Search for sympathy uncovers patterns of brain activity
Neuroscientists trying to tease out the mechanisms underlying the basis of human sympathy have found that such feelings trigger brain activity not only in areas associated with emotion but also in areas associated with performing an action. But, when people act in socially inappropriate ways this activity is replaced by increased activity in regions associated with social conflict.
Understanding the neurophysiology of such basic human characteristics as sympathy is important because some people lack those feelings and may behave in anti-social ways that can be extremely costly to society, said Dr. Jean Decety of the University of Washington. Decety heads the social-cognitive neuroscience laboratory at the UWs Center for Mind, Brain & Learning and is lead author of a new study that appears in a just-published special issue of the journal Neuropsychologia.
In the study, Decety and doctoral student Thierry Chaminade used positron emission tomography (PET) scans to explore what brain systems were activated while people watched videos of actors telling stories that were either sad or neutral in tone. The neutral stories were based on everyday activities such as cooking and shopping. The sad stories described events that could have happened to anyone, such as a drowning accident or the illness of a close relative. The actors were videotaped telling the stories, which lasted one to two minutes, with three different expressions – neutral, happy or sad.
Decety and Chaminade found that, as people watched the videos, different brain regions were activated depending on whether an actors expressions matched the emotional content of the story.
When the story content and expression were congruent, neural activity increased in emotional processing areas of the brain – the amygdala and the adjacent orbitofrontal cortex and the insula. In addition, increased activation also was noted in what neuroscientists call the “shared representational” network which includes the right inferior parietal cortex and premotor cortex. This network refers to brain areas that are activated when a person has a mental image of performing an action, actually performs that action or observes someone else performing it.
However, these emotional processing areas were suppressed when the story content and expression were mismatched, such as by having a person smile while telling about his mothers death. Instead, activation was centered in the ventromedial prefrontal cortex and superior frontal gyrus, regions that deal with social conflict.
After watching each video clip, the 12 subjects in the study also were asked to rate the storytellers mood and likability. Not surprisingly the subjects found the storytellers more likable and felt more sympathetic toward them when their emotional expression matched a storys content than when it did not.
“Sympathy is a very basic way in which we are connected to other people,” said Decety. “We feel more sympathy if the person we are interacting with is more like us. When people act in strange ways, you feel that person is not like you.
“It is important to note that the emotional processing network of the brain was not activated when the subjects in our study watched what we would consider to be inappropriate social behavior. Knowing how the brain typically functions in people when they are sympathetic will lead to a better understanding of why some individuals lack sympathy.”
The research was funded by Frances Institut de la Santé et de la Recherche Médicale, the Talaris Research Institute and the Apex Foundation, the family foundation created by Bruce and Jolene McCaw.
For more information, contact Decety at (206) 543-7357or decety@u.washington.edu or Rose Pike at the Center for Mind, Brain & Learning at (206) 221-6473 or rosepike@u.washington.edu
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