Understanding Brain Mechanisms of Reactive Aggression

Bertsch, Katja; Florange, Julian G; Herpertz, Sabine C.

doi:10.1007/s11920-020-01208-6

Cited by 72 publications

(108 citation statements)

References 104 publications

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“…The present results thus indicate that the striatum is not only sensitive to status signals (Zink et al, 2008;Zerubavel et al, 2015) and competitive outcomes (Qu et al, 2017), but also differentiates between individuals differing in status during decisions to aggress. Our findings are in line with the hypothesized role of the striatum in retaliatory aggression (Chester, 2017;Bertsch et al, 2020), and concur with metaanalytic findings demonstrating increased striatal activity when individuals deliver harsher punishments to unfair co-players (Gabay et al, 2014). Therefore, our data bridge animal and human research in showing that the hippocampus and striatum are involved in the relational processing of social dominance signals.…”

Section: Neural Representations Of Competitive Status During Punishment Selectionsupporting

confidence: 90%

“…The key question that we addressed here is which role these neurocognitive processes play in status-dependent aggression. We reasoned that the neural substrate of status-processing and aggression should show some degree of overlap, be it in subcortical structures assumed to generate aggressive impulses such as the amygdala (da Cunha-Bang et al, 2017;Buades-Rotger and Krämer, 2018), in those linked with retaliation such as the VS (Buades-Rotger, Brunnlieb, et al, 2016;Chester and DeWall, 2016), and/or in areas suggested to regulate aggression such as the vmPFC (Buades-Rotger et al, 2019;Bertsch et al, 2020).…”

Section: Introductionmentioning

confidence: 99%

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Low competitive status elicits aggression in healthy young men: behavioral and neural evidence

Buades-Rotger

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et al. 2020

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Winners are commonly assumed to compete more aggressively than losers. Here, we find overwhelming evidence for the opposite. We first demonstrate that low-ranking teams commit more fouls than they receive in top-tier soccer, ice hockey, and basketball leagues. We replicate this effect in the laboratory, showing that participants deliver louder sound blasts to a rival when placed in a low-status position. Using neuroimaging, we characterize brain activity patterns that encode competitive status as well as those that facilitate status-dependent aggression. These analyses reveal three key findings. First, anterior hippocampus and striatum contain multivariate representations of competitive status. Second, interindividual differences in status-dependent aggression are linked with a sharper status differentiation in the striatum and with greater reactivity to status-enhancing victories in the dorsal anterior cingulate cortex.Third, activity in ventromedial, ventrolateral, and dorsolateral prefrontal cortex is associated with trial-wise increases in status-dependent aggressive behavior. Taken together, our results run counter to narratives glorifying aggression in competitive situations. Rather, we show that those in the lower ranks of skill-based hierarchies are more likely to behave aggressively and identify the potential neural basis of this phenomenon.

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Section: Neural Representations Of Competitive Status During Punishment Selectionsupporting

confidence: 90%

Section: Introductionmentioning

confidence: 99%

Low competitive status elicits aggression in healthy young men: behavioral and neural evidence

Buades-Rotger

Göttlich

Weiblen

et al. 2020

Preprint

View full text Add to dashboard Cite

show abstract

“…High levels of impulsive aggression (or constructs closely linked to it) has repeatedly been associated with heightened amygdala reactivity in the context of angry faces (63,64,(68)(69)(70), fearful faces (11), and provocations in the PSAP (67, 71). A recent review suggests that brain regions involved in threat sensitivity (amygdala, hypothalamus, PAG) and frustrative non-reward (amygdala, VS, caudate nucleus) represent 'activation conditions' and regions involved in cognitive control (PFC, insula, inferior parietal lobules) represent a 'regulating condition' for impulsive aggression (72). This is in line with another review of nine fMRI TAP studies concluding that a neural circuitry mediating emotional reactivity and cognitive control is implicated in reactive aggression (73), although a meta-analysis revealed that the left postcentral gyrus was the only region consistently activated across these TAP studies (74).…”

Section: Functional Neuroimaging Evidence For Brain Circuit Involvementmentioning

confidence: 99%

The Modulatory Role of Serotonin on Human Impulsive Aggression

Cunha-Bang

Knudsen

2021

Biological Psychiatry

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“…In this meta-analysis, we followed Berkowitz' (1989) proposition suggesting that withholding/removing an expected reward would enhance emotional arousal, which further increase the risk for reactive aggression. Given that several psychopathologies may exhibit enhanced risk for frustration and reactive aggression (Bertsch et al, 2020;Leibenluft, 2017), its implication for clinical population are also discussed.…”

Section: Integrative Neurobiological Model Of Frustration-aggression Sequencementioning

confidence: 99%

“…In the last decade, frustration has been thought to be implicated in several psychopathologies that are at risk for aggressive behaviors (e.g., irritability, CD/ASPD, see (Bertsch, Florange, & Herpertz, 2020;Blair, 2010b;Harenski & Kiehl, 2010;Leibenluft, 2017)).…”

Section: Introductionmentioning

confidence: 99%

Neural bases of Frustration-Aggression Theory: A multi-domain meta-analysis of functional neuroimaging studies

Dugré

Potvin

2021

Preprint

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Early evidence suggests that unexpected non-reward may increase the risk for aggressive behaviors. Despite the growing interest in understanding brain functions that may be implicated in aggressive behaviors, the neural processes underlying such frustrative events remain largely unknown. Furthermore, meta-analytic results have produced discrepant results, potentially due to substantial differences in the definition of anger/aggression constructs. Therefore, coordinate-based meta-analyses on unexpected non-reward and retaliatory behaviors in healthy subjects were conducted. Conjunction analyses were further examined to discover overlapping brain activations across these meta-analytical maps. Frustrative non-reward deactivated the orbitofrontal cortex, ventral striatum and posterior cingulate cortex, whereas increased activations were observed in midcingulo-insular regions, as well as dorsomedial prefrontal cortex, amygdala, thalamus and periaqueductal gray, when using liberal threshold. Retaliation activated of midcingulo-insular regions, the dorsal caudate and the primary somatosensory cortex. Conjunction analyses revealed that both strongly activated midcingulo-insular regions. Our results underscore the role of anterior midcingulate/pre-supplementary motor area and fronto-insular cortex in both frustration and retaliatory behaviors. A neurobiological framework for understanding frustration-based impulsive aggression is provided.

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Understanding Brain Mechanisms of Reactive Aggression

Cited by 72 publications

References 104 publications

Low competitive status elicits aggression in healthy young men: behavioral and neural evidence

Low competitive status elicits aggression in healthy young men: behavioral and neural evidence

The Modulatory Role of Serotonin on Human Impulsive Aggression

Neural bases of Frustration-Aggression Theory: A multi-domain meta-analysis of functional neuroimaging studies

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