Chapter 13. Memory, Learning, and Development
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By Bruce Bower Provocative evidence that certain memory exercises make people smarter has sparked the rise of online brain-training programs such as Lumosity. But at least one type of brain training may not work as advertised, a new study finds. As expected, practicing improved volunteers’ performance on tests of memory and the ability to locate items quickly in busy scenes, say psychologist Thomas Redick of Indiana University Purdue University Columbus and his colleagues. That improvement did not, however, translate into higher scores on tests of intelligence and multitasking, the researchers report in the May Journal of Experimental Psychology: General. Redick’s investigation is part of a growing scientific debate about brain training, which is promoted by some companies as having a variety of mental benefits. Some researchers say that extensive instruction and training on memory tasks can indeed fortify reasoning and problem solving. Others are skeptical that vigorous memory sessions produce such wide-ranging effects. The dispute feeds into a longstanding scientific controversy about whether enriched environments can increase intelligence, as measured on IQ tests. What’s not up for debate is that many people feel smarter after brain training. In the new study, 10 of 23 individuals who completed memory sessions said that the program helped them to think, multitask and focus better in daily life. But the scientists say that even if some participants performed daily tasks better after memory training, they may simply have tried harder or felt better about their efforts due to a belief that training had strengthened their minds. © Society for Science & the Public 2000 - 2013
Keyword: Learning & Memory
Link ID: 18140 - Posted: 05.11.2013
By John McCarthy Into brains of newborn mice, researchers implanted human “progenitor cells.” These mature into a type of brain cell called astrocytes (see below). They grew into human astrocytes, crowding out mouse astrocytes. The mouse brains became chimeras of human and mouse, with the workhorse mouse brain cells – neurons – nurtured by billions of human astrocytes. Neuroscience is only beginning to discover what astrocytes do in brains. One job that is known is that they help neurons build connections (synapses) with other neurons. (Firing neurotransmitter molecules across synapses is how neurons communicate.) Human astrocytes are larger and more complex than those of other mammals. Humans’ unique brain capabilities may depend on this complexity. Human astrocytes certainly inspired the mice. Their neurons did indeed build stronger synapses. (Perhaps this was because human astrocytes signal three times faster than mouse astrocytes do.) Mouse learning sharpened, too. On the first try, for instance, altered mice perceived the connection between a noise and an electric shock (a standard learning test in mouse research). Normal mice need a few repetitions to get the idea. Memories of the doctored mice were better too: they remembered mazes, object locations, and the shock lessons longer. The reciprocal pulsing of billions of human and mouse brain cells inside a mouse skull is a little creepy. Imagine one of these hybrid mice exploring your living room. Would you feel like a Stone Age tribesman observing a toy robot? Does the thing think? © 2013 Scientific American
By James Gallagher Health and science reporter, BBC News Flu during pregnancy may increase the risk of the unborn child developing bipolar disorder later in life, research suggests. A study of 814 expectant women, published in JAMA Psychiatry, showed that infection made bipolar four times more likely. The overall risk remained low, but it echoes similar findings linking flu and schizophrenia. Experts said the risks were small and women should not worry. Bipolar leads to intense mood swings, which can last months, ranging from depression and despair to manic feelings of joy, overactivity and loss of inhibitions. Researchers at the Columbia University Medical Center identified a link between the condition, often diagnosed during late teens and twenties, and experiences in the womb. In their study looking at people born in the early 1960s, bipolar disorder was nearly four times as common in people whose mothers caught flu during pregnancy. The condition affects about one in 100 people. The lead researcher, Prof Alan Brown, estimated that influenza infection during pregnancy could lead to a 3-4% chance of bipolar disorder in the resulting children. However, in the vast majority of cases of bipolar disorder there would no history of flu. BBC © 2013
By MARILYNN MARCHIONE DEERFIELD, Ill. (AP) — Baxter International Inc. says that a blood product it was testing failed to slow mental decline or to preserve physical function in a major study of 390 patients with mild to moderate Alzheimer’s disease. The company says that people who received 18 months of infusions with its drug, Gammagard, fared no better than others given infusions of a dummy solution. Gammagard is immune globulin, natural antibodies culled from donated blood. Researchers thought these antibodies might help remove amyloid, the sticky plaque that clogs patients’ brains, sapping memory and ability to think. Patients with moderate disease and those with a gene that raises risk of Alzheimer’s who were taking the higher of two doses in the study seemed to benefit, although the study was not big enough to say for sure. ‘‘The study missed its primary endpoints, however we remain interested by the prespecified sub-group analyses’’ in groups that seemed to benefit, Ludwig Hantson, president of Baxter’s BioScience business, said in a statement. Gammagard is already sold to treat some blood disorders, and the results of the Alzheimer’s study do not affect those uses. About 35 million people worldwide have dementia, and Alzheimer’s is the most common type. In the U.S., about 5 million have Alzheimer's. Current medicines such as Aricept and Namenda just temporarily ease symptoms. There is no known cure. © 2013 NY Times Co.
