Neuroscience

ScienceDaily (June 26, 2012) — Rhode Island Hospital researcher Suzanne de la Monte, M.D., has found a link between brain insulin resistance (diabetes) and two other key mediators of neuronal injury that help Alzheimer’s disease (AD) to propagate. The research found that once AD is established, therapeutic efforts must also work to reduce toxin production in the brain.

The study, “Dysfunctional Pro-Ceramide, ER Stress, and Insulin/IGF Signaling Networks with Progression of Alzheimer’s Disease”, is published in the June 22, 2012, supplement of the Journal of Alzheimer’s Disease.

Alzheimer’s disease is one of the most common degenerative dementias, and more than 115 million new cases are projected worldwide in the next 40 years. There is clinical and experimental evidence that treatment with insulin or insulin sensitizer agents can enhance cognitive function and in some circumstances help slow the rate of cognitive decline in AD. Alzheimer’s and other neurodegenerative diseases destroy the brain until the patients finally succumb. In order to effectively halt the process of neurodegeneration, the forces that advance and perpetuate the disease, particularly with regard to the progressive worsening of brain insulin/IGF resistance, must be understood.

"Brain insulin resistance (diabetes) is very much like regular diabetes," de la Monte said. "Since the underlying problems continue to be just about the same, we believe that the development of new therapies would be applicable for all types of diabetes, including Alzheimer’s disease, which we refer to as Type III diabetes."

She continued, “This study points out that once AD is established, therapeutic efforts should target several different pathways — not just one. The reason is that a positive feedback loop gets going, making AD progress. We have to break the vicious cycle. Restoring insulin responsiveness and insulin depletion will help, but we need to reduce brain stress and repair the metabolic problems that cause the brain to produce toxins.”

Ultimately, these findings will help to expand ways to both detect and treat AD.

Growing evidence supports the concept that AD is fundamentally a metabolic syndrome that leads to abnormalities linked to brain insulin and insulin-like growth factor (IGF) resistance. In AD, brain insulin and IGF resistance and deficiencies begin early and worsen with severity of the disease. The rationale behind the progression of the disease is that insulin-resistance dysregulates lipid metabolism and promotes ceramide accumulation, thereby increasing inflammation and lipid metabolism, causing toxic ceramides to accumulate in the brain. The end result is increased stress that threatens the survival and function of neurons in the brain.

The present study was designed to gain a better understanding of how brain insulin resistance becomes progressive and contributes to the neurodegeneration in AD, focusing on the roles of ceramides and stress. The researchers studied the same brain samples used previously to demonstrate progressive impairments in brain insulin/IGF signaling with increasing severity of AD.

Source: Science Daily

June 26, 2012

The inexorable spread of Alzheimer’s disease through the brain leaves dead neurons and forgotten thoughts in its wake. Researchers at Linköping University in Sweden are the first to show how toxic proteins are transferred from neuron to neuron.

Two nerve cells, each about 10 micrometers large, are visible as shadows in this picture. From the beginning only the right one (yellow arrow) contained the toxic, red stained, oligomeric beta-amyloid. When these sick cells make contacts with the healthy, green labeled cells (black arrow), toxic beta-amyloid will spread through the neuronal projections (white arrow). Subsequently, also the green cell will become sick. Credit: Martin Hallbeck

Through experiments on stained neurons, the research team – under the leadership of Martin Hallbeck, associate professor of Pathology – has been able to depict the process of neurons being invaded by diseased proteins that are then passed on to nearby cells.

"The spread of Alzheimer’s, which can be studied in the brains of diseased patients, always follows the same pattern. But until now how and why this happens has not been understood," says Hallbeck, who along with his research group has now published their results in The Journal of Neuroscience.

The illness starts in the entorhinal cortex – a part of the cerebral cortex, and then spreads to the hippocampus. Both of these areas are important for memory. Gradually, pathological changes take place in more and more areas of the brain, while the patient becomes even sicker.

Two proteins have been identified in connection with Alzheimer’s: beta amyloid and tau. Normally tau is found in the axons – the outgrowths that connect between neurons – where it has a stabilising function, while beta amyloid seems to have a role in the synapses where the neurons transfer signal substances to each other. But in Alzheimer’s patients, something happens with these proteins; autopsies reveal abnormal accumulations of both.

Why they become abnormal is still unknown, but what is known is that it’s not the large accumulations, or plaques, that damage the neurons. Instead, smaller groups of beta amyloid – called oligomeres – seem to be the toxic form that gradually destroy the neurons and shrink the brain.

"We wanted to investigate whether these oligomeres can spread from neuron to neuron, something many researchers tried earlier but didn’t succeed," Hallbeck says.

The study was inaugurated with an experiment on neuron cultures, where researchers injected oligomeres stained with a phosphorescent red substance called TMR using a very thin needle. The next day the neighbouring, connected neurons were also red, which showed that the oligomeres had spread.

To test whether a sick neuron can “infect” others, they conducted a round of experiments with mature human neurons stained green and mixed with others that were red after having taken up stained oligomeres. After a day, approximately half of the green cells had been in contact with a few of the red ones. After two more days, the axons had lost their shape and organelles in the cell nucleus had started to leak.

"Gradually more and more of the green cells became sick. Those that hadn’t taken up the oligomeres, on the other hand, weren’t affected," Hallbeck says.

The study is a breakthrough in understanding Alzheimer’s and its progress. If a way of stopping the transfer can be found, it could lead to a more effective inhibitor against the disease.

Provided by Linköping University

Source: medicalxpress.com

June 26, 2012

A new video article in JoVE, the Journal of Visualized Experiments, describes a novel procedure to monitor brain function and aid in functional mapping of patients with diseases such as epilepsy. This procedure illustrates the use of pre-placed electrodes for cortical mapping in the brains of patients who are undergoing surgery to minimize the frequency of seizures. This technique, while invasive, provides real-time analysis of brain function at a much higher resolution than current technologies.

This image shows the implanted electrodes as they are mapped on the brain. Credit: Journal of Visualized Experiments

Typically, functional magnetic resonance imaging (fMRI) and electroencephalography (EEG) are used in neuroimaging studies but these techniques suffer from low temporal and spatial resolution. By using electrodes implanted in the brain of an epileptic patient already undergoing treatment, scientists can now image the brain with a much higher spatial resolution, lower signal interference, and a higher temporal resolution than fMRI or EEG.

The leading author of the study, Dr. Gerwin Schalk, from the New York State Department of Health and Albany Medical College, states, “Essentially, we have created a new imaging technique. Our procedure is innovative because it is prospective, meaning, it can image brain function as it occurs. Further, it does not require an expert to derive meaningful information concerning brain function.” He also notes that it was crucial for this procedure to be demonstrated in a video format. “The procedure is a very visual process. The ancillary information such as the spatial relationships of different components, the set-up of the hospital room, and the set-up of the equipment itself cannot be represented in a typical print article. The video capacities of JoVE were an excellent vehicle to demonstrate both the general set-up and the specific implementation of the mapping system.”

By relying on an epileptic patient’s neural implants, scientists gain an unprecedented insight into the brain’s function. Dr. Schalk’s procedure provides a technological advancement that can be applied in many ways, including stroke patient monitoring and rehabilitation, signal mapping and transduction for movement of prosthetic limbs, and enhancement of communication in individuals with paralysis of the vocal musculature. The JoVE video article provides a comprehensive demonstration of the new technique, from mapping the electrical implants to interpreting the tests in real time. JoVE editor Dr. Claire Standen emphasizes, “The new imaging technique demonstrated in this article is very important. There is a definite need for better, more accurate, imaging to monitor brain function. This technique can be applied to a wide range of clinical areas within the Neuroscience field.” The article can be found here: Recording Human Electrocorticographic (ECoG) Signals for Neuroscientific Research and Real-time Functional Cortical Mapping

Provided by The Journal of Visualized Experiments

Source: medicalxpress.com

June 25, 2012

The same neurological mechanism involved in the transition from habitual to compulsive drug use could underlie less severe, but still harmful, compulsive behaviours.

"We’re trying to understand individuality in addictive behaviour. Many people can be exposed to drugs with addictive potential, for instance, but not everyone will become addicted,” explains Eric Dumont, an associate professor in the Department of Biomedical and Molecular Sciences. “We believe we’ve identified a mechanism that makes certain people predisposed to developing addictions, and it’s possible that the same mechanism underlies many - perhaps most - compulsive behaviours.”

The mechanism occurs in a reward pathway of the brain. In this pathway, the brain maintains a delicate balance between pleasure and aversion, ensuring that moment-to-moment desires and dislikes remain in sync with the biological needs of the body.

Dr. Dumont and his team found unusual activity in this pathway when modeling drug addiction in rats, which exhibit a genetic predisposition to addiction comparable to humans. They believe that the pathway’s balance is prone to becoming unbalanced in a certain percentage of the population. The signal to stop an activity reverses to a green light.

The team hopes that by identifying this mechanism, and possibly others like it, they will allow researchers to better understand and monitor a range of compulsive behaviours. Accordingly, Dr. Dumont’s team collaborates with Dr. Cella Olmstead, associate professor of Psychology at Queen’s, who recently developed an animal model of compulsive sucrose intake.

Dr. Dumont and this team were recently awarded a $520,000 operating grant from Canadian Institutes of Health Research (CIHR) to support their work for the next five years in understanding the neurological processes behind addiction behaviour.

Provided by Queen’s University

Source: medicalxpress.com

ScienceDaily (June 25, 2012) — The hot flashes and night sweats that most women experience early in menopause are not linked to increased levels of cardiovascular disease risk markers unless the symptoms persist or start many years after menopause begins. These new study results were presented June 23 at The Endocrine Society’s 94th Annual Meeting in Houston.

"Our study provides reassurance that the common experience of menopausal symptoms in early menopause is not associated with increases in blood pressure or other risk markers for cardiovascular disease," said lead researcher Emily Szmuilowicz, MD, an assistant professor at Northwestern University’s medical school in Chicago.

Researchers have questioned whether vasomotor menopausal symptoms such as hot flashes and night sweats reflect poor cardiovascular health. However, a 2011 study by Szmuilowicz and co-workers found that women who experienced menopausal symptoms only at the onset of menopause were less likely to have a stroke or heart attack or to die than were women who experienced hot flashes late in menopause or who did not have hot flashes at all.

Their new study focused on markers in the body that have been linked to a raised risk of cardiovascular disease. The risk markers examined were blood pressure, cholesterol, insulin, glucose (blood sugar) and blood markers of abnormal blood vessel function. Because inflammation is common in people with heart disease or stroke, the group also looked at blood markers of inflammation, including white blood cell count — the number of disease-fighting cells.

This study used retrospective data from nearly 60,000 postmenopausal women who participated in the Women’s Health Initiative Observational Study. The ongoing study, funded by the National Institutes of Health, is examining the relationships between health outcomes and new risk indicators for disease.

The researchers grouped women into four categories based on timing of their menopausal symptoms of hot flashes and night sweats: only at the start of menopause (early-onset menopausal symptoms), only years later in menopause (late-onset menopausal symptoms), both time periods (persistent menopausal symptoms), and not at all.

The investigators found no association between early-onset vasomotor menopausal symptoms and increased levels of any cardiovascular risk markers. However, both persistent and late-onset menopausal symptoms were associated with higher blood pressure and higher white blood cell count compared with women without menopausal symptoms, they reported. Persistent menopausal symptoms also correlated with higher levels of glucose and insulin, which are markers for diabetes.

It is unclear why women who experience menopausal symptoms at different stages of menopause may have differing levels of cardiovascular disease risk, Szmuilowicz said She speculated that “if menopausal symptoms occur long after menopause begins, this may signal a blood vessel abnormality that could also affect cardiovascular health.”

Source: Science Daily

ScienceDaily (June 25, 2012) — Deep brain stimulation reduces binge eating in mice, suggesting that this surgery, which is approved for treatment of certain neurologic and psychiatric disorders, may also be an effective therapy for obesity. Presentation of the results took place June 25 at The Endocrine Society’s 94th Annual Meeting in Houston.

"Doing brain surgery for obesity treatment is a controversial idea," said the study’s presenting author, Casey Halpern, MD, a fifth-year neurosurgery resident physician at the University of Pennsylvania, Philadelphia. "However, binge eating is a common feature of obese patients that frequently is associated with suboptimal treatment outcomes."

Currently the U.S. Food and Drug Administration has approved deep brain stimulation for use in various conditions that affect the brain, including Parkinson’s disease and essential tremor. The procedure does not destroy any part of the brain and typically does not cause pain, Halpern said.

Available treatments of obesity may inadequately address the neural basis of this compulsive overeating behavior, he suggested. A region of the brain called the nucleus accumbens is known to be dysregulated in both rodents and people who binge eat. Therefore, Halpern and his co-workers targeted that brain region with deep brain stimulation in a strain of obesity-prone mice.

The surgery involved implanting an electrode in the nucleus accumbens. Wires connected the electrode to an external neurostimulator, a device similar to a pacemaker. When switched on, the stimulator triggers the electrode to deliver continuous electrical pulses to the brain.

After recovery from surgery, the mice received high-fat food at the same time every day for one hour, and the researchers measured their food consumption. Binge eating was defined as consuming 25 percent or more of the usual daily caloric intake during this period.

For one week, mice consistently binged, eating almost half of their daily calories during this one hour, the authors reported. Then on alternating days, the investigators turned on the stimulator. On the days that deep brain stimulation was administered, or “on,” the scientists observed a significant (approximately 60 percent) decrease in consumption of the high-fat diet. On the alternate days when they turned off the stimulator, binge eating returned, Halpern said.

The researchers then studied how deep brain stimulation might work to improve binge eating. With medications, they blocked various receptors of dopamine neurons, or nerve cells. Dopamine is a brain neurotransmitter, a chemical messenger, whose release in the brain is linked to the desire for rewarding behaviors such as eating high-fat food, according to Halpern.

Only one of the medications had an effect. Raclopride, which blocks the type 2 dopamine receptor, weakened the beneficial effect of deep brain stimulation by 50 percent.

Their results, Halpern said, showed that “at least one way that deep brain stimulation functions to suppress binge eating might be by modulating activity of neurons expressing the type 2 dopamine receptor.”

Source: Science Daily

June 25, 2012 By Rick Nauert

A new study involving children with Williams syndrome (WS) suggests that improved regulation of oxytocin and vasopressin may someday improve care for autism, anxiety, post-traumatic stress disorder and WS.

WS results when certain genes are absent because of a faulty recombination event during the development of sperm or egg cells. Virtually everyone with WS has exactly the same set of genes missing (25 to 28 genes are missing from one of two copies of chromosome 7).

“The genetic deficiencies allow researchers to examine the genetic and neuronal basis of social behavior,” said Ursula Bellugi, Ph.D., a co-author on the paper.

“This study provides us with crucial information about genes and brain regions involved in the control of oxytocin and vasopressin, hormones that may play important roles in other disorders.”

