt werden. Das Breitband-EEG (bis 2000 Hz, Zeitkonstante 1,5 s) wurde über F3, F4, C3 und C4 (Intern. 10-20-System) vor und kurz nach Sprachbeginn abgeleitet. Signalepochen des EEG- und Mikrophonsignals von 6 s Dauer wurden gespeichert. Off-line erfolgte die Auswertung der auf Sprachbeginn zentrierten und auf 1 Sekunde gekürzten EEG-Episoden. Es wurden vor Vokalisation motorische Bereitschaftspotentiale gefunden, die im gesamten Zeitbereich (750 ms prä- und 250 ms perireaktiv) wenig strukturiert sind und sich an den vier Ableitorten weder in ihrer Amplitude noch in ihrer Amplituden-Zeit-Struktur unterscheiden. Die Spektralanalyse der EEG-Signalstrecke zeigt unter beiden Versuchsbedingungen eine überproportional hohe Amplitude im [delta]-Band. Mit Hilfe der von Bartsch und Krüger entwickelten Subpotentialanalyse, die im Hochfrequenzbereich des EEG (10-400 Hz) dem "local field potential" ähnliche Phänomene nachweist, konnten in der Signalperiode des Bereitschaftspotentials positive und negative Subpotentiale ermittelt werden. Die Amplitude dieser Subpotentiale liegt zwischen 6 und 12[mycro]V. Der Zeitpunkt des Erscheinens der Subpotentiale wurde als Subpotentialevent (SPe) bezeichnet. Die SPe treten teils gruppiert und teils kohärent auf. Die Intervalle zwischen den SPe wurden histographisch aufgetragen, sie reichen vom 4 bis 15 ms. Auffallendstes Ergebnis war die unterschiedliche Struktur der SPe-Intervallhistogramme, die sich in den linksseitigen Ableitungen anders verhielten als in den rechtsseitigen. Möglicherweise sind diese Differenzen typisch für den eloquenten Unterschied. / During a pilot study, 28 german speeking subjects were supposed in two trial parts to speak in short sentences in order to define the german homonyme "Leiter" with the meaning "leader" respectively "manager". The homonyme should be used without any article at the beginning of the sentence. The EEG-activity (0-2000 Hz, time constant 1,5 sec) was recorded from F3, F4, C3 and C4 (international 10-20-system) before and after starting speech. Signalepochs of EEG-activity and microphone signals of 6 seconds were stored. The offline-evaluation was based on the centered and to the one second shortened EEG-episodes. Before staring speech there had been found a movement-related readines-potential (motor. Bereitschaftspotential), which had been less structured during the whole period of time (750ms pre- and 250 ms perireactive). Neither in their amplitude nor in their amplitude-time-structure distinctions were observed. The spectral analysis of EEG showed an overpropotional high amplitude in [delta]-band under both conditions of the trial. The subpotential-analysis developed by Bartsch and Krüger, which shows similar phenomenons as the "local field potentials" in the high frequency-EEG (10-400 Hz), could show positve and negative subpotentials during the period of the readiness-potential. The amplitudes of those subpotentials lay between 6 and 12[mycro]V. The point of time, when the subpotentials showed up, is called the subpotential-event (SPe). The SPe showed up partly in groups and partly coherent. The intervals between the SPe were put on histographically with a reach from 4 to 25 ms. The most striking result was the varying structure of the histography of the SPe-intervalls. The left-sided histography was conducted differently to the right-sided. May be that these distinctions are typical for the eloquent difference.

Sprachgenerierung

motorisches Bereitschaftschaftpotential

Subpotentialanalyse

speechproduction

event-related potentials

EEG "gamma-band" activity

subpotetial-analysis

610 Medizin und Gesundheit

33 Medizin

CP 4000

CP 6500

YG 2400

ddc:610