The causal role of the somatosensory cortex in prosocial behaviour

Gallo, Selene; Paracampo, Riccardo; Müller-Pinzler, Laura; Severo, Mario Carlo; Blömer, Laila Ananda; Fernandes-Henriques, Carolina; Henschel, Anna; Lammes, Balint Kalista; Maskaljunas, Tatjana; Suttrup, Judith; Avenanti, Alessio; Keysers, Christian; Gazzola, Valeria

doi:10.7554/elife.32740

Cited by 70 publications

(87 citation statements)

References 111 publications

(171 reference statements)

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“…As for (II), empathic concern was predicted by the within-network connectivity of the somatomotor network. This result further supports an embodied, somatomotor foundation for our concern for others' welfare, in line with numerous findings relating vicarious somatosensory activation to multiple forms of prosocial behavior ((nonstrategic generosity in economic games: Christov-Moore and Iacoboni, 2016;harm aversion in moral dilemmas: Christov-Moore et al, 2017b; donations to reduce pain in another: Gallo et al, 2018;helping behavior: Hein et al, 2011;Morelli et al, 2014;charitable donations: Ma et al, 2011). This also agrees with our recent finding that inferior premotor activation during observation of pain in others was predictive of participants' later tendency to avoid inflicting harm in hypothetical moral dilemmas (Christov-Moore et al, 2017b).…”

Section: Ii)supporting

confidence: 85%

“…The most likely neural substrate for resonance appears to be "neural resonance" (Zaki and Ochsner, 2012), the phenomenon of shared neural representations for the perception and experience of disgust (Jabbi et al, 2011;Wicker et al, 2003), somatosensation (Bufalari et al, 2007;Masten et al, 2011;Singer et al, 2006), emotion (Carr et al, 2003;Pfeifer et al, 2008) and motor behavior (Iacoboni, 2009;Keysers and Fadiga, 2008). Not surprisingly, neural resonance has been repeatedly associated with self-reported measures of trait empathy (Avenanti et al, 2009;Jabbi et al, 2011;Pfeifer et al, 2008) and is predictive of pro-social behavior (non-strategic generosity in economic games: Christov-Moore and Iacoboni, 2016; harm aversion in moral dilemmas: Christov-Moore et al, 2017b; donations to reduce pain in another: Gallo et al, 2018;helping behavior: Hein et al, 2011;Morelli et al, 2014;charitable donations: Ma et al, 2011), suggesting that our resonance with others may underlie our empathic concern (and hence prosocial inclinations) for others.…”

Section: Introductionmentioning

confidence: 99%

“…Following work on restingstate and empathy (e.g. Cox et al, 2012), in a more exploratory fashion, we hypothesized that resting connectivity patterns within and between other cortical networks could also predict levels of trait empathy, with particular attention to the somatomotor network, which has been linked to many forms of prosociality (nonstrategic generosity in economic games: Christov-Moore and Iacoboni, 2016; harm aversion in moral dilemmas: Christov-Moore et al, 2017b; donations to reduce pain in another: Gallo et al, 2018;helping behavior: Hein et al, 2011;Morelli et al, 2014;charitable donations: Ma et al, 2011).…”

Section: Introductionmentioning

confidence: 99%

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Predicting Empathy from Resting Brain Connectivity

Christov-Moore

Reggente

Douglas³

et al. 2019

Preprint

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Recent task fMRI studies suggest that individual differences in trait empathy and empathic concern are mediated by patterns of interaction between self-other resonance and top-down control networks that are stable across task demands. An untested implication of this hypothesis is that these stable patterns of interaction should be visible even in the absence of empathy tasks. Using machine learning, we demonstrate that patterns of resting state fMRI connectivity (i.e. the degree of synchronous BOLD activity across multiple cortical areas in the absence of explicit task demands) of resonance and control networks predict trait empathic concern (n=58). Empathic concern was also predicted by connectivity patterns within the somatomotor network. These findings further support the role of resonance-control network interactions and of somatomotor function in our vicariously-driven concern for others. Furthermore, a practical implication of these results is that it is possible to assess empathic predispositions in individuals without needing to perform conventional empathy assessments.