Link ID: 18131 - Posted: 05.08.2013
By Gisela Telis, I’ve seen friends fret over the purported link between aluminum and Alzheimer’s disease and have often wondered if their fears are founded on fact. Should they give up aluminum pans or aluminum-containing antiperspirants? I’ve always heard that aluminum’s health dangers are just hype. So what’s the real deal? The connection between aluminum and Alzheimer’s disease is less a myth than a longstanding scientific controversy. It began in 1965, when researchers discovered that injecting rabbits’ brains with aluminum caused them to develop neurofibrillary tangles, the twisted proteins found in brain cells of patients with Alzheimer’s disease, a degenerative brain disorder that destroys memory and cognition. The finding spurred a rush of research. Just eight years later, a Canadian group studying brain tissue from deceased Alzheimer’s patients found that certain parts of their brains had two to three times more aluminum than a normal brain. By 1980, Daniel Perl and Arnold Brody had managed to actually peer inside human tangle-bearing brain cells — and found aluminum there, too. “That really changed the whole complexion of the thing,” recalls Perl, now a professor of pathology in the Uniformed Services University of the Health Sciences in Bethesda. “I was getting called all the time, because there was so much public interest.” Despite the rise in interest, no one could figure out what this meant for human health. Part of the problem was that scientific techniques were — and still are — too imperfect to provide an answer. Whether they were studying brain cells or conducting population-wide epidemiological studies that tracked aluminum exposure and Alzheimer’s risk, researchers lacked the tools to get very precise or conclusive results. © 1996-2013 The Washington Post
By Dina Fine Maron Almost a decade after manufacturers stopped using certain chemical flame retardants in furniture foam and carpet padding, many of the compounds still lurk in homes. New work to be presented today reaffirms that the chemicals may also still be hurting young children who were exposed before they were born. Researchers investigating the health impacts of prenatal exposure to flame retardants collected blood samples from 309 pregnant women early in their second trimester. Spikes in the levels of one class of flame retardant, polybrominated diphenyl ethers (PBDEs) correlated with behavior and cognition difficulties during early childhood. The researchers tracked children through the first five years of their lives, looking at a battery of tests for IQ and behavior. They found that children of mothers who had high PBDE levels during their second trimester showed cognition deficits when the children were five years old as well as higher rates of hyperactivity at ages two to five. If the mother’s blood had a 10-fold increase in PBDEs, the average five-year-old had about a four-point IQ deficit. “A four-point IQ difference in an individual child may not be perceivable in…ordinary life. However, in a population, if many children are affected, the social and economic impact can be huge due to the shift of IQ distribution and productivity,” says lead author Aimin Chen, an assistant professor of environmental health at the University of Cincinnati College of Medicine. The findings, based on women and children from Cincinnati, will be presented May 6 at the annual meeting of the Pediatric Academic Societies in Washington, D.C. The unpublished results have been submitted to a peer-reviewed journal, but the paper has not yet been accepted. © 2013 Scientific American
By BILL PENNINGTON BOSTON — The drumbeat of alarming stories linking concussions among football players and other athletes to brain disease has led to a new and mushrooming American phenomenon: the specialized youth sports concussion clinic, which one day may be as common as a mall at the edge of town. In the last three years, dozens of youth concussion clinics have opened in nearly 35 states — outpatient centers often connected to large hospitals that are now filled with young athletes complaining of headaches, amnesia, dizziness or problems concentrating. The proliferation of clinics, however, comes at a time when there is still no agreed-upon, established formula for treating the injuries. “It is inexact, a science in its infancy,” said Dr. Michael O’Brien of the sports concussion clinic at Boston Children’s Hospital. “We know much more than we once did, but there are lots of layers we still need to figure out.” Deep concern among parents about the effects of concussions is colliding with the imprecise understanding of the injury. To families whose anxiety has been stoked by reports of former N.F.L. players with degenerative brain disease, the new facilities are seen as the most expert care available. That has parents parading to the clinic waiting rooms. The trend is playing out vividly in Boston, where the phone hardly stops ringing at the youth sports concussion clinic at Massachusetts General Hospital. “Parents call saying, ‘I saw a scary report about concussions on Oprah or on the ‘Doctors’ show or Katie Couric’s show,’ ” Dr. Barbara Semakula said, describing a typical day at the clinic. “Their child just hurt his head, and they’ve already leapt to the worst possible scenarios. It’s a little bit of a frenzy out there.” © 2013 The New York Times Company
