 |
|
EEGs show brain differences between poor and rich kids
December 03, 2008Prefrontal cortex activity in poor children resembles that of stroke victim, study finds
Berkeley -- University of California, Berkeley, researchers have shown for the first time that the brains of low-income children function differently from the brains of high-income kids.
In a study recently accepted for publication in the Journal of Cognitive Neuroscience, scientists at UC Berkeley's Helen Wills Neuroscience Institute and the School of Public Health report that normal 9- and 10-year-olds differing only in socioeconomic status have detectable differences in the response of their prefrontal cortex, the part of the brain that is critical for problem solving and creativity.
Brain function was measured by means of an electroencephalograph (EEG) - basically, a cap fitted with electrodes to measure electrical activity in the brain - like that used to assess epilepsy, sleep disorders and brain tumors.
"Kids from lower socioeconomic levels show brain physiology patterns similar to someone who actually had damage in the frontal lobe as an adult," said Robert Knight, director of the institute and a UC Berkeley professor of psychology. "We found that kids are more likely to have a low response if they have low socioeconomic status, though not everyone who is poor has low frontal lobe response."
Previous studies have shown a possible link between frontal lobe function and behavioral differences in children from low and high socioeconomic levels, but according to cognitive psychologist Mark Kishiyama, first author of the new paper, "those studies were only indirect measures of brain function and could not disentangle the effects of intelligence, language proficiency and other factors that tend to be associated with low socioeconomic status. Our study is the first with direct measure of brain activity where there is no issue of task complexity."
Co-author W. Thomas Boyce, UC Berkeley professor emeritus of public health who currently is the British Columbia Leadership Chair of Child Development at the University of British Columbia (UBC), is not surprised by the results. "We know kids growing up in resource-poor environments have more trouble with the kinds of behavioral control that the prefrontal cortex is involved in regulating. But the fact that we see functional differences in prefrontal cortex response in lower socioeconomic status kids is definitive."
Boyce, a pediatrician and developmental psychobiologist, heads a joint UC Berkeley/UBC research program called WINKS - Wellness in Kids - that looks at how the disadvantages of growing up in low socioeconomic circumstances change children's basic neural development over the first several years of life.
"This is a wake-up call," Knight said. "It's not just that these kids are poor and more likely to have health problems, but they might actually not be getting full brain development from the stressful and relatively impoverished environment associated with low socioeconomic status: fewer books, less reading, fewer games, fewer visits to museums."
Kishiyama, Knight and Boyce suspect that the brain differences can be eliminated by proper training. They are collaborating with UC Berkeley neuroscientists who use games to improve the prefrontal cortex function, and thus the reasoning ability, of school-age children.
"It's not a life sentence," Knight emphasized. "We think that with proper intervention and training, you could get improvement in both behavioral and physiological indices."
Kishiyama, Knight, Boyce and their colleagues selected 26 children ages 9 and 10 from a group of children in the WINKS study. Half were from families with low incomes and half from families with high incomes. For each child, the researchers measured brain activity while he or she was engaged in a simple task: watching a sequence of triangles projected on a screen. The subjects were instructed to click a button when a slightly skewed triangle flashed on the screen.
The researchers were interested in the brain's very early response - within as little as 200 milliseconds, or a fifth of a second - after a novel picture was flashed on the screen, such as a photo of a puppy or of Mickey and Minnie Mouse.
"An EEG allows us to measure very fast brain responses with millisecond accuracy," Kishiyama said.
The researchers discovered a dramatic difference in the response of the prefrontal cortex not only when an unexpected image flashed on the screen, but also when children were merely watching the upright triangles waiting for a skewed triangle to appear. Those from low socioeconomic environments showed a lower response to the unexpected novel stimuli in the prefrontal cortex that was similar, Kishiyama said, to the response of people who have had a portion of their frontal lobe destroyed by a stroke.
"When paying attention to the triangles, the prefrontal cortex helps you process the visual stimuli better. And the prefrontal cortex is even more involved in detecting novelty, like the unexpected photographs," he said. But in both cases, "the low socioeconomic kids were not detecting or processing the visual stimuli as well. They were not getting that extra boost from the prefrontal cortex."