In the study, scientists at the Salk Institute for Biological Studies and the University of Utah, found that people with WS flushed with the hormones oxytocin and arginine vasopressin (AVP) when exposed to emotional triggers.

Children with WS love people, despite being challenged with numerous health problems. WS kids are extremely gregarious, irresistibly drawn to strangers, and insist on making eye contact.

They have an affinity for music. But they also experience heightened anxiety, have an average IQ of 60, experience severe spatial-visual problems, and suffer from cardiovascular and other health issues.

Yet despite their desire to befriend people, WS kids have difficulty creating and maintaining social relationships — an issue that obviously affects many people without WS.

In the new study, led by Julie R. Korenberg, M.D., 21 participants, 13 who have WS and a control group of eight people without the disorder were evaluated at the Cedars-Sinai Medical Center in Los Angeles. Because music is a known strong emotional stimulus, the researchers asked participants to listen to music.

Before the music was played, the participants’ blood was drawn to determine a baseline level for oxytocin. Remarkably, those with WS had three times as much of the hormone as those without the syndrome.

Blood also was drawn at regular intervals while the music played and was analyzed afterward to check for real-time, rapid changes in the levels of oxytocin and AVP.

While other studies have examined how oxytocin affects emotion when artificially introduced into people, such as through nasal sprays, this is one of the first significant studies to measure naturally occurring changes in oxytocin levels in rapid, real time as people undergo an emotional response.

Although the WS participants displayed little outward response to the music, an analyses of blood samples showed that the oxytocin levels, and to a lesser degree AVP, had increased sharply while they had listened to the music.

In contrast, among those without WS, both the oxytocin and AVP levels remained largely unchanged as they listened to music.

Korenberg believes the blood analyses strongly indicate that oxytocin and AVP are not regulated correctly in people with WS, and that the behavioral characteristics unique to people with WS are related to this problem. “This shows that oxytocin quite likely is very involved in emotional response,” she said.

In addition to listening to music, study participants already had taken three social behavior tests that evaluate willingness to approach and speak to strangers, emotional states, and various areas of adaptive and problem behavior.

Those test results suggest that increased levels of oxytocin are linked to both increased desire to seek social interaction and decreased ability to process social cues, a double-edged message that may be very useful at times, for example, during courtship, but damaging at others, as in WS.

“The association between abnormal levels of oxytocin and AVP and altered social behaviors found in people with Williams Syndrome points to surprising, entirely unsuspected deleted genes involved in regulation of these hormones and human sociability,” Korenberg said.

“It also suggests that the simple characterization of oxytocin as ‘the love hormone’ may be an overreach. The data paint a far more complicated picture.”

Overall, the researchers say, their findings paint a hopeful picture, and the study holds promise for speeding progress in treating WS, and perhaps autism and anxiety through regulation of these key players in human brain and emotion, oxytocin and vasopressin.

Source: PsychCentral

ScienceDaily (June 25, 2012) — Researchers have discovered how a hormone in the gut slows the rate at which the stomach empties and thus suppresses hunger and food intake. Results of the animal study were presented June 25 at The Endocrine Society’s 94th Annual Meeting in Houston.

"The gut hormone glucagon-like peptide 2, or GLP-2, functions as a neurotransmitter and fine-tunes gastric emptying through — as suspected — its receptor action in the brain," said the lead investigator, Xinfu Guan, PhD, assistant professor of pediatrics and medicine at Baylor College of Medicine in Houston.

The researchers found that this action occurs in the GLP-2 receptor specifically in a key group of nerve cells in the brain, called pro-opiomelanocortin, or POMC, neurons. These neurons are in the hypothalamus, the part of the brain that produces appetite-controlling neuropeptides.

In their study using molecular methods, mice lacking this GLP-2 receptor in the POMC neurons showed late-onset obesity and higher food intake compared with normal wild-type mice. The mutant, or GLP-2 receptor “knockout,” mice also had accelerated gastric emptying after a liquid meal, as found on a noninvasive breath test. The faster the gastric emptying, the higher the food intake, scientists know.

Therefore, obese people may have something wrong with this hormone receptor, which alters their gastric emptying rate, Guan speculated. Many studies have shown that nondiabetic, obese humans have accelerated gastric emptying.

The researchers also found that this receptor quickly activated the PI3K intracellular signaling pathway in the POMC neurons. This, in turn, induces neuronal excitation (transmission of signals) and gene expression, according to Guan.

These findings, Guan said, show that in the central nervous system the GLP-2 receptor plays an important physiological role in the control of food intake and gastric emptying.

"This study has advanced our understanding of the brain-gut neural circuits that mediate eating behavior via modulating gastric emptying, which contributes to the control of body weight," he said.

Source: Science Daily

ScienceDaily (June 25, 2012) — Women with moderate to severe depression had substantial improvement in their symptoms of depression after they received treatment for their vitamin D deficiency, a new study finds.

The case report series was presented June 23 at The Endocrine Society’s 94th Annual Meeting in Houston.

Because the women did not change their antidepressant medications or other environmental factors that relate to depression, the authors concluded that correction of the patients’ underlying shortage of vitamin D might be responsible for the beneficial effect on depression.

"Vitamin D may have an as-yet-unproven effect on mood, and its deficiency may exacerbate depression," said Sonal Pathak, MD, an endocrinologist at Bayhealth Medical Center in Dover, Del. "If this association is confirmed, it may improve how we treat depression."

Pathak presented the research findings in three women, who ranged in age from 42 to 66. All had previously diagnosed major depressive disorder, also called clinical depression, and were receiving antidepressant therapy. The patients also were being treated for either Type 2 diabetes or an underactive thyroid (hypothyroidism).

Because the women had risk factors for vitamin D deficiency, such as low vitamin D intake and poor sun exposure, they each underwent a 25-hydroxyvitamin D blood test. For all three women, the test found low levels of vitamin D, ranging from 8.9 to 14.5 nanograms per milliliter (ng/mL), Pathak reported. Levels below 21 ng/mL are considered vitamin D deficiency, and normal vitamin D levels are above 30 ng/mL, according to The Endocrine Society.

Over eight to 12 weeks, oral vitamin D replacement therapy restored the women’s vitamin D status to normal. Their levels after treatment ranged from 32 to 38 ng/mL according to the study abstract.

After treatment, all three women reported significant improvement in their depression, as found using the Beck Depression Inventory. This 21-item questionnaire scores the severity of sadness and other symptoms of depression. A score of 0 to 9 indicates minimal depression; 10 to 18, mild depression; 19 to 29, moderate depression; and 30 to 63, severe depression.

One woman’s depression score improved from 32 before vitamin D therapy to 12, a change from severe to mild depression. Another woman’s score fell from 26 to 8, indicating she now had minimal symptoms of depression. The third patient’s score of 21 improved after vitamin D treatment to 16, also in the mild range.

Other studies have suggested that vitamin D has an effect on mood and depression, but there is a need for large, good-quality, randomized controlled clinical trials to prove whether there is a real causal relationship, Dr Pathak said.

"Screening at-risk depressed patients for vitamin D deficiency and treating it appropriately may be an easy and cost-effective adjunct to mainstream therapies for depression," she said.

Source: Science Daily

ScienceDaily (June 25, 2012) — Widely available EEG testing can distinguish children with autism from neurotypical children as early as age 2, finds a study from Boston Children’s Hospital. The study is the largest, most rigorous study to date to investigate EEGs as a potential diagnostic tool for autism, and offers hope for an earlier, more definitive test.

Widely available EEG testing can distinguish children with autism from neurotypical children as early as age 2, finds a new study. The study is the largest, most rigorous study to date to investigate EEGs as a potential diagnostic tool for autism, and offers hope for an earlier, more definitive test. (Credit: © dule964 / Fotolia)

Researchers Frank H. Duffy, MD, of the Department of Neurology, and Heidelise Als, PhD, of the Department of Psychiatry at Boston Children’s Hospital, compared raw EEG data from 430 children with autism and 554 control subjects, ages 2 to 12, and found that those with autism had consistent EEG patterns indicating altered connectivity between brain regions — generally, reduced connectivity as compared with controls.

While altered connectivity occurred throughout the brain in the children with autism, the left-hemisphere language areas stood out, showing reduced connectivity as compared with neurotypical children, consistent with neuroimaging research. Findings were published June 26 in the online open-access journal BMC Medicine.

Duffy and Als focused on children with “classic” autism who had been referred for EEGs by neurologists, psychiatrists or developmental pediatricians to rule out seizure disorders. Those with diagnosed seizure disorders were excluded, as were children with Asperger’s syndrome and “high functioning” autism, who tend to dominate (and skew) the existing literature because they are relatively easy to study. The researchers also excluded children with genetic syndromes linked to autism (such as Fragile X or Rett syndrome), children being treated for other major illnesses, those with sensory disorders like blindness and deafness and those taking medications.

"We studied the typical autistic child seeing a behavioral specialist — children who typically don’t cooperate well with EEGs and are very hard to study," says Duffy. "No one has extensively studied large samples of these children with EEGs, in part because of the difficulty of getting reliable EEG recordings from them."

The researchers used techniques developed at Boston Children’s Hospital to get clean waking EEG recordings from children with autism, such as allowing them to take breaks. They used computer algorithms to adjust for the children’s body and eye movements and muscle activity, which can throw off EEG readings.

To measure connectivity in the brain, Duffy and Als compared EEG readings from multiple electrodes placed on the children’s scalps, and quantified the degree to which any two given EEG signals — in the form of waves — are synchronized, known as coherence. If two or more waves rise and fall together over time, it indicates that those brain regions are tightly connected. (Duffy likens coherence to two people singing “Mary Had a Little Lamb” together. If they can see and hear each other, they are more likely to sing in synchrony — so their coherence is high.)

In all, using computational techniques, the researchers generated coherence readings for more than 4,000 unique combinations of electrode signals, and looked for the ones that seemed to vary the most from child to child. From these, they identified 33 coherence “factors” that consistently distinguished the children with autism from the controls, across all age groups (2 to 4, 4 to 6, and 6 to 12 years).

Duffy and Als repeated their analysis 10 times, splitting their study population in half different ways and using half to identify the factors, and the other half to test and validate them. Each time, the classification scheme was validated.

"These factors allowed us to make a discriminatory rule that was highly significant and highly replicable," says Duffy. "It didn’t take anything more than an EEG — the rest was computational. Our choice of variables was completely unbiased — the data told us what to do."

The researchers believe the findings could be the basis for a future objective diagnostic test of autism, particularly at younger ages when behavior-based measures are unreliable. Their most immediate goal is to repeat their study in children with Asperger’s syndrome and see if its EEG patterns are similar to or different from autism. They also plan to evaluate children whose autism is associated with conditions such as tuberous sclerosis, fragile X syndrome and extremely premature birth.

Source: Science Daily

June 25, 2012 By Traci Pedersen

Scientists have found improvements on memory tests and an increase in brain volume in Chinese seniors who practice tai chi three times a week, according to an article published in the Journal of Alzheimer’s Disease.

The trial also showed increases in brain volume and smaller cognitive improvements in individuals that participated in lively discussions three times per week over the same time period.

Researchers from the University of South Florida and Fudan University in Shanghai conducted an eight-month randomized controlled trial involving a group of seniors who practiced tai chi as well as a group who participated in lively conversations.  Researchers compared these to a control group who received no intervention.

Previous studies have shown an increase in brain volume in people who participated in aerobic exercise, and in one of these trials, memory was improved as well.

However, this was the first trial to prove that a less aerobic form of exercise, tai chi, as well as stimulating discussion, led to similar increases in brain volume and improvements on psychological tests of memory and thinking.

Volunteers who did not participate in the interventions showed brain shrinkage during this time period, consistent with what generally has been observed for persons in their 60s and 70s.

Several studies have shown that dementia and the gradual cognitive decline that precedes it is linked to increasing shrinkage of the brain as nerve cells and their connections are slowly lost.

“The ability to reverse this trend with physical exercise and increased mental activity implies that it may be possible to delay the onset of dementia in older persons through interventions that have many physical and mental health benefits,” said lead author James Mortimer, Ph.D., professor of epidemiology at the University of South Florida College of Public Health.

Research suggests that aerobic exercise is associated with increased production of brain growth factors. It has been undetermined whether forms of exercise like tai chi that include an important mental exercise component could lead to similar changes in brain development.

“If this is shown, then it would provide strong support to the concept of ‘use it or lose it’ and encourage seniors to stay actively involved both intellectually and physically,” Mortimer said.

One question raised by the research is whether sustained physical and mental exercise can help prevent Alzheimer’s disease.

“Epidemiologic studies have shown repeatedly that individuals who engage in more physical exercise or are more socially active have a lower risk of Alzheimer’s disease,” Mortimer said. “The current findings suggest that this may be a result of growth and preservation of critical regions of the brain affected by this illness.”

Source: PsychCentral

ScienceDaily (June 25, 2012) — A team of researchers led by an epidemiologist at Mount Sinai School of Medicine and University of Iceland has found a correlation between the age at which children with attention-deficit/hyperactivity disorder (ADHD) begin taking medication, and how well they perform on standardized tests, particularly in math.

The study, titled, “A Population-Based Study of Stimulant Drug Treatment of ADHD and Academic Progress in Children,” appears in the July, 2012, edition of Pediatrics, and can be viewed online on June 25. Using data from the Icelandic Medicines Registry and the Database of National Scholastic Examinations, the researchers studied 11,872 Icelandic children born between 1994 and 1996. The children started medication for ADHD at different times between fourth and seventh grades.

The findings showed that children who began drug treatment within 12 months of their fourth-grade test declined 0.3 percent in math by the time they took their seventh-grade test, compared with a decline of 9.4 percent in children who began taking medication 25-to-36 months after their fourth-grade test.

The data also showed that girls benefited only in mathematics, whereas boys had marginal benefits in math and language arts.

"Children who began taking medications immediately after their fourth-grade standardized tests showed the smallest declines in academic performance," said the study’s lead author Helga Zoega, PhD, Post Doctoral Fellow of Epidemiology at Mount Sinai’s Institute for Translational Epidemiology. "The effect was greater in girls than boys and also greater for children who did poorly on their fourth grade test."

Stimulants are widely used in the United States as a therapeutic option for children with inattention, impulsivity, and hyperactivity associated with ADHD. The medications are less frequently used in Europe, although their use in Iceland most closely resembles the U.S. Long-term follow-up studies of stimulant use and academic performance are scarce, according to the researchers.

Source: Science Daily

June 25, 2012

The Allen Institute for Brain Science convened the first ever Allen Brain Atlas Hackathon last week, opening its doors to a diverse group of programmers and informatics experts for a non-stop week of collaboration, learning and coding based on its public online platform of data, tools and source code. The event brought together more than 30 participants from top universities and institutes ranging from the Baylor College of Medicine in Houston to the Nencki Institute of Experimental Biology in Poland, as well as from start-ups and established technology companies, to develop data analysis strategies and tools based on the newly enhanced Allen Brain Atlas application programming interface (API).

