 |
|
People Use Separate Brain Mechanisms to Make Ambiguous and Risky Choices
March 06, 2006Distinct regions of the human brain are activated when people are faced with ambiguous choices versus choices involving only risk, Duke University Medical Center researchers have discovered.
The investigators found that they could predict activation of different brain areas, based on how averse study participants were toward either risk or ambiguity. The finding confirms what economists have long debated - that different attitudes toward perceived risk and ambiguity in decision-making situations may reflect a basic distinction in brain function, the researchers said. Such fundamental knowledge of neural functioning will contribute to an understanding of why people make risky choices, and how such risk-taking can become pathological, as in addiction or compulsive gambling, they added.
Their study appears in the March 2, 2006 issue of Neuron. The research was supported by the National Institute of Mental Health, the National Institute of Neurological Disorders and Stroke and Duke.
"We were able to see individual differences in brain activation depending on the person's preferences or aversions to risk and ambiguity," said Scott Huettel, Ph.D., lead author and a neuroscientist with the Brain Imaging and Analysis Center at Duke University. "People who preferred ambiguity had increased activation in the prefrontal cortex, and people who preferred risk had increased activation in the parietal cortex. This opens up the possibility that there are specific neural mechanisms for different forms of economic decision making, which is a very exciting idea."
The team collected data from 13 adult participants who were asked to choose between pairs of monetary "gambles" that were predetermined to be 'certain', 'risky' or 'ambiguous'. For the risky choices, subjects were told the odds that they would win the gambles, but for the ambiguous choices, subjects were not given this information. The participants were rewarded with a cash payout based upon whether or not they won their gambles.
The team used functional magnetic resonance imaging (MRI) to determine which areas of the brain were activated while people were making risky or ambiguous choices. Functional MRI is a widely used brain imaging technique that uses harmless magnetic fields and radio waves to measure cerebral blood oxygenation, which reflects brain activity in a region. The researchers determined the subjects' preferences by examining how frequently they chose each type of gamble during the experiment.
They found that activation of specific brain regions depended on participants' preferences for risk or for ambiguity. They soon learned that the activation of an area in the lateral prefrontal cortex depended upon whether people tended to choose ambiguous gambles, while activation of an area in the posterior parietal cortex depended on whether people tended to choose risky gambles. Furthermore, whether or not a person is, by nature, impulsive appears to correlate with whether or not their brain preferred risky gambles to those that were ambiguous, the researchers said.
"Some people are impulsive, some people are not; some people think through their decisions while others don't, and sometimes this can become pathological," said Michael Platt, Ph.D., a neurobiologist and co-author of the study. "Impulsive behavior can be associated with all sorts of mental disorders like addiction or problem gambling. If it could be demonstrated that we could change the way people perceive risk and ambiguity by introducing a medication that could influence brain chemistry, someday we might be able to alleviate some types of pathological decision making."
The results provide important data for the emerging field of "neuroeconomics," Huettel added. Neuroeconomics is a relatively new area of research in which neuroscientists, economists, psychologists and psychiatrists collaborate to better understand how the brain works when people make decisions, evaluate risk, and receive rewards.
"By understanding these mechanisms, we may be able to make better predictions about how people will behave or interact in different circumstances," Huettel said.
Further, the team's results should yield new insights in economics, according to Jill Stowe, Ph.D., a decision scientist with Duke's Fuqua School of Business and co-author of the study.
"The results are exciting because they suggest that people evaluate risky and ambiguous options in different ways," she said. "That element is not currently embedded in current economic models of decision making under risk or ambiguity, so this may very well lead to better economic models in the future, as well as hold implications for future economic policy."
Huettel, Platt and Stowe are Co-Directors of the Center for Neuroeconomic Studies at Duke. Evan Gordon and Brent Warner of the Brain Imaging and Analysis Center at Duke are also authors on the study.
Duke University Medical Center
"We were able to see individual differences in brain activation depending on the person's preferences or aversions to risk and ambiguity," said Scott Huettel, Ph.D., lead author and a neuroscientist with the Brain Imaging and Analysis Center at Duke University. "People who preferred ambiguity had increased activation in the prefrontal cortex, and people who preferred risk had increased activation in the parietal cortex. This opens up the possibility that there are specific neural mechanisms for different forms of economic decision making, which is a very exciting idea."
The team collected data from 13 adult participants who were asked to choose between pairs of monetary "gambles" that were predetermined to be 'certain', 'risky' or 'ambiguous'. For the risky choices, subjects were told the odds that they would win the gambles, but for the ambiguous choices, subjects were not given this information. The participants were rewarded with a cash payout based upon whether or not they won their gambles.
The team used functional magnetic resonance imaging (MRI) to determine which areas of the brain were activated while people were making risky or ambiguous choices. Functional MRI is a widely used brain imaging technique that uses harmless magnetic fields and radio waves to measure cerebral blood oxygenation, which reflects brain activity in a region. The researchers determined the subjects' preferences by examining how frequently they chose each type of gamble during the experiment.
They found that activation of specific brain regions depended on participants' preferences for risk or for ambiguity. They soon learned that the activation of an area in the lateral prefrontal cortex depended upon whether people tended to choose ambiguous gambles, while activation of an area in the posterior parietal cortex depended on whether people tended to choose risky gambles. Furthermore, whether or not a person is, by nature, impulsive appears to correlate with whether or not their brain preferred risky gambles to those that were ambiguous, the researchers said.
"Some people are impulsive, some people are not; some people think through their decisions while others don't, and sometimes this can become pathological," said Michael Platt, Ph.D., a neurobiologist and co-author of the study. "Impulsive behavior can be associated with all sorts of mental disorders like addiction or problem gambling. If it could be demonstrated that we could change the way people perceive risk and ambiguity by introducing a medication that could influence brain chemistry, someday we might be able to alleviate some types of pathological decision making."
