From provocation to aggression: the neural network

In-vivo observations of neural processes during human aggressive behavior are difficult to obtain, limiting the number of studies in this area. To address this gap, the present study implemented a social reactive aggression paradigm in 29 healthy men, employing non-violent provocation in a two-playe...

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Bibliographic Details
Published in:BMC neuroscience 2017-10, Vol.18 (1), p.73-73, Article 73
Main Authors: Repple, Jonathan, Pawliczek, Christina M, Voss, Bianca, Siegel, Steven, Schneider, Frank, Kohn, Nils, Habel, Ute
Format: Article
Language:English
Subjects:
Aggression
Aggressive behavior
Aggressiveness
Brain mapping
Brain research
Circuits
Cortex (cingulate)
Decision making
Emotions
Functional magnetic resonance imaging
Health aspects
Human acts
Human behavior
Impulsivity
Medical imaging
Neural networks
Neurobiology
Neuroimaging
Neurosciences
Prefrontal cortex
PSAP
Questionnaires
Studies
TAP
Trends
Violence
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Summary:In-vivo observations of neural processes during human aggressive behavior are difficult to obtain, limiting the number of studies in this area. To address this gap, the present study implemented a social reactive aggression paradigm in 29 healthy men, employing non-violent provocation in a two-player game to elicit aggressive behavior in fMRI settings. Participants responded more aggressively after high provocation reflected in taking more money from their opponents. Comparing aggression trials after high provocation to those after low provocation revealed activations in neural circuits involved in aggression: the medial prefrontal cortex (mPFC), the orbitofrontal cortex (OFC), the dorsolateral prefrontal cortex (dlPFC), the anterior cingulate cortex (ACC), and the insula. In general, our findings indicate that aggressive behavior activates a complex, widespread brain network, reflecting a cortico-limbic interaction and overlapping with circuits underlying negative emotions and conflicting decision-making. Brain activation during provocation in the OFC was associated with the degree of aggressive behavior in this task. Therefore, data suggest there is greater susceptibility for provocation, rather than less inhibition of aggressive tendencies, in individuals with higher aggressive responses. This further supports the hypothesis that reactive aggression can be seen as a consequence of provocation of aggressive emotional responses and parallel evaluative regulatory processes mediated mainly by the insula and prefrontal areas (OFC, mPFC, dlPFC, and ACC) respectively.
ISSN:1471-2202
1471-2202
DOI:10.1186/s12868-017-0390-z