"This hackathon stems from our longstanding, open approach to science and our belief that putting our data-rich resources in the hands of the many and varied experts around the globe is the most effective way to drive progress in brain research,” said Chinh Dang, Chief Technology Officer of the Allen Institute for Brain Science. “The hackathon projects delivered innovative ways of handling data, offering direct contributions to the informatics and programming communities as well as to neuroscience. We hope that this event serves as a springboard for others out in the community to use our API, and we look forward to seeing what can be done with it.”

The Allen Institute for Brain Science is one of the biggest data producers in neuroscience, with rapidly growing data stores in the petabyte range that it makes publicly available through its Web-based Allen Brain Atlas resources. These resources include, among others, anatomically and genomically comprehensive maps of genes at work in the mouse and human brains and receive approximately 50,000 visits each month from researchers around the globe.

The public API was created as an additional form of data sharing to spur community technology development and further empower scientists to make groundbreaking discoveries about the brain in health and disease—including insights into learning, cognition, development, Alzheimer’s, obesity, schizophrenia, autism, and more—that will deliver better treatment options sooner. The hackathon coincided with the public release of the full Allen Brain Atlas API earlier this month, and a key goal of the event was to ignite community momentum and interest in using it.

Using the Allen Brain Atlas API, developers can create entirely new software applications, mashups and novel data mining tools for making sense of the large and ever-growing volumes of neuroscience data. The API offers data access across species, ages, disease and control states, providing a powerful means to compare many types of data (e.g., histology images, gene expression, and MRI) among many types of samples (e.g., ages, species or diseases).

"The Allen Institute is a leader in large-scale open science, known for providing high-quality data and online tools that advance brain research," said Sean Hill, Executive Director of the International Neuroinformatics Coordinating Facility (INCF). "With the Allen Brain Atlas Hackathon and their public API, they are bringing the same collaborative, community-focused approach to technology development and innovation that is at the core of INCF’s mission."

The hackathon program was designed to provide scientists and programmers a solid foundation in using the Allen Brain Atlas API for data mining, data analysis and tools development. The event featured a handful of speakers from the Allen Institute, as well as external experts who had leveraged earlier versions of the API in their work. As a hands-on workshop, participants spent most of the time working on projects of their choice. The Allen Institute development team actively participated throughout the week to provide specific examples of API usage, as well as to team up with community participants to develop collaborative projects. Participants’ presentations throughout the week showcased their projects and progress, stimulating new ideas and benefiting from the collective feedback and troubleshooting power of the entire group.

Projects ranged from practical applications, such as using a list of glioblastoma-related genes to discover biological patterns that could shed new light on the biology of the disease and developing strategies to use gene expression data with functional brain scanning technologies, to purely creative applications, including translating genomic data into music.

The Allen Brain Atlas Hackathon was hosted by the Allen Institute for Brain Science and funded jointly with the International Neuroinformatics Coordinating Facility (INCF).

Provided by Allen Institute for Brain Science

Source: medicalxpress.com

June 24, 2012 by SETH BORENSTEIN

(AP) — The more we study animals, the less special we seem.

In this Dec. 13, 2006 photo provided by the Primate Research Institute of Kyoto University, a 5 1/2-year-old chimpanzee named Ayumu performs a memory test with randomly-placed consecutive Arabic numerals, which are later masked, accurately duplicating the lineup on a touch screen computer in Kyoto, Japan. The young chimpanzees in the study titled “Working memory of numerals in chimpanzees” by Sana Inoue and Tetsuro Matsuzawa could memorize the nine numerals much faster and more accurately than human adults. The evidence that animals are more intelligent and more social than we thought seems to grow each year, especially when it comes to primates. It’s an increasingly hot scientific field with the number of ape and monkey cognition studies doubling in recent years, often with better technology and neuroscience paving the way to unusual discoveries. (AP Photo/Primate Research Institute of Kyoto University) PART OF A SEVEN-PICTURE PACKAGE WITH “ANIMAL SCIENCES”

Baboons can distinguish between written words and gibberish. Monkeys seem to be able to do multiplication. Apes can delay instant gratification longer than a human child can. They plan ahead. They make war and peace. They show empathy. They share.

"It’s not a question of whether they think — it’s how they think," says Duke University scientist Brian Hare. Now scientists wonder if apes are capable of thinking about what other apes are thinking.

The evidence that animals are more intelligent and more social than we thought seems to grow each year, especially when it comes to primates. It’s an increasingly hot scientific field with the number of ape and monkey cognition studies doubling in recent years, often with better technology and neuroscience paving the way to unusual discoveries.

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ScienceDaily (June 24, 2012) — The blood-brain barrier — the filter that governs what can and cannot come into contact with the mammalian brain — is a marvel of nature. It effectively separates circulating blood from the fluid that bathes the brain, and it keeps out bacteria, viruses and other agents that could damage it.

But the barrier can be disrupted by disease, stroke and multiple sclerosis, for example, and also is a big challenge for medicine, as it can be difficult or impossible to get therapeutic molecules through the barrier to treat neurological disorders.

Now, however, the blood-brain barrier may be poised to give up some of its secrets as researchers at the University of Wisconsin-Madison have created in the laboratory dish the cells that make up the brain’s protective barrier. Writing in the June 24, 2012 edition of the journal Nature Biotechnology, the Wisconsin researchers describe transforming stem cells into endothelial cells with blood-brain barrier qualities.

Access to the specialized cells “has the potential to streamline drug discovery for neurological disease,” says Eric Shusta, a UW-Madison professor of chemical and biological engineering and one of the senior authors of the new study. “You can look at tens of thousands of drug candidates and just ask the question if they have a chance to get into the brain. There is broad interest from the pharmaceutical industry.”

The blood-brain barrier depends on the unique qualities of endothelial cells, the cells that make up the lining of blood vessels. In many parts of the body, the endothelial cells that line capillaries are spaced so that substances can pass through. But in the capillaries that lead to the brain, the endothelial cells nestle in tight formation, creating a semi-permeable barrier that allows some substances — essential nutrients and metabolites — access to the brain while keeping others — pathogens and harmful chemicals — locked out.

The cells described in the new Wisconsin study, which was led by Ethan S. Lippmann, now a postdoctoral fellow at the Wisconsin Institute for Discovery, and Samira M. Azarin, now a postdoctoral fellow at Northwestern University, exhibit both the active and passive regulatory qualities of those cells that make up the capillaries of the intact brain.

The research team coaxed both embryonic and induced pluripotent stem cells to form the endothelial cells of the blood-brain barrier. The use of induced cells, which can come from patients with specific neurological conditions, may be especially important for modeling disorders that compromise the blood-brain barrier. What’s more, because the cells can be mass produced, they could be used to devise high-throughput screens for molecules that may have therapeutic value for neurological conditions or to identify existing drugs that may have neurotoxic qualities.

"The nice thing about deriving endothelial cells from induced pluripotent stem cells is that you can make disease-specific models of brain tissue that incorporate the blood-brain barrier," explains Sean Palecek, a UW-Madison professor of chemical and biological engineering and a senior author of the new report. "The cells you create will carry the genetic information of the condition you want to study."

The generation of the specialized blood-brain barrier endothelial cells, the Wisconsin researchers note, has never been done with stem cells. In addition to the potential applications to screen drugs and model pathologies of the blood-brain barrier, they may also provide a novel window for developmental biologists who are interested in how the barrier comes together and co-develops with the brain.

"Neurons develop at the same time as the endothelial cells," Shusta says, noting that, in development, the cells secrete chemical cues that help determine organ specificity.

"We don’t know what all those factors are," Lippmann says. "But with this model, we can go back and look." Identifying all of the molecular factors at play as blank slate stem cells differentiate to become specialized endothelial cells could one day have clinical significance to treat stroke or tamp down the ability of brain tumors to recruit blood vessels needed to sustain cancer.

Source: Science Daily

ScienceDaily (June 24, 2012) — Every day the human brain is presented with tasks ranging from the trivial to the complex. How much mental effort and attention are devoted to each task is usually determined in a split second and without conscious awareness. Now a study from Massachusetts General Hospital (MGH) researchers finds that a structure deep within the brain, believed to play an important role in regulating conscious control of goal-directed behavior, helps to optimize behavioral responses by predicting how difficult upcoming tasks will be. The report is receiving advance online publication in Nature.

"The dorsal anterior cingulate cortex (dACC), which lies deep beneath the outer layer of the frontal lobes, is part of an ancient and enigmatic part of the brain," says Emad Eskandar, MD, of the MGH Department of Neurosurgery, senior author of the Nature paper. “Some have speculated that it plays a role in detecting errors or monitoring for conflicting demands, but exactly how it contributes to regulating behavioral responses is unclear, so we used a variety of scientific techniques to get a better picture of its function.”

The study enrolled six participants who were scheduled to undergo cingulotomy — a procedure in which a small, precisely placed lesion is created within the ACC — to treat severe obsessive compulsive disorder (OCD) that has not responded to other types of treatment. A standard part of the cingulotomy procedure involves microelectrode recordings of the activity of single neurons in the area where the lesion is to be placed. To evaluate dACC function, the investigators recorded brain activity from several neurons within the structure while participants performed a behavioral task testing their reactions to visual images.

The task presented participants with a random series of images of three numerals, which could be 0, 1, 2, or 3. In each image, two of the numerals were identical. Participants responded by pressing one of three buttons, the position of which would indicate the identity of the number that was different, with the left button indicating 1, the middle 2 and the right button 3. Each image was ranked in difficulty depending on how much the position of the target numeral or the identity of the duplicate numerals might distract participants from the correct response. For example, when presented with 3-3-2, the correct response would be to press the middle button for number 2; and that image would be ranked more difficult than 3-2-3, in which both the target number and the correct button were in the same position.

Functional magnetic resonance imaging (fMRI) of four participants performing the behavioral task prior to the cingulotomy procedure revealed that the task increased metabolic activity within the dACC, a result seen in previous fMRI studies. The fMRI images also revealed that responding to more difficult images produced greater activity levels within the dACC and in other structures known to be involved in decision making. Intraoperative microelectrode recordings of all participants demonstrated that this apparent increase in metabolic activity corresponded with an increase in neuronal activity, linking for the first time the increased activation revealed by fMRI with increased neuronal firing.

Analysis of individual neuron activity indicated that dACC neuronal activity remained elevated immediately after difficult trials. Moreover, participant reaction time revealed that the difficulty of the prior trial had an impact on the next trial: if the preceding trial was of the same level of difficulty, reaction time was shorter; if the two tests were of different difficulty levels — even if the second test was easier — reaction time was longer. By anticipating the difficulty of upcoming tasks, the authors note, it appears that the dACC speeds up responses when difficulty levels are constant but slows response time down when faced with changing demands in order to promote accuracy.

While behavioral tests conducted after the cingulotomy procedure — which destroys tissue within the dACC — did not indicate a change in participants’ ability to perform the test accurately, the impact of preceding trials on reaction time appeared to vanish. “Participants could still perform the task, but the dACC’s role of priming the system based on immediate prior experience was gone,” Eskandar explains. “We believe this result indicates an important role for the dACC in rapidly adjusting to different cognitive demands, possibly by recruiting other areas of the brain to solve particular problems.”

An associate professor of Surgery at Harvard Medical School, Eskandar adds that, while significant cognitive changes have not been reported in patients undergoing cingulotomy, the apparent role of the dACC in adapting to changing situations implies a possible role for the structure in several psychiataric disorders. “A lack of behavior flexibility and adjustment is characteristic of OCD, for example. Whether or not our findings directly relate to these disorders remains to be determined, but we hope that continued study using complex tasks, such as the behavioral test used here, will be helpful in diagnosing or monitoring psychiatric disorders.”

Source: Science Daily

ScienceDaily (June 24, 2012) — Hemimegalencephaly is a rare but dramatic condition in which the brain grows asymmetrically, with one hemisphere becoming massively enlarged. Though frequently diagnosed in children with severe epilepsy, the cause of hemimegalencephaly is unknown and current treatment is radical: surgical removal of some or all of the diseased half of the brain.

This image depicts hemimegalencephaly. (Credit: UC San Diego School of Medicine)

In a paper published in the June 24, 2012 online issue of Nature Genetics, a team of doctors and scientists, led by researchers at the University of California, San Diego School of Medicine and the Howard Hughes Medical Institute, say de novo somatic mutations in a trio of genes that help regulate cell size and proliferation are likely culprits for causing hemimegalencephaly, though perhaps not the only ones.

De novo somatic mutations are genetic changes in non-sex cells that are neither possessed nor transmitted by either parent. The scientists’ findings — a collaboration between Joseph G. Gleeson, MD, professor of neurosciences and pediatrics at UC San Diego School of Medicine and Rady Children’s Hospital-San Diego; Gary W. Mathern, MD, a neurosurgeon at UC Los Angeles’ Mattel Children’s Hospital; and colleagues — suggest it may be possible to design drugs that inhibit or turn down signals from these mutated genes, reducing or even preventing the need for surgery.

Gleeson’s lab studied a group of 20 patients with hemimegalencephaly upon whom Mathern had operated, analyzing and comparing DNA sequences from removed brain tissue with DNA from the patients’ blood and saliva.

"Mathern had reported a family with identical twins, in which one had hemimegalencephaly and one did not. Since such twins share all inherited DNA, we got to thinking that there may be a new mutation that arose in the diseased brain that causes the condition," said Gleeson. Realizing they shared the same ideas about potential causes, the physicians set out to tackle this question using new exome sequencing technology, which allows sequencing of all of the protein-coding exons of the genome at the same time.

The researchers ultimately identified three gene mutations found only in the diseased brain samples. All three mutated genes had previously been linked to cancers.

"We found mutations in a high percentage of the cells in genes regulating the cellular growth pathways in hemimegalencephaly," said Gleeson. "These same mutations have been found in various solid malignancies, including breast and pancreatic cancer. For reasons we do not yet understand, our patients do not develop cancer, but rather this unusual brain condition. Either there are other mutations required for cancer propagation that are missing in these patients, or neurons are not capable of forming these types of cancers."

The mutations were found in 30 percent of the patients studied, indicating other factors are involved. Nonetheless, the researchers have begun investigating potential treatments that address the known gene mutations, with the clear goal of finding a way to avoid the need for surgery.

"Although counterintuitive, hemimegalencephaly patients are far better off following the functional removal or disconnection of the enlarged hemisphere," said Mathern. "Prior to the surgery, most patients have devastating epilepsy, with hundreds of seizures per day, completely resistant to even our most powerful anti-seizure medications. The surgery disconnects the affected hemisphere from the rest of the brain, causing the seizures to stop. If performed at a young age and with appropriate rehabilitation, most children suffer less language or cognitive delay due to neural plasticity of the remaining hemisphere."

But a less-invasive drug therapy would still be more appealing.

