Summary: Researchers report neurons in the posterior cingulate cortex ramp up activity prior to divergent behavior.
Source: University of Pennsylvania.
Have you ever been stuck in a rut, going through the same motions day in and day out? How do you motivate to change your behavior?
Researchers from the University of Pennsylvania, Yale University, Columbia University and Duke University now better understand how this happens, and it has to do with a region in the brain called the posterior cingulate cortex. They learned that neurons in this central location ramp up firing rates, peaking just before a divergent behavior occurs. They published their findings in the journal Neuron.
“The circuits in our brain that allow us to focus on a particular task, especially a task that leads to reward, are well known,” said Michael Platt, the James S. Riepe University Professor in Penn’s psychology, neuroscience and marketing departments. “These evolved very early in the history of life on this planet.”
What’s less established is which trigger in the brain causes people to break from a routine, especially when doing so poses potential risks.
Two experiments the research team conducted — one called the patch-leaving task, the other dubbed the traveling salesman — provided some important insights.
In the first, Platt and colleagues looked at the foraging behaviors of rhesus macaques, a non-human primate species the researchers have studied both in the lab and in the wild. The animals had the choice between harvesting a juice reward that depleted over time but was guaranteed and immediate or moving to a new “patch,” which would require more time and energy but offered a potentially larger reward.
“Imagine you’re picking berries in a tree,” he said. “At first it’s easy, but after a while you have to climb farther and farther out on weaker branches to get the berries, most of which probably aren’t ripe. At some point it makes sense to take the time and energy to go to the next tree.”
To understand the second experiment, think about an effective traveling salesman. The merchant moves from door to door, interacting with people in the hopes of making a deal. Not everyone purchases a product, though there is an ideal pattern for success. Once the salesman understands this, he follows that pattern until it stops working and a behavior change is necessary for continued prosperity.
Monkeys in the traveling-salesman experiment had the option to visit six different locations, two of which contained rewards, one large and one small. The reward spots were randomized, and they changed each time the experiment ran.
“The optimal solution is to develop a routine where you visit all of them in a circle. That’s the best you can do; you go from nearest neighbor to next neighbor. That’s what monkeys do in the wild. That’s what bumblebees do in the wild,” Platt said. “Occasionally, these animals break off to explore for something that might be better, kind of like what people do in a grocery store. Suddenly monkeys here would break off and go out of order. We didn’t know why.”
Simultaneous to watching the macaques’ behavior in both experiments, Platt and his colleagues recorded neuron behavior in the posterior cingulate cortex. Neural activity there built up until it peaked, at which point the animals changed course, revealing correlational evidence that this spike in brain function leads to the divergent thinking and action rather than happens because of it.
“If you increased activity in the area exogenously, if I put an electrode in there and stimulated, then you would break off from the routine, you would become more exploratory,” Platt said. “Similarly, if you could suppress activity, you’d see the opposite. You’d become hyper-focused on one option, and you may never make a change.”
These findings have potential business applications in terms of innovation and exploration. Techniques that directly activate the posterior cingulate cortex like brain stimulation or game play that promotes distraction, particularly within situations that don’t allow a routine to form, can lead to more creativity.
“People who have more activity there have more mind-wandering, and they tend to be more creative,” according to Platt. “It suggests that capacity to be more creative evolved for a very specific purpose, which is to allow you to forage efficiently in a landscape that’s always changing.”
Funding: Funding for this research came from the National Eye Institute of the National Institutes of Health (Grant R01 EY013496) and Duke Institute for Brain Sciences. Collaborators included David Barack of Columbia University and Steve Chang from Yale University.
Source: Michele Berger – University of Pennsylvania Publisher: Organized by NeuroscienceNews.com. Image Source: NeuroscienceNews.com images is credited to Michele Berger. Original Research:Abstract for “Posterior Cingulate Neurons Dynamically Signal Decisions to Disengage during Foraging” by David L. Barack, Steve W.C. Chang, and Michael L. Platt in Neuron. Published online October 11 2017 doi:10.1016/j.neuron.2017.09.048
Cite This NeuroscienceNews.com Article
[cbtabs][cbtab title=”MLA”]University of Pennsylvania “Brain Region That Motivates Behavior Change Discovered.” NeuroscienceNews. NeuroscienceNews, 24 October 2017. <https://neurosciencenews.com/behavior-change-brain-region-7805/>.[/cbtab][cbtab title=”APA”]University of Pennsylvania (2017, October 24). Brain Region That Motivates Behavior Change Discovered. NeuroscienceNews. Retrieved October 24, 2017 from https://neurosciencenews.com/behavior-change-brain-region-7805/[/cbtab][cbtab title=”Chicago”]University of Pennsylvania “Brain Region That Motivates Behavior Change Discovered.” https://neurosciencenews.com/behavior-change-brain-region-7805/ (accessed October 24, 2017).[/cbtab][/cbtabs]
Posterior Cingulate Neurons Dynamically Signal Decisions to Disengage during Foraging
Highlights •Foraging salience drives monkeys’ choices to switch strategies in two tasks •PCC neuronal activity during both tasks predicted strategy switches •PCC neurons signaled salience in both tasks more strongly in poor than rich contexts
Summary Foraging for resources is a fundamental behavior balancing systematic search and strategic disengagement. The foraging behavior of primates is especially complex and requires long-term memory, value comparison, strategic planning, and decision-making. Here we provide evidence from two different foraging tasks that neurons in primate posterior cingulate cortex (PCC) signal decision salience during foraging to motivate disengagement from the current strategy. In our foraging tasks, salience refers to the difference between decision thresholds and the net harvested reward. Salience signals were stronger in poor foraging contexts than rich ones, suggesting low harvest rates recruit mechanisms in PCC that regulate strategic disengagement and exploration during foraging.
“Posterior Cingulate Neurons Dynamically Signal Decisions to Disengage during Foraging” by David L. Barack, Steve W.C. Chang, and Michael L. Platt in Neuron. Published online October 11 2017 doi:10.1016/j.neuron.2017.09.048