Single trial variability in neural activity during a working memory task reveals multiple distinct information processing sequences

•Traditional analysis assumes variability in brain activity represents noise.•We develop a method to cluster multiple trials of a stimulus dependent task.•We show that trials of the same task can be classified into three waveforms.•Variability arises from the presence of multiple ERP subtypes.•ERP s...

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Bibliographic Details
Published in:NeuroImage (Orlando, Fla.) Fla.), 2023-04, Vol.269, p.119895-119895, Article 119895
Main Authors: Nakuci, Johan, Covey, Thomas J., Shucard, Janet L., Shucard, David W., Muldoon, Sarah F.
Format: Article
Language:English
Subjects:
Accuracy
Brain Mapping
Buttons
Clustering
Cognition - physiology
Cognitive ability
Decision making
Decomposition
EEG
Electrodes
Electroencephalography
Electroencephalography - methods
Event-related potentials
Evoked Potentials - physiology
Humans
Information processing
Memory
Memory, Short-Term - physiology
Mental task performance
Neural networks
Short term memory
Single trial variability
Working memory
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Summary:•Traditional analysis assumes variability in brain activity represents noise.•We develop a method to cluster multiple trials of a stimulus dependent task.•We show that trials of the same task can be classified into three waveforms.•Variability arises from the presence of multiple ERP subtypes.•ERP subtypes can be linked to behavioral outcomes. Successful encoding, maintenance, and retrieval of information stored in working memory requires persistent coordination of activity among multiple brain regions. It is generally assumed that the pattern of such coordinated activity remains consistent for a given task. Thus, to separate this task-relevant signal from noise, multiple trials of the same task are completed, and the neural response is averaged across trials to generate an event-related potential (ERP). However, from trial to trial, the neuronal activity recorded with electroencephalogram (EEG) is actually spatially and temporally diverse, conflicting with the assumption of a single pattern of activity for a given task. Here, we show that variability in neuronal activity among single time-locked trials arises from the presence of multiple forms of stimulus dependent synchronized activity (i.e., distinct ERPs). We develop a data-driven classification method based on community detection to identify three discrete spatio-temporal clusters, or subtypes, of trials with different patterns of activation that are further associated with differences in decision-making processes. These results demonstrate that differences in the patterns of neural activity during working memory tasks represent fluctuations in the engagement of distinct brain networks and cognitive processes, suggesting that the brain can choose from multiple mechanisms to perform a given task.
ISSN:1053-8119
1095-9572
DOI:10.1016/j.neuroimage.2023.119895