"We know that certain already-approved medications can turn down the signaling pathway used by the mutated genes in hemimegalencephaly," said lead author and former UC San Diego post-doctoral researcher Jeong Ho Lee, now at the Korea Advanced Institute of Science and Technology. "We would like to know if future patients might benefit from such a treatment. Wouldn’t it be wonderful if our results could prevent the need for such radical procedures in these children?"

Source: Science Daily

ScienceDaily (June 24, 2012) — Researchers at Yale School of Medicine have zeroed in on a set of neurons in the part of the brain that controls hunger, and found that these neurons are not only associated with overeating, but also linked to non-food associated behaviors, like novelty-seeking and drug addiction.

A lean animal and a control were both exposed to a novelty item (center). The lean animal spent more time exploring the novelty, as shown by the higher concentration of yellow in the slide. (Credit: Image courtesy of Yale University)

Published in the June 24 online issue of Nature Neuroscience, the study was led by Marcelo O. Dietrich, postdoctoral associate, and Tamas L. Horvath, the Jean and David W. Wallace Professor of Biomedical Research and chair of comparative medicine at Yale School of Medicine.

In attempts to develop treatments for metabolic disorders such as obesity and diabetes, researchers have paid increasing attention to the brain’s reward circuits located in the midbrain, with the notion that in these patients, food may become a type of “drug of abuse” similar to cocaine. Dietrich notes, however, that this study flips the common wisdom on its head.

"Using genetic approaches, we found that increased appetite for food can actually be associated with decreased interest in novelty as well as in cocaine, and on the other hand, less interest in food can predict increased interest in cocaine," said Dietrich.

Horvath and his team studied two sets of transgenic mice. In one set, they knocked out a signaling molecule that controls hunger-promoting neurons in the hypothalamus. In the other set, they interfered with the same neurons by eliminating them selectively during development using diphtheria toxin. The mice were given various non-invasive tests that measured how they respond to novelty, and anxiety, and how they react to cocaine.

"We found that animals that have less interest in food are more interested in novelty-seeking behaviors and drugs like cocaine," said Horvath. "This suggests that there may be individuals with increased drive of the reward circuitry, but who are still lean. This is a complex trait that arises from the activity of the basic feeding circuits during development, which then impacts the adult response to drugs and novelty in the environment."

Horvath and his team argue that the hypothalamus, which controls vital functions such as body temperature, hunger, thirst fatigue and sleep, is key to the development of higher brain functions. “These hunger-promoting neurons are critically important during development to establish the set point of higher brain functions, and their impaired function may be the underlying cause for altered motivated and cognitive behaviors,” he said.

"There is this contemporary view that obesity is associated with the increased drive of the reward circuitry," Horvath added. "But here, we provide a contrasting view: that the reward aspect can be very high, but subjects can still be very lean. At the same time, it indicates that a set of people who have no interest in food, might be more prone to drug addiction."

Source: Science Daily

ScienceDaily (June 24, 2012) — Want to nail that tune that you’ve practiced and practiced? Maybe you should take a nap with the same melody playing during your sleep, new provocative Northwestern University research suggests.

Want to nail that tune that you’ve practiced and practiced? Maybe you should take a nap with the same melody playing during your sleep. (Credit: © Anton Maltsev / Fotolia)

The research grows out of exciting existing evidence that suggests that memories can be reactivated during sleep and storage of them can be strengthened in the process.

In the Northwestern study, research participants learned how to play two artificially generated musical tunes with well-timed key presses. Then while the participants took a 90-minute nap, the researchers presented one of the tunes that had been practiced, but not the other.

"Our results extend prior research by showing that external stimulation during sleep can influence a complex skill," said Ken A. Paller, professor of psychology in the Weinberg College of Arts and Sciences at Northwestern and senior author of the study.

By using EEG methods to record the brain’s electrical activity, the researchers ensured that the soft musical “cues” were presented during slow-wave sleep, a stage of sleep previously linked to cementing memories. Participants made fewer errors when pressing the keys to produce the melody that had been presented while they slept, compared to the melody not presented.

"We also found that electrophysiological signals during sleep correlated with the extent to which memory improved," said lead author James Antony of the Interdepartmental Neuroscience Program at Northwestern. "These signals may thus be measuring the brain events that produce memory improvement during sleep."

The age-old myth that you can learn a foreign language while you sleep is sure to come to mind, said Paul J. Reber, associate professor of psychology at Northwestern and a co-author of the study.

"The critical difference is that our research shows that memory is strengthened for something you’ve already learned," Reber said. "Rather than learning something new in your sleep, we’re talking about enhancing an existing memory by re-activating information recently acquired."

The researchers, he said, are now thinking about how their findings could apply to many other types of learning.

"If you were learning how to speak in a foreign language during the day, for example, and then tried to reactivate those memories during sleep, perhaps you might enhance your learning."

Paller said he hopes the study will help them learn more about the basic brain mechanisms that transpire during sleep to help preserve memory storage.

"These same mechanisms may not only allow an abundance of memories to be maintained throughout a lifetime, but they may also allow memory storage to be enriched through the generation of novel connections among memories," he said.

The study opens the door for future studies of sleep-based memory processing for many different types of motor skills, habits and behavioral dispositions, Paller said.

Source: Science Daily

ScienceDaily (June 23, 2012) — The commonly-used epilepsy drug, valproic acid (VPA), can have a highly beneficial effect on some babies born with spinal muscular atrophy (SMA), the number one genetic killer during early infancy. But in about two-thirds of such cases it is either damaging or simply has no effect. Now, for the first time, researchers have found a way to identify which patients are likely to respond well to VPA prior to starting treatment. Their results have major implications, not just for SMA patients, but for other conditions treated with the drug such as migraine and epilepsy, and may even provide the conditions for turning VPA non-responders into responders, the researchers say.

Dr. Lutz Garbes, from the Institute of Human Genetics, University of Cologne, Germany, will tell the annual conference of the European Society of Human Genetics on June 24 that he and his colleagues had analysed blood RNA samples from a small group of SMA patients who had been treated with VPA. They found, as expected, that only about one third of patients responded well. In an attempt to discover whether blood sampling was the most appropriate test method to use, they also looked at VPA response in another tissue — fibroblasts (a type of skin cell). They found that the response in blood and in skin was the same in 60% of cases.

The researchers then generated pluripotent stem cells from fibroblasts of both a VPA responder and a non-responder, and differentiated them into GABAergic neurons (neurons that produce the amino acid GABA, the chief neurotransmitter in the mammalian nervous system). These neurons, when treated with VPA, exhibited a similar response to that previously found in blood and fibroblasts.

"This indicates for the first time that response to VPA is the same among blood and skin and suggests that monitoring blood for VPA therapy is indeed feasible in central nervous system diseases," says Dr. Garbes. "But, even more importantly, by using the SMA patients’ fibroblasts we were able to identify a decisive factor in the suppression of the positive response to VPA treatment. Utilising transcriptome-wide microarray profiling*, we found that high levels of the fatty acid transporter protein CD36 are associated with the lack of positive response to treatment.

"The implications of this discovery are far-reaching. First, we have been able to prove that monitoring blood is a reliable method for doctors to determine response to VPA treatment in many central nervous system diseases, since our findings are not specific to SMA. Second, the identification of CD36 as the crucial factor in suppressing response to treatment provides a simple way of appraising whether a patient will respond to therapy before treatment starts. And third, in the long run we may find a way to target CD36 in order to be able to change a non-VPA responder into a responder."

Knowing that CD36 is a crucial factor here means that the current, potentially dangerous, ‘trial and error’ approach to VPA treatment is now obsolete, the researchers say. Screening of patients for CD36 prior to treatment would mean that only those who would respond positively to VPA would be given it. This is important because, in some cases, VPA can cause life-threatening side-effects such as impairment of liver, blood cell and pancreatic function, especially in those just starting the treatment. “But we still do not understand how CD36 suppresses response to VPA, only that it does so,” says Dr. Garbes. “A greater understanding of its effects could also lead to the detection of even better targets to overcome the problem. “

In the case of SMA, VPA works by inhibiting enzymes called histone deacetylase (HDACs) which are involved in regulating the packaging of DNA. HDACs lead to a denser DNA packaging whereby protein production from genes is reduced. Other enzymes called histone acetyltransferases (HATs) lead to a more relaxed DNA structure, producing more protein. By inhibiting HDACs with VPA, the DNA packaging balance shifts towards the more relaxed structure and thus genes get activated and proteins produced. In SMA, the crucial gene is SMN2, a copy gene of the disease-determining gene SMN1. In healthy individuals, SMN1 is the major source of SMN protein, but SMN2 cannot fully compensate for the loss of SMN1 in SMA patients. By increasing SMN2 activity, it will produce more SMN protein and ameliorate the condition.

"Avoiding needless VPA treatment of non-responders would have a major effect on healthcare costs and improve quality of life for patients," Dr. Garbes will say. "Half of the babies born with SMA will die within two years, but the other half can live to twenty or even longer, so this is an important finding for them. Our findings may also help identify patients who are candidates for VPA treatment in many other diseases of the central nervous system, some of them very common.

"In the EU, approximately 550 SMA babies are born each year, and there are about 311,000 new cases of epilepsy per year. It is estimated that, in Europe, migraine affects up to 28% of people at some time in their lives. We are happy that we may have been able to contribute to the development of personalised medicine for so many people," he will conclude.

*A transcriptome-wide microarray profile provides a way of identifying all the genes that are differentially expressed in distinct cell populations or subtypes, allowing the effects of treatment to be monitored.

Source: Science Daily

ScienceDaily (June 22, 2012) — Some dementia patients show symptoms of a malfunctioning immune system and can receive appropriate treatment.

Scientists at Charité — Universitätsmedizin Berlin have succeeded in recommending a new type of therapeutic approach to dementia. The study published in the journal Neurology shows that immune reactions against the body’s own nerve cells can be the cause of advanced dementia and an appropriate immune suppressive therapy can develop with significant effectiveness.

Dementia burdens society with high costs, and those affected by it and their family members carry a tremendous psychosocial burden. Dementia is increasingly perceived as a sword of Damocles over an aging society due to its often unclear origin, difficult prevention and unsatisfactory therapies.

Together with a workgroup and cooperation partners in Germany and the US, Dr. Harald Prüß, physician at the Klinik für Neurologie of the Charité, was able to prove that dementia is also caused by the immune system. As an accessory symptom of an autoimmune disease, dementia can thus be treated. This approach to diagnostic criteria has been overlooked until now. It was proven that a number of patients in this study who suffered from advanced memory loss had developed an immune defense response with antibodies against an ion channel in the brain, a so-called NMDA-type glutamate channel. Particular proteins in the nerve cell membrane are reduced leading to the characteristic disruption in nerve function and synapsis loss. Those affected exhibit memory problems and abnormalities in mood and emotion. Eliminating these antibodies through hemodialysis improved the symptoms in cerebral metabolism in the hippocampus region — a part of the brain that is relevant for memory performance and particularly affected by dementia.

"Through the study results, a completely new approach to diagnosing dementia can possibly result. At the moment we are working on a follow-up study with larger test groups in order to verify our approach even further," explains Harald Prüß. He adds: "The potential promise of this new approach is that completely new perspectives could result for an entire group of people suffering from dementia for whom no specific therapeutic option exists."

Source: Science Daily

ScienceDaily (June 22, 2012) — A longstanding question in brain research is how information is processed in the brain. Neuroscientists at the Charité — Universitätsmedizin Berlin, Cluster of Excellence NeuroCure and University of Newcastle have made a contribution towards answering this question. In a new study, they have shown that signals are generated not only in the cell body of nerve cells, but also in their output extension, the axon. A specific filter cell regulates signal propagation.

These findings have now been published in the journal Science.

Until now it has been assumed that information flow in nerve cells proceeds along a “one-way street.” Electrical impulses are initiated at the cell body and propagate along the axon to the next neuron, where they are received by extensions, the dendrites, acting as antennae. However, the team around Charité researchers Tengis Gloveli and Tamar Dugladze has demonstrated that this model needs to be revised. They discovered that signals can also be initiated in axons, i.e. outside the cell body. This happens during highly synchronous neuronal activity as, for example, in a state of heightened attention. Moreover, these axonally generated signals flow bidirectionally and represent a new principle of information processing: on the one hand, impulses propagate from their origin towards other nerve cells; on the other hand, the signals also backpropagate towards the cell body, i.e. in the “wrong direction” down the one-way street. A potential problem is that backpropagating signals could lead to excessive cell activation.

However, the researchers found that backpropagating signals do not reach the cell body under normal conditions. The reason for this, the scientists discovered, is a natural filter that prevents these signals from passing. “Axo-axonic cells, an inhibitory cell type, regulate signal propagation and thus occupy an outstanding strategic position,” explains Tamar Dugladze. Through the filter function, these cells allow signals initiated at the cell body to pass, but suppress backpropagating impulses generated in the axon. By this means, excessive activation of the cell body is prevented. In experiments, the scientists could show that when this filter function is deactivated, backpropagating signals are allowed to pass, resulting in higher cell activation.

These filter cells can become damaged in various neurological diseases. The consequent misregulation of signal flow, in turn, has fatal effects on information processing in the brain. “Results of this study shed new light on the central question of how signals are processed in the brain. In addition, these findings could help us better understand the development and progress of neuronal diseases such as epilepsy, which involves excessive hypersynchronous activity of large sets of neurons. This knowledge could open up new therapeutic approaches,” says Tengis Gloveli. The neuroscientists will therefore focus their future research on both basic understanding of the mechanisms of signal flow in the nervous system, and the relevance of these mechanisms in the genesis of epilepsy.

Source: Science Daily

ScienceDaily (June 22, 2012) — The gene p53 is the most commonly mutated gene in cancer. p53 is dubbed the “guardian of the genome” because it blocks cells with damaged DNA from propagating and eventually becoming cancerous. However, new research led by Ute M. Moll, M.D., Professor of Pathology at Stony Brook University School of Medicine, and colleagues, uncovers a novel role for p53 beyond cancer in the development of ischemic stroke. The research team identified an unexpected critical function of p53 in activating necrosis, an irreversible form of tissue death, triggered during oxidative stress and ischemia.

Dr. Ute Moll, Professor of Pathology, has uncovered a novel role for p53 in the development of ischemic stroke. (Credit: Image courtesy of Stony Brook Medicine)

The findings are detailed online in Cell.

Ischemia-associated oxidative damage leads to irreversible necrosis which is a major cause of catastrophic tissue loss. Elucidating its signaling mechanism is of paramount importance. p53 is a central cellular stress sensor that responds to multiple insults including oxidative stress and is known to orchestrate apoptotic and autophagic types of cell death. However, it was previously unknown whether p53 can also activate oxidative stress-induced necrosis, a regulated form of cell death that depends on the mitochondrial permeability transition pore (PTP) pore.

