Areas V1 and V2 show microsaccade-related 3-4-Hz covariation in gamma power and frequency

Autor: P De Weerd, Pascal Fries, Conrado A. Bosman, Mark Roberts, Eric Lowet
Přispěvatelé: Cognitive and Systems Neuroscience (SILS, FNWI), RS: FPN CN 3, Perception, RS: FPN MaCSBio
Jazyk: angličtina
Rok vydání: 2016
Předmět:
0301 basic medicine
Male
MACAQUE MONKEY
gamma-band response
Local field potential
Macaque
Synchronization (alternating current)
0302 clinical medicine
Neural Pathways
Gamma Rhythm
Cortical Synchronization
Theta Rhythm
Visual Cortex
biology
General Neuroscience
120 000 Neuronal Coherence
160 000 Neuronal Oscillations
Signal Processing
Computer-Assisted
saccade
PRIMARY VISUAL-CORTEX
medicine.anatomical_structure
Saccade
THETA
Microsaccade
monkey
Psychology
Biophysics
BAND SYNCHRONIZATION
BRAIN SIGNALS
NEURONAL OSCILLATIONS
150 000 MR Techniques in Brain Function
03 medical and health sciences
biology.animal
medicine
Saccades
COHERENCE
Coherence (signal processing)
Animals
ATTENTION
electrophysiology
Macaca mulatta
Electrophysiology
030104 developmental biology
Visual cortex
visual system
ALPHA-ACTIVITY
EYE-MOVEMENTS
Neuroscience
030217 neurology & neurosurgery
120 013 Primate Research Maastricht
Photic Stimulation
Zdroj: European Journal of Neuroscience
Europe PubMed Central
European Journal of Neuroscience, 43(10), 1286-1296. Wiley-Blackwell
European Journal of Neuroscience, 43(10), 1286-1296. Wiley
ISSN: 0953-816X
Popis: Neuronal gamma-band synchronization (25-90 Hz) in visual cortex appears sustained and stable during prolonged visual stimulation when investigated with conventional averages across trials. Yet, recent studies in macaque visual cortex have used single-trial analyses to show that both power and frequency of gamma oscillations exhibit substantial moment-by-moment variation. This has raised the question whether these apparently random variations might limit the functional role of gamma-band synchronization for neural processing. Here, we studied the moment-by-moment variation of gamma oscillation power and frequency, as well as inter-areal gamma synchronization by simultaneously recording local field potentials in V1 and V2 of two macaque monkeys. We additionally analyzed electrocorticographic (ECoG) V1 data from a third monkey. Our analyses confirm that gamma-band synchronization is not stationary and sustained but undergoes moment-by-moment variations in power and frequency. However, those variations are neither random and nor a possible obstacle to neural communication. Instead, the gamma power and frequency variations are highly structured, shared between areas, and shaped by a microsaccade-related 3-4 Hz theta rhythm. Our findings provide experimental support for the suggestion that cross-frequency coupling might structure and facilitate the information flow between brain regions. This article is protected by copyright. All rights reserved.
Databáze: OpenAIRE
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