By John Horgan What is mental illness? Schizophrenia? Autism? Bipolar disorder? Depression? Since the 1950s, the profession of psychiatry has attempted to provide definitive answers to these questions in the Diagnostic and Statistical Manual of Mental Disorders. Often called The Bible of psychiatry, the DSM serves as the ultimate authority for diagnosis, treatment and insurance coverage of mental illness. Now, in a move sure to rock psychiatry, psychology and other fields that address mental illness, the director of the National Institutes of Mental Health has announced that the federal agency–which provides grants for research on mental illness–will be “re-orienting its research away from DSM categories.” Thomas Insel’s statement comes just weeks before the scheduled publication of the DSM-V, the fifth edition of the Diagnostic and Statistical Manual. Insel writes: “While DSM has been described as a ‘Bible’ for the field, it is, at best, a dictionary, creating a set of labels and defining each. The strength of each of the editions of DSM has been ‘reliability’–each edition has ensured that clinicians use the same terms in the same ways. The weakness is its lack of validity. Unlike our definitions of ischemic heart disease, lymphoma, or AIDS, the DSM diagnoses are based on a consensus about clusters of clinical symptoms, not any objective laboratory measure. In the rest of medicine, this would be equivalent to creating diagnostic systems based on the nature of chest pain or the quality of fever. Indeed, symptom-based diagnosis, once common in other areas of medicine, has been largely replaced in the past half century as we have understood that symptoms alone rarely indicate the best choice of treatment. Patients with mental disorders deserve better.” © 2013 Scientific American
Alla Katsnelson People who use a ‘brain-workout’ program for just 10 hours have a mental edge over their peers even a year later, researchers report today in PLoS ONE1. The search for a regimen of mental callisthenics to stave off age-related cognitive decline is a booming area of research — and a multimillion-dollar business. But critics argue that even though such computer programs can improve performance on specific mental tasks, there is scant proof that they have broader cognitive benefits. For the study, adults aged 50 and older played a computer game designed to boost the speed at which players process visual stimuli. Processing speed is thought to be “the first domino that falls in cognitive decline”, says Fredric Wolinsky, a public-health researcher at the University of Iowa in Iowa City, who led the research. The game was developed by academic researchers but is now sold under the name Double Decision by Posit Science, based in San Francisco, California. (Posit did not fund the study.) Players are timed on how fast they click on an image in the centre of the screen and on others that appear around the periphery. The program ratchets up the difficulty as a player’s performance improves. Participants played the training game for 10 hours on site, some with an extra 4-hour ‘booster’ session later, or for 10 hours at home. A control group worked on computerized crossword puzzles for 10 hours on site. Researchers measured the mental agility of all 621 subjects before the brain training began, and again one year later, using eight well-established tests of cognitive performance. © 2013 Nature Publishing Group
Chris Palmer NF-kB activation in neurons in the hypothalamus increases with age (left column), while the total number of neurons (middle column) and the total number of all cell types in the hypothalamus (right column) is maintained at a relatively steady rate across age groups. The area of the brain that controls growth, reproduction and metabolism also kick-starts ageing, according to a study published today in Nature1. The finding could lead to new treatments for age-related illnesses, helping people to live longer. Dongsheng Cai, a physiologist at Albert Einstein College of Medicine in New York, and his colleagues tracked the activity of NF-κB — a molecule that controls DNA transcription and is involved in inflammation and the body's response to stress — in the brains of mice. They found that the molecule becomes more active in the brain area called the hypothalamus as a mouse grows older. Further tests suggested that NF-κB activity helps to determine when mice display signs of ageing. Animals lived longer than normal when they were injected with a substance that inhibited the activity of NF-κB in immune cells called microglia in the hypothalamus. Mice that received a substance to stimulate the activity of NF-κB died earlier. “We have provided scientific evidence for the concept that systemic ageing is influenced by a particular tissue in the body,” says Cai. Health and well-being © 2013 Nature Publishing Group
By NICHOLAS BAKALAR A large new study confirms that sticking to the Mediterranean diet — fish, poultry, vegetables and fruit, with minimal dairy foods and meat — may be good for the brain. Researchers prospectively followed 17,478 mentally healthy men and women 45 and older, gathering data on diet from food questionnaires, and testing mental function with a well-validated six-item screening tool. They ranked their adherence to the Mediterranean diet on a 10-point scale, dividing the group into low adherence and high adherence. The study was published April 30 in the journal Neurology. During a four-year follow-up, 1,248 people became cognitively impaired. But those with high adherence to the diet were 19 percent less likely to be among them. This association persisted even after controlling for almost two dozen demographic, environmental and vascular risk factors, and held true for both African-Americans and whites. The study included 2,913 people with Type 2 diabetes, but for them adherence to the diet had no effect on the likelihood of becoming impaired. The lead author, Dr. Georgios Tsivgoulis, an assistant professor of neurology at the University of Athens, said that this is the largest study of its kind. The Mediterranean diet, he added, “has many benefits — cardiovascular, cancer risk, anti-inflammatory, central nervous system. We’re on the tip of the iceberg, and trying to understand what is below.” Copyright 2013 The New York Times Company