"We identified an unexpected and critical function of p53 in activating necrosis: In response to oxidative stress in normal healthy cells, p53 accumulates in the mitochondrial matrix and triggers the opening of the PTP pore at the inner mitochondrial membrane, leading to collapse of the electrochemical gradient and cell necrosis," explains Dr. Moll. "p53 acts via physical interaction with the critical PTP regulator Cyclophylin D (CypD). This p53 action occurs in cultured cells and in ischemic stroke in mice. "

Of note, they found in their model that when the destructive p53-CypD complex is blocked from forming by using Cyclosporine-A type inhibitors, the brain tissue is strongly protected from necrosis and stroke is prevented.

"The findings fundamentally expand our understanding of p53-mediated cell death networks," says Dr. Moll. "The data also suggest that acute temporary blockade of the destructive p53-CypD complex with clinically well-tolerated Cyclosporine A-type inhibitors may lead to a therapeutic strategy to limit the extent of an ischemic stroke in patients."

"p53 is one of the most important genes in cancer and by far the most studied," says Yusuf A. Hannun, M.D., Director of the Stony Brook University Cancer Center, Vice Dean for Cancer Medicine, and the Joel Kenny Professor of Medicine at Stony Brook. "Therefore, this discovery by Dr. Moll and her colleagues in defining the mechanism of a new p53 function and its importance in necrotic injury and stoke is truly spectacular."

Dr. Moll has studied p53 for 20 years in her Stony Brook laboratory. Her research has led to numerous discoveries about the function of p53 and two related genes. For example, previous to this latest finding regarding p53 and stroke, Dr. Moll identified that p73, a cousin to p53, steps in as a tumor suppressor gene when p53 is lost and can stabilize the genome. She found that p73 plays a major developmental role in maintaining the neural stem cell pool during brain formation and adult learning. Her work also helped to identify that another p53 cousin, called p63, has a critical surveillance function in the male germ line and likely contributed to the evolution of humans and great apes, enabling their long reproductive periods.

Source: Science Daily

ScienceDaily (June 22, 2012) — Scientists have discovered that plant compounds from a South African flower may in time be used to treat diseases originating in the brain — including depression. At the University of Copenhagen, a number of these substances have now been tested in a laboratory model of the blood-brain barrier.

Crinum from South Africa. (Credit: Gary I. Stafford)

Scientists at the University of Copenhagen have previously documented that substances from the South African plant species Crinum and Cyrtanthus — akin to snowdrops and daffodils — have an effect on the mechanisms in the brain that are involved in depression. This research has now yielded further results, since a team based at the Faculty of Health and Medical Sciences has recently shown how several South African daffodils contain plant compounds whose characteristics enable them to negotiate the defensive blood-brain barrier that is a key challenge in all new drug development.

"Several of our plant compounds can probably be smuggled past the brain’s effective barrier proteins. We examined various compounds for their influence on the transporter proteins in the brain. This study was made in a genetically-modified cell model of the blood-brain barrier that contains high levels of the transporter P-glycoprotein. Our results are promising, and several of the chemical compounds studied should therefore be tested further, as candidates for long-term drug development," says Associate Professor Birger Brodin.

"The biggest challenge in medical treatment of diseases of the brain is that the drug cannot pass through the blood-brain barrier. The blood vessels of the brain are impenetrable for most compounds, one reason being the very active transporter proteins. You could say that the proteins pump the drugs out of the cells just as quickly as they are pumped in. So it is of great interest to find compounds that manage to ‘trick’ this line of defence."

The results of the study have been published in the Journal of Pharmacy and Pharmacology.

It will nonetheless be a long time before any possible new drug reaches our pharmacy shelves: “This is the first stage of a lengthy process, so it will take some time before we can determine which of the plant compounds can be used in further drug development,” says Birger Brodin.

Yet this does not curb his enthusiasm for the opportunities from the interdisciplinary cooperation with organic scientists from the Department of Drug Design and Pharmacology and the Natural History Museum of Denmark.

"In my research group, we have had a long-term focus on the body’s barrier tissue — and in recent years particularly the transport of drug compounds across the blood-brain barrier. More than 90 per cent of all potential drugs fail the test by not making it through the barrier, or being pumped out as soon as they do get in. Studies of natural therapies are a valuable source of inspiration, giving us knowledge that can also be used in other contexts," Birger Brodin emphasises.

Source: Science Daily

June 22, 2012 By Virat Markandeya

Listening to a single voice in a crowded cocktail party sometimes seems like picking a needle out of a haystack, but new research shows that people may be better at this than expected.

New research shows that people can comprehend one sound among many.

The results surprised the University of Washington, Seattle, research team, which tested how well people could pick out one sound from a dense collection of noises.

The researchers asked ten subjects to listen to multiple streams of letters. A stream consisted of a repeating letter, for example, Q-Q-Q-Q. If four streams were played, the listener heard four different repeating letters, say, D, C, Q and J. The letters came fast —the time interval between each letter was just one-twelfth of a second.

In front of the listener was a computer screen. Before the start of each trial, the researchers put one of the four letters on the screen to prime the subject to focus on it. If he heard an oddball letter in that stream, such as R instead of Q, he was to press a button.

To make it easier on the listener, each letter stream carried a different pitch and came from a different location in the room. R was chosen as the oddball because it doesn’t rhyme with any other letter.  

"Unlike most experiments where you try to make it difficult for the listener to do the task, we tried to give every advantage we could," said Adrian K.C. Lee, a speech and hearing researcher at the university, who worked closely with Ross Maddox.

As expected, when the number of streams went up, the ability to discern the letter came down. But even with 12 streams the letter was identified correctly around 70 percent of the time.

"We expected that 12 streams would have broken the upper limits of the [subject’s hearing] system," said Lee. "It is surprising that even with twelve things coming at you at the same time you can lock on to one with reasonably high accuracy."

The work was presented last month at the Acoustics 2012 Hong Kong conference.

Down the line, the researchers want to use these experiments to design a way for paralyzed patients to control a wheelchair or a computer using brain signals. Such devices, called brain-computer interfaces, have mostly relied on visual or motor stimuli. Typically, a subject might focus on a visual cue or imagine making a movement. Using a machine that detects brain signals, such as an electroencephalogram, researchers would attempt to characterize the brain responses connected with that task and translate them into commands. Focusing on an auditory signal too produces brain signals that can be characterized. However, the current study did not look at brain signals.

A very practical reason to look at auditory interfaces is that eye-gaze control — on which visually-controlled interfaces are based — is often absent in people in a late stage of a neurodegenerative disease, said Martijn Schreuder, a researcher at the Berlin Institute of Technology.

Schreuder, who has worked on an interface where subjects spelled words by focusing on particular sounds, pointed out that auditory interfaces allow someone who is completely blind to communicate.

Schreuder said Lee’s work provides hints on “whether or not it’s good or bad to have different [audio] streams or whether it is good to have a quicker repetition or not.” To his knowledge, this is the first time researchers have gone up to 12 streams. Previous research included only two streams.

The other part Schreuder found interesting was how quickly the listeners learned how to discriminate between letter streams.

"There is a difference between being able to spell one letter every two minutes or spelling three letters per minute, which is the range [brain-computer interfaces] go," Schreuder said. "So if one selection takes 20 seconds, it’s worse than if it goes 10 seconds."

The University of Washington researchers are planning follow-up experiments to directly investigate how the brain responds to audio streams.

Provided by Inside Science News Service

Source: medicalxpress.com

June 22nd, 2012

New research suggests that it is possible to suppress emotional autobiographical memories. The study published this month by psychologists at the University of St Andrews reveals that individuals can be trained to forget particular details associated with emotional memories.

The important findings may offer exciting new potential for therapeutic interventions for individuals suffering from emotional disorders, such as depression and post-traumatic stress disorder.

The research showed that although individuals could still accurately recall the cause of the event, they could be trained to forget the consequences and personal meaning associated with the memory.

The work was carried out by researchers Dr Saima Noreen and Professor Malcolm MacLeod of the University’s School of Psychology. Lead author Dr Noreen explained, “The ability to remember and interpret emotional events from our personal past forms the basic foundation of who we are as individuals.

Research is starting to show that autobiographical memories may be forgotten. This image is adapted from a photograph of a painting. Both are in the public domain. The original painting is translated as The Break-Up Letter and was painted by Alfred Émile Léopold Stevens (ca 1867).

“These novel findings show that individuals can be trained to not think about memories that have personal relevance and significance to them and provide the most direct evidence to date that we possess some kind of control over autobiographical memory.”

The research involved participants generating emotional memories in response to generic cue words, such as theatre, barbecue, wildlife etc. Participants were asked to recall the cause of the event, the consequence of the event and the personal meaning they derived from the event.

Subjects were then asked to provide a single word that was personal to them which reminded them of the memory. In a subsequent session, participants were shown the cue and personal word pairings and were asked to either recall the memory associated with the word pair or to not think about the associated memory.

Interestingly, the findings revealed that whilst the entire autobiographical episode was not forgotten, the details associated with the memory were. Specifically, individuals could remember what caused the event, but were able to forget what happened and how it made them feel.

Co-author Professor MacLeod commented, “The capacity to engage in this kind of intentional forgetting may be critical to our ability to maintain coherent images about who we are and what we are like”.

Source: Neuroscience News

June 22, 2012

The hormone oxytocin - often referred to as the “trust” hormone or “love hormone” for its role in stimulating emotional responses - plays an important role in Williams syndrome (WS), according to a study published June 12, 2012, in PLoS One.

The study, a collaboration between scientists at the Salk Institute for Biological Studies and the University of Utah, found that people with WS flushed with the hormones oxytocin and arginine vasopressin (AVP) when exposed to emotional triggers.

The findings may help in understanding human emotional and behavioral systems and lead to new treatments for devastating illnesses such as WS, post-traumatic stress disorder, anxiety and possibly even autism.

“Williams syndrome results from a very clear genetic deletion, allowing us to explore the genetic and neuronal basis of social behavior,” says Ursula Bellugi, the director of Salk’s Laboratory for Cognitive Neuroscience and a co-author on the paper. “This study provides us with crucial information about genes and brain regions involved in the control of oxytocin and vasopressin, hormones that may play important roles in other disorders.”

WS arises from a faulty recombination event during the development of sperm or egg cells. As a result, virtually everyone with WS has exactly the same set of genes missing (25 to 28 genes are missing from one of two copies of chromosome 7). There also are rare cases of individuals who retain one or more genes that most people with the disorder have lost.

To children with WS, people are much more comprehensible than inanimate objects. Despite myriad health problems they are extremely gregarious, irresistibly drawn to strangers, and insist on making eye contact. They have an affinity for music. But they also experience heightened anxiety, have an average IQ of 60, experience severe spatial-visual problems, and suffer from cardiovascular and other health issues. Despite their desire to befriend people, they have difficulty creating and maintaining social relationships, something that is not at all understood but can afflict many people without WS.

In the new study, led by Dr. Julie R. Korenberg, a University of Utah professor and Salk adjunct professor, the scientists conducted a trial with 21 participants, 13 who have WS and a control group of eight people without the disorder. The participants were evaluated at the Cedars-Sinai Medical Center in Los Angeles. Because music is a known strong emotional stimulus, the researchers asked participants to listen to music.

Before the music was played, the participants’ blood was drawn to determine a baseline level for oxytocin, and those with WS had three times as much of the hormone as those without the syndrome. Blood also was drawn at regular intervals while the music played and was analyzed afterward to check for real-time, rapid changes in the levels of oxytocin and AVP. Other studies have examined how oxytocin affects emotion when artificially introduced into people, such as through nasal sprays, but this is one of the first significant studies to measure naturally occurring changes in oxytocin levels in rapid, real time as people undergo an emotional response.

There was little outward response to the music, but when the blood samples were analyzed, the researchers were happily surprised. The analyses showed that the oxytocin levels, and to a lesser degree AVP, had not only increased but begun to bounce among WS participants while among those without WS, both the oxytocin and AVP levels remained largely unchanged as they listened to music.

Korenberg believes the blood analyses strongly indicate that oxytocin and AVP are not regulated correctly in people with WS, and that the behavioral characteristics unique to people with WS are related to this problem.

"This shows that oxytocin quite likely is very involved in emotional response," Korenberg says.

To ensure accuracy of results, those taking the test also were asked to place their hands in 60-degree Fahrenheit water to test for negative stress, and the same results were produced as when they listened to music. Those with WS experienced an increase in oxytocin and AVP, while those without the syndrome did not.

In addition to listening to music, study participants already had taken three social behavior tests that evaluate willingness to approach and speak to strangers, emotional states, and various areas of adaptive and problem behavior. Those test results suggest that increased levels of oxytocin are linked to both increased desire to seek social interaction and decreased ability to process social cues, a double-edged message that may be very useful at times, for example, during courtship, but damaging at others, as in WS.

"The association between abnormal levels of oxytocin and AVP and altered social behaviors found in people with Williams Syndrome points to surprising, entirely unsuspected deleted genes involved in regulation of these hormones and human sociability," Korenberg said. "It also suggests that the simple characterization of oxytocin as ‘the love hormone’ may be an overreach. The data paint a far more complicated picture."

In particular, the study results indicate that the missing genes affect the release of oxytocin and AVP through the hypothalamus and the pituitary gland. About the size of a pearl, the hypothalamus is located just above the brain stem and produces hormones that control body temperature, hunger, mood, sex drive, sleep, hunger and thirst, and the release of hormones from many glands, including the pituitary. The pituitary gland, about the size of a pea, controls many other glands responsible for hormone secretion.

Overall, the researchers say, their findings paint a very hopeful picture, and the study holds promise for speeding progress in treating WS, and perhaps Autism and anxiety through regulation of these key players in human brain and emotion, oxytocin and vasopressin.

Provided by Salk Institute

Source: medicalxpress.com

June 22, 2012

Neuropsychiatric conditions such as autism, schizophrenia and epilepsy involve an imbalance between two types of synapses in the brain: excitatory synapses that release the neurotransmitter glutamate, and inhibitory synapses that release the neurotransmitter GABA. Little is known about the molecular mechanisms underlying development of inhibitory synapses, but a research team from Japan and Canada has reported that a molecular signal between adjacent neurons is required for the development of inhibitory synapses.

Figure 1: Compared with the brains of normal animals (left), mice lacking the Slitrk3 gene (right) have a reduced density of inhibitory synapses in the hippocampus. Reproduced from Ref. 1 © 2012 Jun Aruga, RIKEN Brain Science Institute

In earlier work, the researchers—led by Jun Aruga of the RIKEN Brain Science Institute, Wako, and Ann Marie Craig of the University of British Colombia, Vancouver—showed that a membrane protein called Slitrk2 organizes signaling molecules at synapses. They therefore tested whether five related proteins are involved in inhibitory synapse development. They cultured immature hippocampal neurons with non-neural cells expressing each of the six Slitrk proteins. They found that Slitrk3, but not other Slitrk proteins, induced clustering of VGAT, a GABA transporter protein found only at inhibitory synapses.

The researchers also examined the localization of Slitrk3 by tagging it with yellow fluorescent protein and introducing it into cultured hippocampal cells. This revealed that Slitrk3 co-localizes in the dendrites of neurons with gephyrin, a scaffold protein found only in inhibitory synapses. They then blocked Slitrk3 synthesis, and found that it led to a significant reduction in the number of inhibitory synapses.