"These kids have no neural damage, no prenatal exposure to drugs and alcohol, no neurological damage," Kishiyama said. "Yet, the prefrontal cortex is not functioning as efficiently as it should be. This difference may manifest itself in problem solving and school performance."
The researchers suspect that stressful environments and cognitive impoverishment are to blame, since in animals, stress and environmental deprivation have been shown to affect the prefrontal cortex. UC Berkeley's Marian Diamond, professor emeritus of integrative biology, showed nearly 20 years ago in rats that enrichment thickens the cerebral cortex as it improves test performance. And as Boyce noted, previous studies have shown that children from poor families hear 30 million fewer words by the time they are four than do kids from middle-class families.
"In work that we and others have done, it really looks like something as simple and easily done as talking to your kids" can boost prefrontal cortex performance, Boyce said.
"We are certainly not blaming lower socioeconomic families for not talking to their kids - there are probably a zillion reasons why that happens," he said. "But changing developmental outcomes might involve something as accessible as helping parents to understand that it is important that kids sit down to dinner with their parents, and that over the course of that dinner it would be good for there to be a conversation and people saying things to each other."
"The study is suggestive and a little bit frightening that environmental conditions have such a strong impact on brain development," said Silvia Bunge, UC Berkeley assistant professor of psychology who is leading the intervention studies on prefrontal cortex development in teenagers by using functional magnetic resonance imaging (fMRI).
Boyce's UBC colleague, Adele Diamond, showed last year that 5- and 6-year-olds with impaired executive functioning, that is, poor problem solving and reasoning abilities, can improve their academic performance with the help of special activities, including dramatic play.
Bunge hopes that, with fMRI, she can show improvements in academic performance as a result of these games, actually boosting the activity of the prefrontal cortex.
"People have tried for a long time to train reasoning, largely unsuccessfully," Bunge said. "Our question is, 'Can we replicate these initial findings and at the same time give kids the tools to succeed?'"
University of California - Berkeley
Brain function was measured by means of an electroencephalograph (EEG) - basically, a cap fitted with electrodes to measure electrical activity in the brain - like that used to assess epilepsy, sleep disorders and brain tumors.
"Kids from lower socioeconomic levels show brain physiology patterns similar to someone who actually had damage in the frontal lobe as an adult," said Robert Knight, director of the institute and a UC Berkeley professor of psychology. "We found that kids are more likely to have a low response if they have low socioeconomic status, though not everyone who is poor has low frontal lobe response."
Previous studies have shown a possible link between frontal lobe function and behavioral differences in children from low and high socioeconomic levels, but according to cognitive psychologist Mark Kishiyama, first author of the new paper, "those studies were only indirect measures of brain function and could not disentangle the effects of intelligence, language proficiency and other factors that tend to be associated with low socioeconomic status. Our study is the first with direct measure of brain activity where there is no issue of task complexity."
Co-author W. Thomas Boyce, UC Berkeley professor emeritus of public health who currently is the British Columbia Leadership Chair of Child Development at the University of British Columbia (UBC), is not surprised by the results. "We know kids growing up in resource-poor environments have more trouble with the kinds of behavioral control that the prefrontal cortex is involved in regulating. But the fact that we see functional differences in prefrontal cortex response in lower socioeconomic status kids is definitive."
Boyce, a pediatrician and developmental psychobiologist, heads a joint UC Berkeley/UBC research program called WINKS - Wellness in Kids - that looks at how the disadvantages of growing up in low socioeconomic circumstances change children's basic neural development over the first several years of life.
"This is a wake-up call," Knight said. "It's not just that these kids are poor and more likely to have health problems, but they might actually not be getting full brain development from the stressful and relatively impoverished environment associated with low socioeconomic status: fewer books, less reading, fewer games, fewer visits to museums."
Kishiyama, Knight and Boyce suspect that the brain differences can be eliminated by proper training. They are collaborating with UC Berkeley neuroscientists who use games to improve the prefrontal cortex function, and thus the reasoning ability, of school-age children.
"It's not a life sentence," Knight emphasized. "We think that with proper intervention and training, you could get improvement in both behavioral and physiological indices."
Kishiyama, Knight, Boyce and their colleagues selected 26 children ages 9 and 10 from a group of children in the WINKS study. Half were from families with low incomes and half from families with high incomes. For each child, the researchers measured brain activity while he or she was engaged in a simple task: watching a sequence of triangles projected on a screen. The subjects were instructed to click a button when a slightly skewed triangle flashed on the screen.