By Meghan Rosen A child who is good at learning math may literally have a head for numbers. Kids’ brain structures and wiring are associated with how much their math skills improve after tutoring, researchers report April 29 in the Proceedings of the National Academy of Sciences. Certain measures of brain anatomy were even better at judging learning potential than traditional measures of ability such as IQ and standardized test results, says study author Kaustubh Supekar of Stanford University. These signatures include the size of the hippocampus — a string bean–shaped structure involved in making memories — and how connected the area was with other parts of the brain. The findings suggest that kids struggling with their math homework aren’t necessarily slacking off, says cognitive scientist David Geary of the University of Missouri in Columbia. “They just may not have as much brain region devoted to memory formation as other kids.” The study could give scientists clues about where to look for sources of learning disabilities, he says. Scientists have spent years studying brain regions related to math performance in adults, but how kids learn is still “a huge question,” says Supekar. He and colleagues tested IQ and math and reading performance in 24 8- and 9-year-olds, then scanned their brains in an MRI machine. The scans measured the sizes of different brain structures and the connections among them. “It’s like creating a circuit diagram,” says study leader Vinod Menon, also of Stanford. © Society for Science & the Public 2000 - 2013
Keyword: Learning & Memory
Link ID: 18094 - Posted: 04.30.2013
By VATSAL G. THAKKAR IN the spring of 2010, a new patient came to see me to find out if he had attention-deficit hyperactivity disorder. He had all the classic symptoms: procrastination, forgetfulness, a propensity to lose things and, of course, the inability to pay attention consistently. But one thing was unusual. His symptoms had started only two years earlier, when he was 31. Though I treat a lot of adults for attention-deficit hyperactivity disorder, the presentation of this case was a violation of an important diagnostic criterion: symptoms must date back to childhood. It turned out he first started having these problems the month he began his most recent job, one that required him to rise at 5 a.m., despite the fact that he was a night owl. The patient didn’t have A.D.H.D., I realized, but a chronic sleep deficit. I suggested some techniques to help him fall asleep at night, like relaxing for 90 minutes before getting in bed at 10 p.m. If necessary, he could take a small amount of melatonin. When he returned to see me two weeks later, his symptoms were almost gone. I suggested he call if they recurred. I never heard from him again. Many theories are thrown around to explain the rise in the diagnosis and treatment of A.D.H.D. in children and adults. According to the Centers for Disease Control and Prevention, 11 percent of school-age children have now received a diagnosis of the condition. I don’t doubt that many people do, in fact, have A.D.H.D.; I regularly diagnose and treat it in adults. But what if a substantial proportion of cases are really sleep disorders in disguise? © 2013 The New York Times Company
By Russell Foster "Making teens start school in the morning is ‘cruel,’ brain doctor claims." So declared a British newspaper headline in 2007 after a talk I gave at an academic conference. One disbelieving reader responded: "This man sounds brain-dead." That was a typical reaction to work I was reporting at the time on teenage sleep patterns and their effect on performance at school. Six years on, there is growing acceptance that the structure of the academic day needs to take account of adolescent sleep patterns. The latest school to adopt a later start time is the UCL Academy in London; others are considering following suit. So what are the facts about teenage slumber, and how should society adjust to these needs? The biology of human sleep timing, like that of other mammals, changes as we age. This has been shown in many studies. As puberty begins, bedtimes and waking times get later. This trend continues until 19.5 years in women and 21 in men. Then it reverses. At 55 we wake at about the time we woke prior to puberty. On average this is two hours earlier than adolescents. This means that for a teenager, a 7 a.m. alarm call is the equivalent of a 5 a.m. start for people in their 50s. Precisely why this is so is unclear, but the shifts correlate with hormonal changes at puberty and the decline in those hormones as we age. However, biology is only part of the problem. Additional factors include a more relaxed attitude to bedtimes by parents, a general disregard for the importance of sleep, and access to TVs, DVDs, PCs, gaming devices, cellphones, and so on, all of which promote alertness and eat into time available for sleep. © 2013 The Slate Group, LLC.