To confirm these findings, the researchers generated a strain of genetically engineered mice lacking the Slitrk3 gene. These animals had significantly fewer inhibitory synapses than normal animals (Fig. 1), and therefore impaired neurotransmission of GABA. They were also susceptible to epileptic seizures. From a screen for proteins that bind to Slitrk3, Aruga, Craig and colleagues identified the protein PTPδ as its only binding partner. Introduction of PTPδ fused to yellow fluorescent protein to cultured hippocampal neurons showed that it is expressed in neuronal dendrites and cell bodies, but not in axons. Blocking PTPδ synthesis prevented the induction of inhibitory synapses by the Slitrk3 protein.

These results demonstrated that the interaction between Slitrk3 on dendrites and PTPδ on axons of adjacent cells is required for the proper development of inhibitory synapses and for inhibitory neurotransmission in the brain.

“We are now examining whether the balance of excitatory and inhibitory synapses is affected by other members of the Slitrk protein family,” says Aruga. “It is possible that Slitrk3 and other Slitrk proteins are acting synergistically or antagonistically. We are also clarifying whether Slitrk3 is involved in any neurological disorders.”

Provided by RIKEN

Source: medicalxpress.com

ScienceDaily (June 21, 2012) — Preventing diabetes or delaying its onset has been thought to stave off cognitive decline — a connection strongly supported by the results of a 9-year study led by researchers at the University of California, San Francisco (UCSF) and the San Francisco VA Medical Center.

Earlier studies have looked at cognitive decline in people who already had diabetes. The new study is the first to demonstrate that the greater risk of cognitive decline is also present among people who develop diabetes later in life. It is also the first study to link the risk of cognitive decline to the severity of diabetes.

The result is the latest finding to emerge from the Health, Aging, and Body Composition (Health ABC) Study, which enrolled 3,069 adults over 70 at two community clinics in Memphis, TN and Pittsburgh, PA beginning in 1997. All the patients provided periodic blood samples and took regular cognitive tests over time.

When the study began, hundreds of those patients already had diabetes. A decade later, many more of them had developed diabetes, and many also suffered cognitive decline. As described this week in Archives of Neurology, those two health outcomes were closely linked.

People who had diabetes at the beginning of the study showed a faster cognitive decline than people who developed it during the course of the study — and these people, in turn, tended to be worse off than people who never developed diabetes at all. The study also showed that patients with more severe diabetes who did not control their blood sugar levels as well suffered faster cognitive declines.

"Both the duration and the severity of diabetes are very important factors," said Kristine Yaffe, MD, the lead author of the study. "It’s another piece of the puzzle in terms of linking diabetes to accelerated cognitive aging."

An important question for future studies, she added, would be to ask if interventions that would effectively prevent, delay or better control diabetes would also lower people’s risk of cognitive impairment later in life.

Yaffe is the Roy and Marie Scola Endowed Chair of Psychiatry; professor in the UCSF departments of Psychiatry, Neurology and Epidemiology and Biostatistics; and Chief of Geriatric Psychiatry and Director of the Memory Disorders Clinic at the San Francisco VA Medical Center.

Diabetes and Cognitive Decline

Diabetes is a chronic and complex disease marked by high levels of sugar in the blood that arise due to problems with the hormone insulin, which regulates blood sugar levels. It is caused by an inability to produce insulin (type 1) or an inability to respond correctly to insulin (type 2).

A major health concern in the United States, diabetes of all types affects an estimated 8.3 percent of the U.S. population — some 25.8 million Americans — and costs U.S. taxpayers more than $200 billion annually. In California alone, an estimated 4 million people (one out of every seven adults) has type 2 diabetes and millions more are at risk of developing it. These numbers are poised to explode in the next half century if more is not done to prevent the disease.

Over the last several decades, scientists have come to appreciate that diabetes affects many tissues and organs of the body, including the brain and central nervous system — particularly because diabetes places people at risk of cognitive decline later in life.

In their study the scientists looked at a blood marker known as “glycosylated hemoglobin,” a standard measure of the severity of diabetes and the ability to control it over time. The marker shows evidence of high blood sugar because these sugar molecules become permanently attached to hemoglobin proteins in the blood. Yaffe and her colleagues found that greater levels of this biomarker were associated with more severe cognitive dysfunction.

While the underlying mechanism that accounts for the link between diabetes and risk of cognitive decline is not completely understood, Yaffe said, it may be related to a human protein known as insulin degrading enzyme, which plays an important role in regulating insulin, the key hormone linked to diabetes. This same enzyme also degrades a protein in the brain known as beta-amyloid, a brain protein linked to Alzheimer’s disease.

Source: Science Daily

ScienceDaily (June 21, 2012) — Scientists have developed a small-molecule-inhibiting drug that in early laboratory cell tests stopped breast cancer cells from spreading and also promoted the growth of early nerve cells called neurites.

Researchers from Cincinnati Children’s Hospital Medical Center report their findings online June 21 in Chemistry & Biology. The scientists named their lead drug candidate “Rhosin” and hope future testing shows it to be promising for the treatment of various cancers or nervous system damage.

The inhibitor overcomes a number of previous scientific challenges by precisely targeting a single component of a cell signaling protein complex called Rho GTPases. This complex regulates cell movement and growth throughout the body. Miscues in Rho GTPase processes are also widely implicated in human diseases, including various cancers and neurologic disorders.

"Although still years from clinical development, in principle Rhosin could be useful in therapy for many kinds of cancer or possibly neuron and spinal cord regeneration," said Yi Zheng, PhD, lead investigator and director of Experimental Hematology and Cancer Biology at Cincinnati Children’s. "We’ve performed in silica (computerized) rational drug design, pharmacological characterization and cell tests in the laboratory, and we are now starting to work with mouse models."

Because the role of Rho GTPases in cellular processes and cancer formation is well established, researchers have spent years trying to identify safe and effective therapeutic targets for specific parts of the protein complex. In particular, scientists have focused on the center protein in the complex called RhoA, which is essential for the signaling function of the complex. In breast cancer for example, increased RhoA activity makes the cancer cells more invasive and causes them to spread, while a deficiency of RhoA suppresses cancer growth and progression.

Despite this knowledge, past efforts to develop an effective small-molecule inhibitor for RhoA have failed, explained Zheng, who has studied Rho GTPases for over two decades. Most roadblocks stem from a lack of specificity in how researchers have been able to target RhoA, a resulting lack of efficiency in affecting molecular processes, problems with toxicity, and the inability to find a workable drug design.

For the current study, Zheng and his colleagues started with the extensive body of research from Cincinnati Children’s and other institutions describing the processes and functions of Rho GTPases. They then used high-throughput computerized molecular screening and computerized drug design to reveal a druggable target site. This also provided a preliminary virtual simulation on the potential effectiveness of candidate drugs.

A key challenge to binding a small-molecule inhibitor to RhoA is the protein’s globular structure and lack of surface pocket areas suitable for easy binding, Zheng said. The unique chemical structure of the lead compound identified by researchers, Rhosin, allows it to effectively bind to two shallow surface grooves on RhoA. This enables the candidate drug to take root and begin affecting cells. The two-legged configuration of Rosin also describes a useful drug design strategy for more effectively targeting difficult molecular sites like RhoA.

The researchers also wanted to make sure Rhosin effectively blocked what are known as guanine nucleotide exchange factors (GEFs). Guanine nucleotide is a critical energy source and signaling component of cells. Activation of GEFs is required to set off the regulatory signaling of GTPases (GTP stands for guanosine triphosphate).

After conducting a series of laboratory cell tests to verify the targeting and binding capabilities of Rhosin to RhoA, the researchers then tested the candidate drug’s impact on cultured breast cancer cells and nerve cells.

In tests on a human breast cancer cells, Rhosin inhibited cell growth and the formation of mammary spheres in a dose dependent manner, acting specifically on RhoA molecular targets without disrupting other critical cellular processes. Rhosin does not affect non-cancerous breast cells. This, along with other tests the scientists performed, indicated Rhosin’s effectiveness in targeting RhoA-mediated breast cancer proliferation, according to the researchers.

Researchers also treated an extensively tested line of neuronal cells with Rhosin, along with nerve growth factor, a protein that is important to the growth and survival of neurons. Rhosin worked with nerve growth factor in a dose-dependent way to promote the proliferation of branching neurites from the neuronal cells. Neurites are young or early stage extensions from neurons required for neuronal communications.

Source: Science Daily

ScienceDaily (June 21, 2012) — Eating disorders are commonly seen as an issue faced by teenagers and young women, but a new study reveals that age is no barrier to disordered eating. In women aged 50 and over, 3.5% report binge eating, nearly 8% report purging, and more than 70% are trying to lose weight. The study published in the International Journal of Eating Disorders revealed that 62% of women claimed that their weight or shape negatively impacted on their life.

The researchers, led by Dr Cynthia Bulik, Director of the University of North Carolina Eating Disorders Program, reached 1,849 women from across the USA participating in the Gender and Body Image Study (GABI) with a survey titled, ‘Body Image in Women 50 and Over — Tell Us What You Think and Feel.’

"We know very little about how women aged 50 and above feel about their bodies," said Bulik. "An unfortunate assumption is that they ‘grow out of’ body dissatisfaction and eating disorders, but no one has really bothered to ask. Since most research focuses on younger women, our goal was to capture the concerns of women in this age range to inform future research and service planning."

The average age of the participants was 59, while 92% were white. More than a quarter, 27%, were obese, 29% were overweight, 42% were normal weight and 2% were underweight.

Results revealed that eating disorder symptoms were common. About 8% of women reported purging in the last five years and 3.5% reported binge eating in the last month. These behaviors were most prevalent in women in their early 50s, but also occurred in women over 75.

When it came to weight issues, 36% of the women reported spending at least half their time in the last five years dieting, 41% checked their body daily and 40% weighed themselves a couple of times a week or more.

62% of women claimed that their weight or shape negatively impacted their life, 79% said that it affected their self-perception and 64% said that they thought about it daily.

The women reported resorting to a variety of unhealthy methods to change their body, including diet pills (7.5%), excessive exercise (7%), diuretics (2.5%), laxatives (2%) and vomiting (1%).

Two-thirds, 66%, were unhappy with their overall appearance and this was highest when it came to their stomach, 84%, and shape, 73%.

"The bottom line is that eating disorders and weight and shape concerns don’t discriminate on the basis of age," concluded Bulik. "Healthcare providers should remain alert for eating disorder symptoms and weight and shape concerns that may adversely influence women’s physical and psychological wellbeing as they mature."

Source: Science Daily

ScienceDaily (June 21, 2012) — A pioneering report of genome-wide gene expression in autism spectrum disorders (ASDs) finds genetic changes that help explain why one person has an ASD and another does not. The study, published by Cell Press on June 21 in The American Journal of Human Genetics, pinpoints ASD risk factors by comparing changes in gene expression with DNA mutation data in the same individuals. This innovative approach is likely to pave the way for future personalized medicine, not just for ASD but also for any disease with a genetic component.

ASDs are a heterogeneous group of developmental conditions characterized by social deficits, difficulty communicating, and repetitive behaviors. ASDs are thought to be highly heritable, meaning that they run in families. However, the genetics of autism are complex.

Researchers have found rare changes in the number of copies of defined genetic regions that associate with ASD. Although there are some hot-spot regions containing these alterations, very few genetic changes are exactly alike. Similarly, no two autistic people share the exact same symptoms. To discover how these genetic changes might affect gene transcription and, thus, the presentation of the disorder, Rui Luo, a graduate student in the Geschwind lab at UCLA, studied 244 families in which one child (the proband) was affected with an ASD and one was not.

In addition to identifying several potential new regions where copy-number variants (CNVs) are associated with ASDs, Geschwind’s team found genes within these regions to be significantly misregulated in ASD children compared with their unaffected siblings. “Strikingly, we observed a higher incidence of haploinsufficient genes in the rare CNVs in probands than in those of siblings, strongly indicating a functional impact of these CNVs on expression,” says Geschwind. Haploinsuffiency occurs when only one copy of a gene is functional; the result is that the body cannot produce a normal amount of protein. The researchers also found a significant enrichment of misexpressed genes in neural-related pathways in ASD children. Previous research has found that these pathways include other genetic variants associated with autism, which Geschwind explains further legitimizes the present findings.

Source: Science Daily

June 21, 2012 By Janice Wood

Thanks to science, we know that love lives in the brain, not the heart.

Now a new international study has mapped out where love and sexual desire are in the brain.

“No one has ever put these two together to see the patterns of activation,” says Dr. Jim Pfaus, professor of psychology at Concordia University.

“We didn’t know what to expect –the two could have ended up being completely separate. It turns out that love and desire activate specific but related areas in the brain.”

Working with colleagues in the United States and Switzerland, Pfaus analyzed the results of 20 separate studies that examined brain activity while subjects engaged in tasks such as viewing erotic pictures or looking at photographs of their significant others. Pooling this data enabled the scientists to form a map of love and desire in the brain.

They found that two brain structures, the insula and the striatum, are responsible for tracking the progression from sexual desire to love.

The insula is a portion of the cerebral cortex folded deep within an area between the temporal lobe and the frontal lobe, while the striatum is located nearby, inside the forebrain.

According to the researchers, love and sexual desire activate different areas of the striatum. The area activated by sexual desire is usually turned on by things that are inherently pleasurable, such as sex or food.

The area activated by love is involved in the process of conditioning in which things paired with reward or pleasure are given inherent value. That is, as feelings of sexual desire develop into love, they are processed in a different place in the striatum, the researchers explain.

This area of the striatum is also the part of the brain associated with drug addiction. Pfaus says there is good reason for this.

“Love is actually a habit that is formed from sexual desire as desire is rewarded,” he explains. “It works the same way in the brain as when people become addicted to drugs.”

However, the habit is not a bad one, he said, noting that love activates different pathways in the brain that are involved in monogamy and pair bonding. Some areas in the brain are actually less active when a person feels love than when they feel desire, he added.

“While sexual desire has a very specific goal, love is more abstract and complex, so it’s less dependent on the physical presence someone else,” says Pfaus.

Source: PsychCentral

June 20, 2012 By Robin Erb

Go ahead - do it: Grab a pencil. Right now. Write your name backward. And upside down. Awkward, right?

But if researchers and neurologists are correct, doing exercises like these just might buy you a bit more time with a healthy brain.

Some research suggests that certain types of mental exercises - whether they are memory games on your mobile device or jotting down letters backward - might help our gray matter maintain concentration, memory and visual and spatial skills over the years.

"There is some evidence of a use-it-or-lose-it phenomenon," says Dr. Michael Maddens, chief of medicine at Beaumont Hospital, Royal Oak, Mich.

Makers of computer brain games, in fact, are tapping into a market of consumers who have turned to home treadmills and gym memberships to maintain their bodies, and now worry that aging might take its toll on their mental muscle as well.