The results provide important data for the emerging field of "neuroeconomics," Huettel added. Neuroeconomics is a relatively new area of research in which neuroscientists, economists, psychologists and psychiatrists collaborate to better understand how the brain works when people make decisions, evaluate risk, and receive rewards.
"By understanding these mechanisms, we may be able to make better predictions about how people will behave or interact in different circumstances," Huettel said.
Further, the team's results should yield new insights in economics, according to Jill Stowe, Ph.D., a decision scientist with Duke's Fuqua School of Business and co-author of the study.
"The results are exciting because they suggest that people evaluate risky and ambiguous options in different ways," she said. "That element is not currently embedded in current economic models of decision making under risk or ambiguity, so this may very well lead to better economic models in the future, as well as hold implications for future economic policy."
Huettel, Platt and Stowe are Co-Directors of the Center for Neuroeconomic Studies at Duke. Evan Gordon and Brent Warner of the Brain Imaging and Analysis Center at Duke are also authors on the study.
Duke University Medical Center
Brain Mechanism Current Events and Brain Mechanism News RSSNeural mechanism reveals why dyslexic brain has trouble distinguishing speech from noise
New research reveals that children with developmental dyslexia have a deficit in a brain mechanism involved in the perception of speech in a noisy environment.
Discovery may provide new treatments for alcohol dependence
Researchers at the Sahlgrenska Academy, Gothenburg, have discovered a new brain mechanism involved in alcohol addiction involving the stomach hormone ghrelin.
Recognizing someone's name but forgetting how you met them is all in your head
New research from The University of Western Ontario suggests the sometimes eerie feeling experience when recognizing someone, yet failing to remember how or why, reveals important insight into how memory is wired in the human brain.
Low-pitch treatment alleviates ringing sound of tinnitus
For those who pumped up the volume one too many times, UC Irvine researchers may have found a treatment for the hearing damage loud music can cause.
Drug triggers body's mechanism to reverse aging effect on memory process
A drug made to enhance memory appears to trigger a natural mechanism in the brain that fully reverses age-related memory loss, even after the drug itself has left the body, according to researchers at UC Irvine.
Complex Gene Interactions Account for Autism Risk
Using a novel analysis of the interactions among related genes, Duke University Medical Center researchers have uncovered some of the first evidence that complex genetic interactions account for autism risk.
More Brain Mechanism Current Events and Brain Mechanism News Articles
|
Speech and Brain-Mechanisms. First Ed. by Wilder Penfield (Author) | |
 |
Keyboard Holder; Articulating Mechanism by Ergotron The Articulating Keyboard Arm mounts a Keyboard/Mouse Tray (77-026-098) below the Worksurface. It features a wide range of adjustment options: slide forward and backward; move up and down 6 inches; rotate 360; tilts fore and aft. Main FeaturesManufacturer: Ergotron, IncManufacturer Part Number: 75-038Manufacturer Website Address: www.ergotron.comProduct Type: ArmDimensions: 16.812" Length - Slide Track |
 |
Ergonomic Concepts Boomerang Board Reflexive Mechanism - Keyboard platform with mouse tray by Ergonomic Concepts The Boomerang Board provides keyboard and mouse support within typical radius of 18" or more or angled corner configurations of 17" or more. The radial movement of the pull-out mouse tray helps support mousing within a restricted space. The REF mechanism adjusts in height by simply lifting up on the platform. The tilt angle can be set by tightening the palm handle. |
![How the Ear Works (1948) [DVD]](http://ecx.images-amazon.com/images/I/41qUxbD5zmL._SL160_.jpg) |
How the Ear Works (1948) [DVD] We all know that if a pebble is dropped into water, ring-like ripples spread in all directions over the surface. A doorbell ringing sends out similar but invisible wavelike impulses, which travel through the air with a speed of about 1100 feet per second. Sounds of every kind are transmitted to our ears by just such waves. The modern miracles of sound, motion pictures and radio open up vast sources of entertainment and instruction. To benefit from these, we need our ears, which interpret for us the multitude of sound waves they receive. Lend us your ears and learn about these invisible waves and how our ears are able to convert them into sound. |
 |
Fetal and Neonatal Brain Injury: Mechanisms, Management and the Risks of Practice by Benitz (Author), David K. Stevenson (Adapter), Philip Sunshine (Adapter) This comprehensive survey of fetal and neonatal brain injury discusses a broad range of areas from epidemiology and pathogenesis, to clinical manifestations and obstetric care, and on to diagnosis, long-term outcomes, and medico-legal aspects. This latest edition highlights scientific and clinical advances that have played a role in minimizing risk, improving clinical care and outcomes. It describes how placental abnormalities, imaging studies, and laboratory measurements can identify the timing and severity of the injury. |
|
Brain Mechanisms and Mind (World of Science) by Keith Oatley (Author) | |
 |
Okidata 2ND PAPER TRAY MECHANISM ( 42158551 ) by Okidata 530 sheet 2nd paper tray provides increased flexibility and low user intervention. |
|
Brain Mechanisms of Sleep by Dennis J. McGinty (Contributor) | |
 |
Brain Mechanisms for the Integration of Posture and Movement (Progress in Brain Research) by Author Unknown (Author) Second author, Douglas G. Stuart, is with the Univ. of Arizona, Tucson. Describes the current state of knowledge on the role of parallel and distributed neuronal systems in the integration of posture and movement. Discusses the brainstem-spinal cord interactions, early appearing movements, and later-developed skilled movements. |
 |
Brain Mechanisms, Volume 1 (Progress in Brain Research) by Author Unknown (Editor) |
| © 2009 BrightSurf.com |