The researchers were interested in the brain's very early response - within as little as 200 milliseconds, or a fifth of a second - after a novel picture was flashed on the screen, such as a photo of a puppy or of Mickey and Minnie Mouse.
"An EEG allows us to measure very fast brain responses with millisecond accuracy," Kishiyama said.
The researchers discovered a dramatic difference in the response of the prefrontal cortex not only when an unexpected image flashed on the screen, but also when children were merely watching the upright triangles waiting for a skewed triangle to appear. Those from low socioeconomic environments showed a lower response to the unexpected novel stimuli in the prefrontal cortex that was similar, Kishiyama said, to the response of people who have had a portion of their frontal lobe destroyed by a stroke.
"When paying attention to the triangles, the prefrontal cortex helps you process the visual stimuli better. And the prefrontal cortex is even more involved in detecting novelty, like the unexpected photographs," he said. But in both cases, "the low socioeconomic kids were not detecting or processing the visual stimuli as well. They were not getting that extra boost from the prefrontal cortex."
"These kids have no neural damage, no prenatal exposure to drugs and alcohol, no neurological damage," Kishiyama said. "Yet, the prefrontal cortex is not functioning as efficiently as it should be. This difference may manifest itself in problem solving and school performance."
The researchers suspect that stressful environments and cognitive impoverishment are to blame, since in animals, stress and environmental deprivation have been shown to affect the prefrontal cortex. UC Berkeley's Marian Diamond, professor emeritus of integrative biology, showed nearly 20 years ago in rats that enrichment thickens the cerebral cortex as it improves test performance. And as Boyce noted, previous studies have shown that children from poor families hear 30 million fewer words by the time they are four than do kids from middle-class families.
"In work that we and others have done, it really looks like something as simple and easily done as talking to your kids" can boost prefrontal cortex performance, Boyce said.
"We are certainly not blaming lower socioeconomic families for not talking to their kids - there are probably a zillion reasons why that happens," he said. "But changing developmental outcomes might involve something as accessible as helping parents to understand that it is important that kids sit down to dinner with their parents, and that over the course of that dinner it would be good for there to be a conversation and people saying things to each other."
"The study is suggestive and a little bit frightening that environmental conditions have such a strong impact on brain development," said Silvia Bunge, UC Berkeley assistant professor of psychology who is leading the intervention studies on prefrontal cortex development in teenagers by using functional magnetic resonance imaging (fMRI).
Boyce's UBC colleague, Adele Diamond, showed last year that 5- and 6-year-olds with impaired executive functioning, that is, poor problem solving and reasoning abilities, can improve their academic performance with the help of special activities, including dramatic play.
Bunge hopes that, with fMRI, she can show improvements in academic performance as a result of these games, actually boosting the activity of the prefrontal cortex.
"People have tried for a long time to train reasoning, largely unsuccessfully," Bunge said. "Our question is, 'Can we replicate these initial findings and at the same time give kids the tools to succeed?'"
University of California - Berkeley
Science News and Science Current Events Tag Cloud
This tag cloud is a visual representation of term frequencies of random science news topics with common terms grouped together and emphasized by their display size.
Sleeping Sickness Pathogens Medulloblastoma Algal Blooms Syphilis Medical Imaging Ecosystem Polyphenols Neuroticism Migraine Coffee Fatty Acid Rice Stroke Chimpanzees Growth Hormone Cesarean Amino Acids Neurotransmitter Endothelial Cells Genetic Mutation Human Papillomavirus Estrogen Receptor Atrial Fibrillation Drug Addiction
See More: Science News Tags
Prefrontal Cortex Current Events and Prefrontal Cortex News RSSMIT: Long-distance brain waves focus attention
Just as our world buzzes with distractions - from phone calls to e-mails to tweets - the neurons in our brain are bombarded with messages.
Brain activation can predict the strategies people use to make risky decisions
Watching people's brains in real time as they handle a set of decision-making problems can reveal how different each person's strategy can be, according to neuroscientists at the Duke University Medical Center.
Use science to convince teens a sober prom is better, AAAS says
This is the time of year when even teens who have never tried a drop of alcohol may be tempted. Middle and high school proms and graduation are big events and there will be multiple parties to attend and a wide array of opportunities for alcohol to be served.