But tweaking every day routines can help.

Like brushing your teeth with your non-dominant hand. Or crossing your arms the opposite way you’re used to, says Cheryl Deep, who leads “Brain Neurobics” sessions on behalf of the Wayne State Institute of Gerontology.

At a recent session in Novi, Mich., Deep encouraged several dozen senior citizens to flip the pictures in their homes upside-down. It might baffle houseguests, but the exercise crowbars the brain out of familiar grooves cut deep by years of mindless habit.

"Every time you walk past and look, your brain has to rotate that image," Deep says. "Brain neurobics is about getting us out of those ruts, those pathways, and shaking things up."

Participants were asked to call out the color of ink that flashed on a screen in front them. The challenge: The colors spelled out names of other colors. Blue ink spelled o-r-a-n-g-e, for example.

Several in the crowd at Waltonwood Senior Living hesitated - a few scrunching up faces in concentration. The first instinct is to say “orange.”

In another exercise, participants had to try to name as many red foods as possible. Apple? Sure that’s an easy one. It took a while, but the crowd eventually made its way to pomegranate and pimento.

Elissa and Hal Leider chuckled with friends as they tested their recall.

Hal Leider, 82, a retired carpenter, was diagnosed with early-stage Alzheimer’s, and he tries to challenge himself mentally and physically - bowling and shooting pool and playing poker: “I think anything we can do might be helpful,” says Elissa Leider, 74.

The idea of mental workouts marks a dramatic shift in how we understand the brain these days.

"We want to stretch and flex and push" the brain, says Moriah Thomason, assistant professor in Wayne State University School of Medicine’s pediatrics department and in the Merrill Palmer Skillman Institute for Child and Family Development

Thomason also is a scientific adviser to http://www.Lumosity.com, one of the fastest-growing brain game websites.

"We used to think that what you’re born with is what you have through life. But now we understand that the brain is a lot more plastic and flexible than we ever appreciated," she says.

Still, like the rest of your body, aging takes its toll, she says.

The protective covering of the neural cells - white matter - begins to shrink first. Neural and glial cells, often called the gray matter, begin to shrink as well, but more slowly. Neurotransmitters, or chemical messengers, decrease.

But challenging the brain stimulates neural pathways - those tentacles that look like tree branches in a cluster of brain cells. It boosts the brain’s chemistry and connectivity, refueling the entire engine.

"Certain activities will lay more neural pathways that can be more readily re-engaged," Thomason says. "The hope is that there are ways to train and strengthen these pathways."

Maddens explains it this way: Consider the neurons of your brain like electrical wires and the white matter like the insulation. When the insulation breaks down over time, things can misfire.

In labs, those who engaged in mentally challenging games do, in fact, show improvement in cognitive functioning. They get faster at speed games and stronger in memory games, for example.

What’s less clear is whether this improvement transfers to everyday tasks, like remembering where you parked the car or the name of your child’s teacher, both Thomason and Maddens say.

But when it comes to the link between physical exercise and the brain, researchers and clinicians agree: physical exercise is good for the brain; it has also been linked to lower rates of chronic disease. Good nutrition is essential too.

Oxygen, itself, is essential, Deep said: “Your brain is an oxygen hog.”

Diet, exercise and mental maneuvers all may boost brain health in ways science still doesn’t understand. In the best cases, the right mix might stave off the effects of Alzheimer’s and other age-related disease too, Maddens says.

All this is good news for an aging, stressed out, and too-busy society, he says.

Reading a book, engaging with friends or going out for a walk and paying attention to what’s around you - that’s not really about goofing off. Rather, it’s critical time that stimulates neural pathways and boosts the odds of long-time brain health.

"It’s talking to friends. It’s getting out socially. It’s engaging in life. The question is ‘How do I force myself to learn?’" Thomason says.

The same might be true when it comes to mentally changing computer games.

Says Maddens: “Would I have patients playing computer games eight hours a day in hopes that they can delay Alzheimer’s by two months? No. But you can enjoy (playing such games) and possibly get a benefit from it, too.”

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ScienceDaily (June 20, 2012) — Most of us assume that confidence and certainty are preferred over uncertainty and bewilderment when it comes to learning complex information. But a new study led by Sidney D’Mello of the University of Notre Dame shows that confusion when learning can be beneficial if it is properly induced, effectively regulated and ultimately resolved.

Most of us assume that confidence and certainty are preferred over uncertainty and bewilderment when it comes to learning complex information. But a new study shows that confusion when learning can be beneficial if it is properly induced, effectively regulated and ultimately resolved. (Credit: © Ana Blazic Pavlovic / Fotolia)

The study will be published in a forthcoming issue of the journal Learning and Instruction.

Notre Dame psychologist and computer scientist D’Mello, whose research areas include artificial intelligence, human-computer interaction and the learning sciences, together with Art Graesser of the University of Memphis, collaborated on the study, which was funded by the National Science Foundation.

They found that by strategically inducing confusion in a learning session on difficult conceptual topics, people actually learned more effectively and were able to apply their knowledge to new problems.

In a series of experiments, subjects learned scientific reasoning concepts through interactions with computer-animated agents playing the roles of a tutor and a peer learner. The animated agents and the subject engaged in interactive conversations where they collaboratively discussed the merits of sample research studies that were flawed in one critical aspect. For example, one hypothetical case study touted the merits of a diet pill, but was flawed because it did not include an appropriate control group. Confusion was induced by manipulating the information the subjects received so that the animated agents sometimes disagreed with each other and expressed contradictory or incorrect information. The agents then asked subjects to decide which opinion had more scientific merit, thereby putting the subject in the hot spot of having to make a decision with incomplete and sometimes contradictory information.

In addition to the confusion and uncertainty triggered by the contradictions, subjects who were confused scored higher on a difficult post-test and could more successfully identify flaws in new case studies.

"We have been investigating links between emotions and learning for almost a decade, and find that confusion can be beneficial to learning if appropriately regulated because it can cause learners to process the material more deeply in order to resolve their confusion," D’Mello says.

According to D’Mello, it is not advisable to intentionally confuse students who are struggling or induce confusion during high-stakes learning activities. Confusion interventions are best for higher-level learners who want to be challenged with difficult tasks, are willing to risk failure, and who manage negative emotions when they occur.

"It is also important that the students are productively instead of hopelessly confused. By productive confusion, we mean that the source of the confusion is closely linked to the content of the learning session, the student attempts to resolve their confusion, and the learning environment provides help when the student struggles. Furthermore, any misleading information in the form of confusion-induction techniques should be corrected over the course of the learning session, as was done in the present experiments."

According to D’Mello, the next step in this body of research is to apply these methods to some of the more traditional domains such as physics, where misconceptions are common.

Source: Science Daily

ScienceDaily (June 20, 2012) — Most of us have experienced it. You are introduced to someone, only to forget his or her name within seconds. You rack your brain trying to remember, but can’t seem to even come up with the first letter. Then you get frustrated and think, “Why is it so hard for me to remember names?”

You may think it’s just how you were born, but that’s not the case, according to Kansas State University’s Richard Harris, professor of psychology. He says it’s not necessarily your brain’s ability that determines how well you can remember names, but rather your level of interest.

"Some people, perhaps those who are more socially aware, are just more interested in people, more interested in relationships," Harris said. "They would be more motivated to remember somebody’s name."

This goes for people in professions like politics or teaching where knowing names is beneficial. But just because someone can’t remember names doesn’t mean they have a bad memory.

"Almost everybody has a very good memory for something," Harris said.

The key to a good memory is your level of interest, he said. The more interest you show in a topic, the more likely it will imprint itself on your brain. If it is a topic you enjoy, then it will not seem like you are using your memory.

For example, Harris said a few years ago some students were playing a geography game in his office. He started to join in naming countries and their capitals. Soon, the students were amazed by his knowledge, although Harris didn’t understand why. Then it dawned on him that his vast knowledge of capitals didn’t come from memorizing them from a map, but rather from his love of stamps and learning their whereabouts.

"I learned a lot of geographical knowledge without really studying," he said.

Harris said this also explains why some things seem so hard to remember — they may be hard to understand or not of interest to some people, such as remembering names.

Harris said there are strategies for training your memory, including using a mnemonic device.

"If somebody’s last name is Hefty and you notice they’re left-handed, you could remember lefty Hefty," he said.

Another strategy is to use the person’s name while you talk to them — although the best strategy is simply to show more interest in the people you meet, he said.

Source: Science Daily

June 20, 2012

A “brain pacemaker” called deep brain stimulation (DBS) remains an effective treatment for Parkinson’s disease for at least three years, according to a study in the June 2012 online issue of Neurology, the medical journal of the American Academy of Neurology.

But while improvements in motor function remained stable, there were gradual declines in health-related quality of life and cognitive abilities.

First author of the study is Frances M. Weaver, PhD, who has joint appointments at Edward Hines Jr. VA Hospital and Loyola University Chicago Stritch School of Medicine.

Weaver was one of the lead investigators of a 2010 paper in the New England Journal of Medicine that found that motor functions remained stable for two years in DBS patients. The new additional analysis extended the follow-up period to 36 months.

DBS is a treatment for Parkinson’s patients who no longer benefit from medication, or who experience unacceptable side effects. DBS is not a cure, and it does not stop the disease from progressing. But in the right patients, DBS can significantly improve symptoms, especially tremors. DBS also can relieve muscle rigidity that causes decreased range of motion.

In the DBS procedure, a neurosurgeon drills a dime-size hole in the skull and inserts an electrode about 4 inches into the brain. A connecting wire from the electrode runs under the skin to a battery implanted near the collarbone. The electrode delivers mild electrical signals that effectively reorganize the brain’s electrical impulses. The procedure can be done on one or both sides of the brain.

Researchers evaluated 89 patients who were stimulated in a part of the brain called the globus pallidus interna and 70 patients who were stimulated in a different part of the brain called the subthalamic nucleus. (Patients received DBS surgery at seven VA and six affiliated university medical centers.) Patients were assessed at baseline (before DBS surgery) and at 3, 6, 12, 18, 24 and 36 months. Patients were rated on a Parkinson’s disease scale that includes motor functions such as speech, facial expression, tremors, rigidity, finger taps, hand movements, posture, gait, bradykinesia (slow movement) etc. The lower the rating, the better the function.

Improvements in motor function were similar in both groups of patients, and stable over time. Among patients stimulated in the globus pallidus interna, the score improved from 41.1 at baseline to 27.1 at 36 months. Among patients stimulated in the subthalamic nucleus, the score improved from 42.5 at baseline to 29.7 at 36 months.

By contrast, some early gains in quality of life and the abilities to do the activities of daily living were gradually lost, and there was a decline in neurocognitive function. This likely reflects the progression of the disease, and the emergence of symptoms that are resistant to DBS and medications.

Researchers concluded that both the globus pallidus interna and the subthalamic nucleus areas of the brain “are viable DBS targets for treatment of motor symptoms, but highlight the importance of nonmotor symptoms as determinants of quality of life in people with Parkinson’s disease.”

Source: medicalxpress.com

June 20, 2012

With a single drug treatment, researchers at the Ludwig Institute for Cancer Research at the University of California, San Diego School of Medicine can silence the mutated gene responsible for Huntington’s disease, slowing and partially reversing progression of the fatal neurodegenerative disorder in animal models.

This image shows stained mouse neurons. Credit: Image courtesy of Taylor Bayouth

The findings are published in the June 21, 2012 online issue of the journal Neuron.

Researchers suggest the drug therapy, tested in mouse and non-human primate models, could produce sustained motor and neurological benefits in human adults with moderate and severe forms of the disorder. Currently, there is no effective treatment.

Huntington’s disease afflicts approximately 30,000 Americans, whose symptoms include uncontrolled movements and progressive cognitive and psychiatric problems. The disease is caused by the mutation of a single gene, which results in the production and accumulation of toxic proteins throughout the brain.

Don W. Cleveland, PhD, professor and chair of the UC San Diego Department of Cellular and Molecular Medicine and head of the Laboratory of Cell Biology at the Ludwig Institute for Cancer Research, and colleagues infused mouse and primate models of Huntington’s disease with one-time injections of an identified DNA drug based on antisense oligonucleotides (ASOs). These ASOs selectively bind to and destroy the mutant gene’s molecular instructions for making the toxic huntingtin protein.

The singular treatment produced rapid results. Treated animals began moving better within one month and achieved normal motor function within two. More remarkably, the benefits persisted, lasting nine months, well after the drug had disappeared and production of the toxic proteins had resumed.

"For diseases like Huntington’s, where a mutant protein product is tolerated for decades prior to disease onset, these findings open up the provocative possibility that transient treatment can lead to a prolonged benefit to patients,” said Cleveland. “This finding raises the prospect of a ‘huntingtin holiday,’ which may allow for clearance of disease-causing species that might take weeks or months to re-form. If so, then a single application of a drug to reduce expression of a target gene could ‘reset the disease clock,’ providing a benefit long after huntingtin suppression has ended.”

Beyond improving motor and cognitive function, researchers said the ASO treatment also blocked brain atrophy and increased lifespan in mouse models with a severe form of the disease. The therapy was equally effective whether one or both huntingtin genes were mutated, a positive indicator for human therapy.

Cleveland noted that the approach was particularly promising because antisense therapies have already been proven safe in clinical trials and are the focus of much drug development. Moreover, the findings may have broader implications, he said, for other “age-dependent neurodegenerative diseases that develop from exposure to a mutant protein product” and perhaps for nervous system cancers, such as glioblastomas.

Provided by University of California - San Diego

Source: medicalxpress.com

June 20, 2012

Researchers from Boston University School of Medicine (BUSM) have demonstrated in experimental models that blocking the Sigma-1 receptor, a cellular protein, reduced binge eating and caused binge eaters to eat more slowly. The research, which is published online in Neuropsychopharmacology, was led by Pietro Cottone, PhD, and Valentina Sabino, PhD, both assistant professors in the pharmacology and psychiatry departments at BUSM.

Binge eating disorder, which affects approximately 15 million Americans, is believed to be the eating disorder that most closely resembles substance dependence. In binge eating subjects, normal regulatory mechanisms that control hunger do not function properly. Binge eaters typically gorge on “junk” foods excessively and compulsively despite knowing the adverse consequences, which are physical, emotional and social in nature. In addition, binge eaters typically experience distress and withdrawal when they abstain from junk food.

The researchers developed an experimental model of compulsive binge eating by providing a sugary, chocolate diet only for one hour a day while the control group was given a standard laboratory diet. Within two weeks, the group exposed to the sugary diet exhibited binge eating behavior and ate four times as much as the controls. In addition, the experimental binge eaters exhibited compulsive behavior by putting themselves in a potentially risky situation in order to get to the sugary food while the control group avoided the risk.

The researchers then tested whether a drug that blocks the Sigma-1 receptor could reduce binge eating of the sugary diet. The experimental data showed the drug successfully reduced binge eating by 40 percent, caused the binge eaters to eat more slowly and blocked the risky behavior.