by Emily Underwood In the cartoon series named after them, Pinky and the Brain, two laboratory mice genetically enhanced to increase their intelligence plot to take over the world—and fail each time. Perhaps their creators hadn't tweaked the correct gene. Researchers have now found a genetic mutation that causes mammalian neural tissue to expand and fold. The discovery may help explain why humans evolved more elaborate brains than mice, and it could suggest ways to treat disorders such as autism and epilepsy that arise from abnormal neural development. In mice and humans alike, the cerebral cortex—the outermost layer of brain tissue associated with high-level functions such as memory and decision-making—starts out as a spherical sheet of tissue made up of only neural stem cells. As these stem cells divide, the cortex increases its surface area, expanding like an inflating balloon, says neuroscientist Victor Borrell of the Institute of Neurosciences of Alicante in Spain. Unlike the small, smooth mouse brain, however, the uppermost layers of tissue in the human brain cram millions of neurons into specialized folds and furrows responsible for complex tasks such as language and thought. Because the human cerebral cortex is generally considered "special," some scientists have hypothesized that the genes that govern its development of cortical folds and furrows are also unique to humans, Borrell says. In studies of neural development in mice, Stahl found that TRNP1 produces a protein that determines whether neural stem cells self-replicate, leading to a balloonlike expansion of cortical surface area, or whether they differentiate into a plethora of intermediate stem cell types and neurons, thickening the cortex and forming more complex brain structures. Based on that discovery, the team hypothesized that varying levels of the gene's expression in mice and humans might account for the varying levels of cortical thickness and different shapes between the two species. © 2010 American Association for the Advancement of Science
by Dr. Claire McCarthy April is Autism Awareness Month--and if there's anything that we need when it comes to autism, it's awareness. We need people to be aware of this condition that affects a staggering 1 in 50 children, so that we can understand what causes it, and find ways to prevent it. And we need people to be aware of the signs of autism--because getting help early can make a real difference. Many children aren't diagnosed with autism until they get to preschool, or sometimes even later--and that means important time is lost. The signs of autism can be present in toddlers--and when we find it then, we can get help to those children and their families right away. The trick is in asking the right questions--and acting on the answers. In the practice where I work, as in many other practices, we ask parents to fill out questionnaires about the behavior and development of their children. At the 18 month and 24 month visits, we ask parents to fill out one called the MCHAT (Modified Checklist for Autism in Toddlers)--that's the tool we've chosen to help us look for autism. It's a list of questions that parents answer yes or no to, questions about how their child acts, plays and interacts with other people. While all the questions on the MCHAT are important, there are six that are most important: Does your child take an interest in other children? Does your child ever use his finger to point at or ask for something? Does your child ever bring objects over to you to show you something? Does your child imitate you? Does your child respond to his name when you call? If you point at a toy across the room, does your child look at it? © 2013 NY Times Co.
