Brain network that controls, redirects attention identified
News Jul 16, 2015
Human-specific network may have evolved to strengthen social communication
Researchers at Columbia University Medical Center (CUMC) have found that key parts of the human brain network that give us the power to control and redirect our attention—a core cognitive ability—may be unique to humans. The research, which was published in the July 13 online edition of the Proceedings of the National Academy of Sciences, suggests that the network may have evolved in response to increasingly complex social cues.
“The human brain is powerful, but even it cannot make sense of the entire sum of stimuli that bombard our senses,” said Vincent P. Ferrera, PhD, the study’s senior author. Dr. Ferrera is a principal investigator at Columbia’s Mortimer B. Zuckerman Mind Bran Behavior Institute and associate professor in the department of neuroscience (in psychiatry) at CUMC. “Instead, it selects and prioritizes information based on what is needed at any given moment—this is called attention. And while attention is a fundamental characteristic of human cognition, and something that we use all the time, the underlying brain circuits that give us this ability remain largely unclear.”
In order to better understand these circuits, the authors compared the brains of primate and human subjects during a specific attention-seeking task. In so doing, they uncovered key clues about these so-called ‘attention networks’: how they evolved and how they underlie human cognitive abilities—and are already using this information to test what role they may play in psychiatric disorders.
In the human brain, there are two main attention networks: the dorsal attention network (DAN) and ventral attention network (VAN). “The DAN is in charge of directing your attention to something specific, and when it’s active, the VAN is silent,” explained Gaurav Patel, MD/PhD, a postdoctoral fellow in the Department of Psychiatry and the study’s first author. “This keeps you focused and limits your distraction. But if you see something that is new, unique, or behaviorally relevant, the VAN will switch on. This give-and-take between the DAN and VAN allows us to reorient our attention to what is most important.”
In a series of experiments, first using a primate model at Washington University in St. Louis, and later with human subjects at CUMC, the researchers used functional magnetic resonance imaging (fMRI) to map brain activity. Before the start of a session, the subject memorized a specific target object. During the session, a stream of images appeared on various parts of a screen. The subject pushed a button when the target object appeared on the screen. fMRI technology allowed the researchers to see when various parts of the brain ‘switched on’ while the subject performed the task. And the results were surprising.
Increases (orange--yellow) & decreases (blue) of neural activity in the macaque brain while performing an attention task as measured by fMRI. Courtesy: Gaurav Patel/New York State Psychiatric Institute/Columbia University Medical Center
“The fMRI showed striking differences between the two species, which was wholly unexpected,” said Dr. Patel. “We were giving both the human and primate subjects the exact same task—their brain activity should have been more similar. That’s when we realized there was something else going on.”
First, they realized that the VAN—located in the right hemisphere of the human brain—had no equivalent in the primate brain. They also noticed the DAN had expanded in the human subjects, and observed enhanced cross talk between the human subjects’ brain hemispheres.
“Taken together, these findings suggests that at some point in our evolutionary history, we evolved an additional attention network—perhaps in order to better process the world around us,” said Dr. Patel.
The human social world is far more complex than any of our primate relatives. It is possible this network evolved to help us understand increasingly complex social cues, such as the subtle twitch of an eyebrow, or a shift in gaze, say the researchers.
Armed with this new information, Dr. Patel is now examining the attention networks of people with schizophrenia—a disorder characterized in part by poor social function.
“Persons with schizophrenia have difficulty expressing emotions, responding to social cues and often become socially isolated,” said Dr. Patel. “Right now we’re testing whether these individuals have an impairment to how the VAN is organized or communicates with the rest of the brain. Because if they do, we could potentially tailor a treatment strategy to mitigate that impairment, and maybe even restore some level of social communication that the patient lacked.”
Note: Material may have been edited for length and content. For further information, please contact the cited source.
Ferrara VP et al. Functional evolution of new and expanded attention networks in humans. Proceedings of the National Academy of Sciences, Published Online July 13 2015. doi: 10.1073/pnas.1420395112
Synaptotagmin 7 Ensures Efficiency of Inhibitory Signal TransmissionNews
Researchers at IST Austria define function of an enigmatic synaptic protein, synaptotagmin 7.READ MORE
Molecules in Spit Could Help Diagnose ConcussionsNews
Diagnosing a concussion can sometimes be a guessing game, but clues taken from small molecules in saliva may be able to help diagnose and predict the duration of concussions in children, according to Penn State College of Medicine researchers.READ MORE
Elpis BioMed Closes Funding Round to Commercialise Novel Technology Platform for Generating Human Cell TypesNews
New Cambridge spin-out company commercialises disruptive technology that enables rapid generation of pure and consistent batches of human cell types. Geographically diversified, top-tier investor team includes key industry leaders to support early company development.READ MORE