Brain's problem-solving function at work when we daydream
A new University of British Columbia study finds that our brains are much more active when we daydream than previously thought.
Flow of potassium into cells implicated in schizophrenia
A study on schizophrenia has implicated machinery that maintains the flow of potassium in cells and revealed a potential molecular target for new treatments.
Genetic variant impairs communication within the brain
For some time now it has been known that certain hereditary factors enhance the risk of schizophrenia or a manic-depressive disorder.
Adult brain processes fractions 'effortlessly'
Although fractions are thought to be a difficult mathematical concept to learn, the adult brain encodes them automatically without conscious thought.
Activation of the prefrontal cortex improves working memory
Psychologists and neurologists invest considerable effort in the study of working memory. In terms of information retention, there is a difference between long-term memory, which is affected in diseases such as Alzheimer, and short-term or working memory, which allows us to make immediate decisions or structure a discourse.
A mother's criticism causes distinctive neural activity among formerly depressed
Formerly depressed women show patterns of brain activity when they are criticized by their mothers that are distinctly different from the patterns shown by never depressed controls, according to a new study from Harvard University.
The Genetics of Fear: Study Suggests Specific Genetic Variations Contribute to Anxiety Disorders
Polymorphisms are variations in genes which can result in changes in the way a particular gene functions and thus may be associated with susceptibility to common diseases.
More Prefrontal Cortex Current Events and Prefrontal Cortex News Articles
 |
The Prefrontal Cortex, Fourth Edition by Joaquin Fuster (Author), Joaquin Fuster (Editor) This is the completely revised and updated fourth edition of the undisputed classic on the prefrontal cortex. This area of the brain is the main executive center of cognitive function, and one of the seats of primate and human intelligence. This book is a unique exercise in analysis and synthesis of our knowledge on the subject, from a vast empirical foundation built by five generations of clinicians and neuroscientists. Previous editions of this text have guided the work of innumerable researchers worldwide; their findings are now in the substance of this new edition. * Written by an award-winning author who discovered "memory cells"-the physiological substrate of working memory * Provides an in-depth examination of the contributions of every relevant methodology, from... |
 |
The Prefrontal Cortex, Fourth Edition by Academic Press This is the completely revised and updated fourth edition of the undisputed classic on the prefrontal cortex. This area of the brain is the main executive center of cognitive function, and one of the seats of primate and human intelligence. This book is a unique exercise in analysis and synthesis of our knowledge on the subject, from a vast empirical foundation built by five generations of clinicians and neuroscientists. Previous editions of this text have guided the work of innumerable researchers worldwide; their findings are now in the substance of this new edition. * Written by an award-winning author who discovered "memory cells"-the physiological substrate of working memory * Provides an in-depth examination of the contributions of every relevant methodology, from... |
 |
Prefrontal Cortex: From Synaptic Plasticity to Cognition by Satoru Otani (Editor) Universite de Paris VI, France. Provides an interdisciplinary view of the function of the anterior portion of the frontal lobe in rodents, humans, and primates. Addresses membrane properties of prefrontal neurons, cognitive psychology, the role of dopamine in cognition, and more. Halftone illustrations. Expanded-outline format. |
 |
The Prefrontal Cortex: Executive and Cognitive Functions by A. C. Roberts (Editor), T. W. Robbins (Editor), L. Weiskrantz (Editor) The prefrontal cortex, one of the most important areas of research in contemporary neuropsychology, appears to be linked with executive processes affecting many diverse areas of cognition, including working memory, information processing, behavioral organization, and attention. This state-of-the-art account of our knowledge of the prefrontal cortex brings together contributions from some of the world's leading researchers on the subject. The authors discuss the many recent theoretical and technical advances in the field--from advances in our understanding of the neural architecture of the prefrontal cortex to the use of functional neuroimaging and from new ideas about the relationships between neuronal activity and behavior to comparisons between human and non-human primate cognition. One... |
 |