Link ID: 18081 - Posted: 04.27.2013
By Karen Rowan and MyHealthNewsDaily Children at an increased risk of autism may have abnormal structures in the placenta that can be detected at birth, a new study finds. The findings suggest behavioral interventions aimed at social and motor skill development in these children could be started right away, the researchers said. Studies have shown that such interventions are more effective in children with autism when they are started earlier. It's much too early to say that an examination of the placenta could be used as a definitive test for autism at birth, said study researcher Dr. Harvey Kliman, director of Reproductive and Placental Research at the Yale University School of Medicine. Autism spectrum disorders are typically diagnosed when children are ages 3 or 4, or even older. However, if these structures were found upon a child's birth and interventions were started, the child might benefit greatly if they did turn out to have autism, while there would be little downside if a child turned out not to have autism -- it's unlikely they would be harmed by the effort, Kliman said. In the study, Kliman and his colleagues collected samples of placenta tissue from 117 children born to families who already had a child with autism, and compared them with placentas from 100 babies born into families in which no older children had autism. The researchers, who didn't know which placentas had come from each group of children, examined samples of the placentas under microscopes. © 2013 Scientific American
Karen Ravn Birds of a feather may flock together, but do birds that flock together develop distinct cultures? Two studies published today in Science1, 2 find strong evidence that, at the very least, monkeys that troop together and whales that pod together do just that. And they manage it in the same way that humans do: by copying and learning from each other. A team led by Erica van de Waal, a primate psychologist at the University of St Andrews, UK, created two distinct cultures — 'blue' and 'pink' — among groups of wild vervet monkeys (Chlorocebus aethiops) in South Africa1. The researchers trained two sets of monkeys to eat maize (corn) dyed one of those two colours but eschew maize dyed the other colour. The scientists then waited to see how the groups behaved when newcomers — babies and migrating males — arrived. Both sets of newcomers seemed to follow social cues when selecting their snacks. Baby monkeys ate the same colour maize as their mothers. Seven of the ten males that migrated from one colour culture to another adopted the local colour preference the first time that they ate any maize. The trend was even stronger when they first fed with no higher-ranking monkey around, with nine of the ten males choosing the locally preferred variety. The only immigrant to buck this trend was a monkey who assumed the top rank in his new group as soon as he got there — and he may not have given a fig what anyone else ate. “The take-home message is that social learning — learning from others rather than through individual trial and error — is a more potent force in shaping wild animals’ behaviour than has been recognized so far,” says Andrew Whiten, an evolutionary and developmental psychologist at St Andrews and co-author of the paper. © 2013 Nature Publishing Group
By Meghan Holohan Need to remember some important facts for that big presentation at work? Clench your right hand while preparing to remember. When giving that talk, ball up your left hand and you’ll call to mind those details, no problem. That’s the finding from a new study authored by Ruth Propper, an associate professor and director of the cerebral lateralization laboratory at Montclair State University. Propper has long been intrigued by how body movements impact how the brain works. While most people realize that the brain influences the body (the brain tells your arm there is an itch, and you feel it), less is understood about how the body sways the brain. Past research suggests that clenching our hands can evoke emotions. When people ball up their right hands, for example, the left sides of their brains become more active, causing what’s known as “approach emotions,” feelings such as happiness or excitement. By squeezing the left hand, people engage the right side of the brain, which controls “withdrawal emotions” such as introversion, fear, or anxiety. (It probably seems like these might be less useful, but they come in handy in dangerous situations.) Propper theorized that if clenching hands impacted feelings, these gestures might influence the brain in other ways. © 2013 NBCNews.com
By KATIE THOMAS With the diagnosis of autism on the rise and drug companies facing major setbacks in developing successful treatments, the University of California, Los Angeles will lead a $9 million effort financed by the National Institute of Mental Health to find effective drugs, officials said Wednesday. Under a contract with the institute, U.C.L.A. will form a network of researchers at other academic centers that will try to identify promising new and older drug compounds quickly, and conduct early tests to see if they merit additional investment. The program, part of the “Fast Fail” initiative at the institute, aims to determine within weeks whether a drug works, rather than the years it traditionally takes to evaluate a new drug. “The whole idea is just getting much better in these early phases at identifying drugs that are going to be efficacious and safe, and thereby greatly speeding the development of effective new therapies and reducing the overall cost,” said Dr. James McCracken, who is leading the effort at U.C.L.A. as director of the division of child and adolescent psychiatry at the Semel Institute for Neuroscience and Human Behavior. The number of diagnosed cases of autism, Asperger’s syndrome and related disorders in children has been growing in recent years, largely because of increased awareness. A recent report by the Centers for Disease Control and Prevention and the Health Resources and Services Administration concluded that one in 50 children aged 6 to 17 had been found to have autism or a related disorder, a 72 percent increase since 2007. Although more cases are being diagnosed, no drugs are approved to treat the core symptoms of the disorders, which are characterized by delays in developing effective communication and social skills. Other drugs often prescribed to people with the disorders treat difficult behaviors like aggressiveness, hyperactivity and irritability. © 2013 The New York Times Company
Link ID: 18070 - Posted: 04.25.2013