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Section: Ii)supporting

confidence: 85%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Predicting Empathy from Resting Brain Connectivity

Christov-Moore

Reggente

Douglas³

et al. 2019

Preprint

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“…We often have to learn that certain actions lead to favorable outcomes for us, but harm others, while alternative actions are less favorable for us but avoid or mitigate harms to others 1 . Much is already known about the brain structures involved in making moral choices when the relevant action-outcome contingencies are well known [2][3][4][5][6][7][8][9] , but how we learn these contingencies remains poorly understood, especially in situations pitting gains to self against losses for others.…”

Section: Introductionmentioning

confidence: 99%

“…Or do we typically track separate expectations for benefits to the self and harms to others? In addition, people differ in how they represent benefits and harms to self 14 , and in whether they prefer to maximize benefits for the self vs. minimizing harms to others 3,4,6 . How can such differences be computationally represented using RLT?…”

Section: Introductionmentioning

confidence: 99%

Neuro-computational mechanisms of action-outcome learning under moral conflict

Nostro

Ioumpa

Paracampo

et al. 2020

Preprint

Self Cite

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Learning to predict how our actions result in conflicting outcomes for self and others is essential for social functioning, but remains poorly understood. We test whether Reinforcement Learning Theory captures how participants learn to choose between two symbols that define a moral conflict between financial gain to self and pain for others. Computational modelling and fMRI imaging show that participants have dissociable representations for self-gain and pain to others. Signals in dorsal rostral cingulate and insulae track more closely with outcomes than prediction errors, while the opposite is true for the ventral rostral cingulate. Cognitive computational models estimated a valuational preference parameter that captured individual variability of choice in this moral conflict task. Participants' valuational preferences predicted how much they chose to spend to reduce another person's pain in an independent task. Learning separate representations for self and others allows participants to rapidly adapt to changes in contingencies during conflicts.

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Testing effects of social rejection on aggressive and prosocial behavior: A meta‐analysis

Quarmley

Feldman

Grossman

et al. 2022

Aggressive Behavior

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Social rejection elicits profound feelings of distress. From an evolutionary perspective, the best way to alleviate this distress is to behave prosocially, minimizing the likelihood of further exclusion. Yet, examples ranging from the playground to the pub suggest rejection commonly elicits aggression. Opposing theoretical perspectives and discordant empirical results have left a basic question unanswered: does rejection more commonly elicit prosocial or aggressive behavior?We conducted three meta-analyses (one with studies measuring aggressive behavior; one with studies measuring prosocial behavior; and one with studies measuring both aggressive and prosocial behavior; N = 3864) to quantify: (1) the extent to which social rejection elicits prosocial or aggressive behavior and (2) potential moderating effects on these relations. Random-effects models revealed medium effects such that social rejection potentiated aggressive behavior (k = 19; d = 0.41, p < .0001) and attenuated prosocial behavior (k = 7; d = 0.59, p < .0001), an effect that remained consistent even when participants were given the option to behave prosocially or aggressively (k = 15; d = 0.71, p < .0001). These results cast doubt on the theory that rejection triggers prosocial behavior, and instead suggest it is a robust elicitor of aggression.Statement of Relevance: To our knowledge, these meta-analyses are the first to directly test whether social rejection elicits aggressive or prosocial behavior. By including a comprehensive collection of both published and unpublished research studies, and examining a wide variety of previously untested moderators, we show that social rejection robustly elicits aggressive behavior and inhibits prosocial behavior. Additionally, we demonstrate that aggressive behavior following social rejection is not simply a function of limited choices in response options. In fact, aggressive behavior was evoked even when the option to engage in prosocial behavior was provided. Furthermore, we conducted a comprehensive narrative review of the neural mechanisms underlying social rejection-elicited aggressive and prosocial behavior to supplement primary analyses. Overall, we believe that our work makes a critical theoretical contribution to the field.

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The causal role of the somatosensory cortex in prosocial behaviour

Cited by 70 publications

References 111 publications

Predicting Empathy from Resting Brain Connectivity

Predicting Empathy from Resting Brain Connectivity

Neuro-computational mechanisms of action-outcome learning under moral conflict

Testing effects of social rejection on aggressive and prosocial behavior: A meta‐analysis

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