It’s not simply a professional skill to multitask. It requires something known as cognitive flexibility, or the capacity to seamlessly switch between different brain processes, and it is essential to functioning as a person.
Researchers from UNC undertook a study to map the neural correlates of cognitive flexibility and identify variations in the brain activity of kids with Attention Deficit Hyperactivity Disorder (ADHD) and without it. Their findings were published in the journal Molecular Psychiatry, which could help doctors diagnose children with ADHD and monitor the severity of the condition and treatment effectiveness.
Some people are more cognitively flexible than others. It’s just the luck of the genetic draw in some ways, though we can improve our cognitive flexibility once we realize we’re being inflexible.
Think of it like this: we’re cognitively flexible when we can start dinner, let the onions simmer, text a friend, return to making dinner without scorching the onions, and then finish dinner while also carrying on a conversation with your spouse.
We’re also cognitively flexible when we switch communication styles while talking to a friend and then a daughter and then a coworker, or when we solve problems creatively, say, when you realize you don’t have onions to make the dinner you want, so you need a new plan.
It’s part of our executive function, which includes accessing memories and exhibiting self control. Poor executive function is a hallmark of ADHD in children and adults. When we’re cognitively inflexible, we can’t focus on some of the tasks, we pick up the phone and scroll social media without thinking, forgetting what we’re doing while making dinner. In adults but especially in children, such cognitive inflexibility can wreak havoc with an individual’s ability to learn and accomplish tasks.
UNC scientists led by senior author Weili Lin, PhD, director of the UNC Biomedical Research Imaging Center (BRIC), wanted to find out what’s happening throughout the brain when executive function, particularly cognitive flexibility, is off line.
Lin and colleagues used functional magnetic resonance imaging (fMRI) to study the neural flexibility of 180 children diagnosed with ADHD and 180 typically developing children. “We observed significantly decreased neural flexibility in the ADHD group at both the whole brain and sub-network levels,” said Lin, the Dixie Boney Soo Distinguished Professor of Neurological Medicine in the UNC Department of Radiology, “particularly for the default mode network, attention-related networks, executive function-related networks, and primary networks of the brain involved in sensory, motor and visual processing.”
The researchers also found that children with ADHD who received medication exhibited significantly increased neural flexibility compared to children with ADHD who were not taking medication. Children on medication displayed neural flexibility that was not statistically different from the group of traditionally developing children.
Lastly, the researchers found that they could use fMRI to discover neural flexibility differences across entire brain regions between children with ADHA and the traditionally developing children.
“And we were able to predict ADHD severity using clinical measures of symptom severity,” Lin said. “We think our study demonstrate the potential clinical utility of neural flexibility to identify children with ADHD, as well as to monitor treatment responses and the severity of the condition in individual children.”