The brains of children with autism are relatively inflexible at switching from rest to task performance, according to a new brain-imaging study from the Stanford University School of Medicine.
Instead of changing to accommodate a job, connectivity in key brain networks of autistic children looks similar to connectivity in the resting brain. And the greater this inflexibility, the more severe the child's manifestations of repetitive and restrictive behaviors that characterize autism, the study found.
The study, which will be published online July 29 in Cerebral Cortex, used functional magnetic resonance imaging, or fMRI, to examine children's brain activity at rest and during two tasks: solving simple math problems and looking at pictures of different faces. The study included an equal number of children with and without autism. The developmental disorder, which now affects one of every 68 children in the United States, is characterized by social and communication deficits, repetitive behaviors and sensory problems.
"We wanted to test the idea that a flexible brain is necessary for flexible behaviors," said Lucina Uddin, PhD, a lead author of the study. "What we found was that across a set of brain connections known to be important for switching between different tasks, children with autism showed reduced 'brain flexibility' compared with typically developing peers." Uddin, who is now an assistant professor of psychology at the University of Miami, was a postdoctoral scholar at Stanford when the research was conducted.
"The fact that we can tie this neurophysiological brain-state inflexibility to behavioral inflexibility is an important finding because it gives us clues about what kinds of processes go awry in autism," said Vinod Menon, PhD, the Rachel L. and Walter F. Nichols, MD, professor of psychiatry and behavioral sciences at Stanford and the senior author of the study.
The researchers focused on a network of brain areas they have studied before. These areas are involved in making decisions, performing social tasks and identifying relevant events in the environment to guide behavior. The team's prior work showed that, in children with autism, activity in these areas was more tightly connected when the brain was at rest than it was in children who didn't have autism.
The new research shows that, in autism, connectivity in these networks that can be seen on fMRI scans is fairly similar regardless of whether the brain is at rest or performing a task. In contrast, typically developing children have a larger shift in brain connectivity when they perform tasks.
The study looked at 34 kids with autism and 34 typically developing children. All of the children with autism received standard clinical evaluations to characterize the severity of their disorder. Then, the two groups were split in half: 17 children with autism and 17 typically developing children had their brains scanned with fMRI while at rest and while performing simple arithmetic problems. The remaining children had their brains scanned at rest and during a task that asked them to distinguish between different people's faces. The facial recognition task was chosen because autism is characterized by social deficits; the math task was chosen to reflect an area in which children with autism do not usually have deficits.
Children with autism performed as well as their typically developing peers on both tasks -- that is, they were as good at distinguishing between the faces and solving the math problems. However, their brain scan results were different. In addition to the reduced brain flexibility, the researchers showed a correlation between the degree of inflexibility and the severity of restrictive and repetitive behaviors, such as performing the same routine over and over or being obsessed with a favorite topic.
"This is the first study that has examined how the patterns of intrinsic brain connectivity change with a cognitive load in children with autism," Menon said. The research is the first to demonstrate that brain connectivity in children with autism changes less, relative to rest, in response to a task than the brains of other children, he added.
"The findings may help researchers evaluate the effects of different autism therapies," said Kaustubh Supekar, PhD, a research associate and the other lead author of the study. "Therapies that increase the brain's flexibility at switching from rest to goal-directed behaviors may be a good target, for instance."
"We're making progress in identifying a brain basis of autism, and we're starting to get traction in pinpointing systems and signaling mechanisms that are not functioning properly," Menon said. "This is giving us a better handle both in thinking about treatment and in looking at change or plasticity in the brain."
Other Stanford authors of the study are research assistants Charles Lynch, Katherine Cheng, Paola Odriozola and Maria Barth; Jennifer Phillips, PhD, clinical associate professor of psychiatry and behavioral sciences and co-director of the Autism and Developmental Disabilities Clinic at Lucile Packard Children's Hospital Stanford; Carl Feinstein, MD, professor emeritus of psychiatry and behavioral sciences; and Daniel Abrams, PhD, postdoctoral scholar.
Feinstein and Menon are members of Stanford's Child Health Research Institute.
The study was supported by grants from the International Society for Autism Research, the Singer Foundation, and the National Institutes of Health (grants K01MH092288, HD047520, HD059205 and MH084164).
Information about Stanford's Department of Psychiatry and Behavioral Sciences, which also supported the work, is available at http://psychiatry.
The Stanford University School of Medicine consistently ranks among the nation's top medical schools, integrating research, medical education, patient care and community service. For more news about the school, please visit http://mednews.