Prefrontal Cortex: From Synaptic Plasticity to Cognition by Springer Universite de Paris VI, France. Provides an interdisciplinary view of the function of the anterior portion of the frontal lobe in rodents, humans, and primates. Addresses membrane properties of prefrontal neurons, cognitive psychology, the role of dopamine in cognition, and more. Halftone illustrations. Expanded-outline format. |
 |
Development of the Prefrontal Cortex: Evolution, Neurobiology, and Behavior by Norman A. Krasnegor (Editor), G. Reid Lyon (Editor), Patricia S. Goldman-Rakic (Editor) Prominent investigators in the fields of neuroscience and behavior come together in this volume to examine the brain's prefrontal cortex. Exploring evolutionary issues, neurobiology, neuropsychology, and neuropathology, these experts advance the knowledge of the growth, structure, and function of this brain region as it relates to human behavior and development. Based on multiple human and primate research studies, the book sheds light on typical brain growth and simultaneously describes the functional and developmental consequences of acquired and developmental damage to the prefontal cortex. The authors address specific types of brain injuries and lesions, explaining how these factors can affect cognitive, behavioral, and social functions such as memory, attention, decision making, and... |
|
Structure and Functions of the Human Prefrontal Cortex (Annals of the New York Academy of Sciences ; Vol. 769) by Jordan Grafman (Editor), Keith J. Holyoak (Editor), Francois Boller (Editor) This volume contains papers that deal with the structure and functions of the human prefrontal cortex, including a review of recent work on its neuroanatomy, neurochemistry, neural development and degeneration, and neuropsychology. In addition, papers focus on novel and competing theories of human prefrontal cortical functions, utilising convergent evidence from the fields of comparative neuropsychology, cognitive sciences, artificial intelligence, neuropsychiatry, and cognitive neuropsychology. The book provides a broad overview on the subject of the human prefrontal cortex and integration of human prefrontal cortical functioning, and offer in-depth comparisons of alternative testable theories of human prefrontal cortical functions. | |
|
Amygdala, prefrontal cortex are keys to anxiety: bringing that knowledge to neuroimaging should help pinpoint diagnosis, treatment response.(Adult Psychiatry)(Disease/Disorder ... An article from: Clinical Psychiatry News by Damian McNamara (Author) This digital document is an article from Clinical Psychiatry News, published by Thomson Gale on February 1, 2007. The length of the article is 679 words. The page length shown above is based on a typical 300-word page. The article is delivered in HTML format and is available in your Amazon.com Digital Locker immediately after purchase. You can view it with any web browser. Citation Details Title: Amygdala, prefrontal cortex are keys to anxiety: bringing that knowledge to neuroimaging should help pinpoint diagnosis, treatment response.(Adult Psychiatry)(Disease/Disorder overview) Author: Damian McNamara Publication: Clinical Psychiatry News (Magazine/Journal) Date: February 1, 2007 Publisher: Thomson Gale Volume: 35 Issue: 2 Page: 17(1) Article Type:... | |
 |
Monoaminergic Modulation of Cortical Excitability by Springer Monoaminergic Modulation of Cortical Excitability serves as an integrative and comprehensive comparison of the diverse and complex modulatory action of dopamine, noradrenaline, and serotonin receptors in the cortex. The volume is organized into several sections offering a broad spectrum of opinions on how the monoamine systems affect cortical function from a cellular/sub-cellular level to a system level. The complexity of these interactions are discussed in light of recent data showing how disruption of these systems dramatically affects the memory formation and information processing in the cortex. About the Editors: |
![Anterior prefrontal cortex and the recollection of contextual information [An article from: Neuropsychologia]](http://ecx.images-amazon.com/images/I/51PPQSTG2AL._SL160_.jpg) |
Anterior prefrontal cortex and the recollection of contextual information [An article from: Neuropsychologia] by J.S. Simons (Author), A.M. Owen (Author), P.C. Fletcher (Author), P. Burgess (Author) This digital document is a journal article from Neuropsychologia, published by Elsevier in 2005. The article is delivered in HTML format and is available in your Amazon.com Media Library immediately after purchase. You can view it with any web browser. Description: Recollective memory can involve the retrieval of many different kinds of contextual information, including where and when an event took place, as well as our thoughts and feelings at the time. The brain regions associated with this ability were examined in an event-related fMRI experiment, where participants made decisions about words or famous faces which were presented either on the left or right of a monitor screen. Subsequently, the studied words and faces were again presented and participants underwent fMRI... |
| © 2009 BrightSurf.com |