The abnormal, risky behavior exhibited by the binge eating experimental group suggested to the researchers that there could be something wrong with how decisions were made. Because evaluation of risks and decision making are functions executed in the prefronto-cortical regions of the brain, the researchers tested whether the abundance of Sigma-1 receptors in those regions was abnormal in the binge eaters. They found that Sigma-1 receptor expression was unusually high in those areas, which could explain why blocking its function could decrease both compulsive binge eating and risky behavior.

"These findings suggest that the Sigma-1 receptor may contribute to the neurobiological adaptations that cause compulsive-like eating, opening up a new potential therapeutic treatment target for binge eating disorder,” said Cottone, who also co-directs the Laboratory of Addictive Disorders at BUSM with Sabino.

Provided by Boston University Medical Center

Source: medicalxpress.com

ScienceDaily (June 20, 2012) — A protein required to regrow injured peripheral nerves has been identified by researchers at Washington University School of Medicine in St. Louis.

These are images of axon regeneration in mice two weeks after injury to the hind leg’s sciatic nerve. On the left, axons (green) of a normal mouse have regrown to their targets (red) in the muscle. On the right, a mouse lacking DLK shows no axons have regenerated, even after two weeks. (Credit: Jung Eun Shin)

The finding, in mice, has implications for improving recovery after nerve injury in the extremities. It also opens new avenues of investigation toward triggering nerve regeneration in the central nervous system, notorious for its inability to heal.

Peripheral nerves provide the sense of touch and drive the muscles that move arms and legs, hands and feet. Unlike nerves of the central nervous system, peripheral nerves can regenerate after they are cut or crushed. But the mechanisms behind the regeneration are not well understood.

In the new study, published online June 20 in Neuron, the scientists show that a protein called dual leucine zipper kinase (DLK) regulates signals that tell the nerve cell it has been injured — often communicating over distances of several feet. The protein governs whether the neuron turns on its regeneration program.

"DLK is a key molecule linking an injury to the nerve’s response to that injury, allowing the nerve to regenerate," says Aaron DiAntonio, MD, PhD, professor of developmental biology. "How does an injured nerve know that it is injured? How does it take that information and turn on a regenerative program and regrow connections? And why does only the peripheral nervous system respond this way, while the central nervous system does not? We think DLK is part of the answer."

The nerve cell body containing the nucleus or “brain” of a peripheral nerve resides in the spinal cord. During early development, these nerves send long, thin, branching wires, called axons, out to the tips of the fingers and toes. Once the axons reach their targets (a muscle, for example), they stop extending and remain mostly unchanged for the life of the organism. Unless they’re damaged.

If an axon is severed somewhere between the cell body in the spinal cord and the muscle, the piece of axon that is no longer connected to the cell body begins to disintegrate. Earlier work showed that DLK helps regulate this axonal degeneration. And in worms and flies, DLK also is known to govern the formation of an axon’s growth cone, the structure responsible for extending the tip of a growing axon whether after injury or during development.

The formation of the growth cone is an important part of the early, local response of a nerve to injury. But a later response, traveling over greater distances, proves vital for relaying the signals that activate genes promoting regeneration. This late response can happen hours or even days after injury.

But in mice, unlike worms and flies, DiAntonio and his colleagues found that DLK is not involved in an axon’s early response to injury. Even without DLK, the growth cone forms. But a lack of DLK means the nerve cell body, nestled in the spinal cord far from the injury, doesn’t get the message that it’s injured. Without the signals relaying the injury message, the cell body doesn’t turn on its regeneration program and the growth cone’s progress in extending the axon stalls.

In addition, it was shown many years ago that axons regrow faster after a second injury than axons injured only once. In other words, injury itself increases an axon’s ability to regenerate. Furthering this work, first author Jung Eun Shin, graduate research assistant, and her colleagues found that DLK is required to promote this accelerated growth.

"A neuron that has seen a previous injury now has a different regenerative program than one that has never been damaged," Shin says. "We hope to be able to identify what is different between these two neurons — specifically what factors lead to the improved regeneration after a second injury. We have found that activated DLK is one such factor. We would like to activate DLK in a newly injured neuron to see if it has improved regeneration."

In addition to speeding peripheral nerve recovery, DiAntonio and Shin see possible implications in the central nervous system. It is known for example, that some of the important factors regulated and ramped up by DLK are not activated in the central nervous system.

"Since this sort of signaling doesn’t appear to happen in the central nervous system, it’s possible these nerves don’t ‘know’ when they are injured," DiAntonio says. "It’s an exciting idea — but not at all proven — that activating DLK in the central nervous system could promote its regeneration."

Source: Science Daily

ScienceDaily (June 20, 2012) — Researchers at the RIKEN Brain Science Institute (BSI) in Japan have uncovered two brain signals in the human prefrontal cortex involved in how humans predict the decisions of other people. Their results suggest that the two signals, each located in distinct prefrontal circuits, strike a balance between expected and observed rewards and choices, enabling humans to predict the actions of people with different values than their own.

Figure one shows the neural activity for the simulation of another person: Reward Signal (red) and Action Signal (green). The action signal shown in this figure (green) is in the dorsomedial prefrontal cortex. The activity of reward signal (red) largely overlaps with the activity of the signal for the self-valuation (blue) in the ventromedial prefrontal cortex. (Credit: RIKEN)

Every day, humans are faced with situations in which they must predict what decisions other people will make. These predictions are essential to the social interactions that make up our personal and professional lives. The neural mechanism underlying these predictions, however, by which humans learn to understand the values of others and use this information to predict their decision-making behavior, has long remained a mystery.

Researchers at the RIKEN Brain Science Institute (BSI) in Japan have now shed light on this mystery with a paper to appear in the June 21st issue of Neuron. The researchers describe for the first time the process governing how humans learn to predict the decisions of another person using mental simulation of their mind.

Learning another person’s values and mental processes is often assumed to require simulation of the other’s mind: using one’s own familiar mental processes to simulate unfamiliar processes in the mind of the other. While simple and intuitive, this explanation is hard to prove due to the difficulty in disentangling one’s own brain signals from those of the simulated other.

Research scientists Shinsuke Suzuki and Hiroyuki Nakahara, a Principal Investigator of the Laboratory for Integrated Theoretical Neuroscience at RIKEN BSI, together with their collaborators, set out to disentangle these signals using functional Magnetic Resonance Imaging (fMRI) on humans. First, they studied the behavior of subjects as they played a game by making predictions about the other’s behavior based on the knowledge of others and their decisions. Then they generated a computer model of the simulation process to examine the brain signals underlying the prediction of the other’s behavior.

The authors found that humans simulate the decisions of other people using two brain signals encoded in the prefrontal cortex, an area responsible for higher cognition. One signal involves the estimated value of the reward to the other person, and is called the reward signal, referring to the difference between the other’s values, simulated in one’s mind, and the reward benefit that the other actually received. The other signal is called the action signal, relating to the other’s expected action predicted by the simulation process in one’s mind, and what the other person actually did, which may or may not be different. They found that the reward signal is processed in a part of the brain called the ventromedial prefrontal cortex. The action signal, on the other hand, was found in a separate brain area called the dorsomedial prefrontal cortex.

"Every day, we interact with a variety of other individuals," Suzuki said. "Some may share similar values with us and for those interactions simulation using the reward signal alone may suffice. However, other people with different values may be quite different and then the action signal may become quite important."

Nakahara believes that their approach, using mathematical models based on human behavior with brain imaging, will be useful to answer a wide range of questions about the social functions employed by the brain. “Perhaps we may one day better understand how and why humans have the ability to predict others’ behavior, even those with different characteristics. Ultimately, this knowledge could help improving political, educational, and social systems in human societies.”

Source: Science Daily

ScienceDaily (June 20, 2012) — The human brain can recognize thousands of different objects, but neuroscientists have long grappled with how the brain organizes object representation; in other words, how the brain perceives and identifies different objects. Now researchers at the MIT Computer Science and Artificial Intelligence Lab (CSAIL) and the MIT Department of Brain and Cognitive Sciences have discovered that the brain organizes objects based on their physical size, with a specific region of the brain reserved for recognizing large objects and another reserved for small objects.

This figure shows brain activations while participants view pictures of large and small objects. (Credit: Image courtesy of Massachusetts Institute of Technology, CSAIL)

Their findings, to be published in the June 21 issue of Neuron, could have major implications for fields like robotics, and could lead to a greater understanding of how the brain organizes and maps information.

"Prior to this study, nobody had looked at whether the size of an object was an important factor in the brain’s ability to recognize it," said Aude Oliva, an associate professor in the MIT Department of Brain and Cognitive Sciences and senior author of the study.

"It’s almost obvious that all objects in the world have a physical size, but the importance of this factor is surprisingly easy to miss when you study objects by looking at pictures of them on a computer screen," said Dr. Talia Konkle, lead author of the paper. "We pick up small things with our fingers, we use big objects to support our bodies. How we interact with objects in the world is deeply and intrinsically tied to their real-world size, and this matters for how our brain’s visual system organizes object information."

As part of their study, Konkle and Oliva took 3D scans of brain activity during experiments in which participants were asked to look at images of big and small objects or visualize items of differing size. By evaluating the scans, the researchers found that there are distinct regions of the brain that respond to big objects (for example, a chair or a table), and small objects (for example, a paperclip or a strawberry).

By looking at the arrangement of the responses, they found a systematic organization of big to small object responses across the brain’s cerebral cortex. Large objects, they learned, are processed in the parahippocampal region of the brain, an area located by the hippocampus, which is also responsible for navigating through spaces and for processing the location of different places, like the beach or a building. Small objects are handled in the inferior temporal region of the brain, near regions that are active when the brain has to manipulate tools like a hammer or a screwdriver.

The work could have major implications for the field of robotics, in particular in developing techniques for how robots deal with different objects, from grasping a pen to sitting in a chair.

"Our findings shed light on the geography of the human brain, and could provide insight into developing better machine interfaces for robots," said Oliva.

Many computer vision techniques currently focus on identifying what an object is without much guidance about the size of the object, which could be useful in recognition. “Paying attention to the physical size of objects may dramatically constrain the number of objects a robot has to consider when trying to identify what it is seeing,” said Oliva.

The study’s findings are also important for understanding how the organization of the brain may have evolved. The work of Konkle and Oliva suggests that the human visual system’s method for organizing thousands of objects may also be tied to human interactions with the world. “If experience in the world has shaped our brain organization over time, and our behavior depends on how big objects are, it makes sense that the brain may have established different processing channels for different actions, and at the center of these may be size,” said Konkle.

Oliva, a cognitive neuroscientist by training, has focused much of her research on how the brain tackles scene and object recognition, as well as visual memory. Her ultimate goal is to gain a better understanding of the brain’s visual processes, paving the way for the development of machines and interfaces that can see and understand the visual world like humans do.

"Ultimately, we want to focus on how active observers move in the natural world. We think this not only matters for large-scale brain organization of the visual system, but it also matters for making machines that can see like us," said Konkle and Oliva.

Source: Science Daily

June 20, 2012

Neurons come in an astounding assortment of shapes and sizes, forming a thick inter-connected jungle of cells. Now, UCL neuroscientists have found that there is a simple pattern that describes the tree-like shape of all neurons.

Neurons look remarkably like trees, and connect to other cells with many branches that effectively act like wires in an electrical circuit, carrying impulses that represent sensation, emotion, thought and action.

Over 100 years ago, Santiago Ramon y Cajal, the father of modern neuroscience, sought to systematically describe the shapes of neurons, and was convinced that there must be a unifying principle underlying their diversity.

Cajal proposed that neurons spread out their branches so as to use as little wiring as possible to reach other cells in the network. Reducing the amount of wiring between cells provides additional space to pack more neurons into the brain, and therefore increases its processing power.

New work by UCL neuroscientists, published today in Proceedings of the National Academy of Sciences, has revisited this century-old hypothesis using modern computational methods. They show that a simple computer program which connects points with as little wiring as possible can produce tree-like shapes which are indistinguishable from real neurons - and also happen to be very beautiful. They also show that the shape of neurons follows a simple mathematical relationship called a power law.

Power laws have been shown to be common across the natural world, and often point to simple rules underlying complex structures. Dr Herman Cuntz (UCL Wolfson Institute for Biomedical Research) and colleagues find that the power law holds true for many types of neurons gathered from across the animal kingdom, providing strong evidence for Ramon y Cajal’s general principle.

The UCL team further tested the theory by examining neurons in the olfactory bulb, a part of the brain where new brain cells are constantly being formed. These neurons grow and form new connections even in the adult brain, and therefore provide a unique window into the rules behind the development of neural trees in a mature neural circuit.

The team analysed the change in shape of the newborn olfactory neurons over several days, and found that the growth of these neurons also follow the power law, providing further evidence to support the theory.

Dr Hermann Cuntz said: “The ultimate goal of neuroscience is to understand how the impenetrable neural jungle can give rise to the complexity of behaviour.

"Our findings confirm Cajal’s original far-reaching insight that there is a simple pattern behind the circuitry, and provides hope that neuroscientists will someday be able to see the forest for the trees."

Provided by University College London

Source: medicalxpress.com

ScienceDaily (June 19, 2012) — Fish cannot display symptoms of autism, schizophrenia, or other human brain disorders. However, a team of Whitehead Institute and MIT scientists has shown that zebrafish can be a useful tool for studying the genes that contribute to such disorders.

Zebrafish with certain genes turned off during embryonic development (center and right images) showed abnormalities of brain formation (top row) and axon wiring (bottom row). At left is a normally developing zebrafish embryo. (Credit: Sive Lab)

Led by Whitehead Member Hazel Sive, the researchers set out to explore a group of about two dozen genes known to be either missing or duplicated in about 1 percent of autistic patients. Most of the genes’ functions were unknown, but a new study by Sive and Whitehead postdocs Alicia Blaker-Lee, Sunny Gupta and, Jasmine McCammon, revealed that nearly all of them produced brain abnormalities when deleted in zebrafish embryos.

The findings, published online recently in the journal Disease Models & Mechanisms, should help researchers pinpoint genes for further study in mammals, says Sive, who is also professor of biology and associate dean of MIT’s School of Science. Autism is thought to arise from a variety of genetic defects; this research is part of a broad effort to identify culprit genes and develop treatments that target them.

"That’s really the goal — to go from an animal that shares molecular pathways, but doesn’t get autistic behaviors, into humans who have the same pathways and do show these behaviors," Sive says.

Sive recalls that some of her colleagues chuckled when she first proposed studying human brain disorders in fish, but it is actually a logical starting point, she says. Brain disorders are difficult to study because most of the symptoms are behavioral, and the biological mechanisms behind those behaviors are not well understood, she says.

"We thought that since we really know so little, that a good place to start would be with the genes that confer risk in humans to various mental health disorders, and to study these various genes in a system where they can readily be studied," she says.

Those genes tend to be the same across species — conserved throughout evolution, from fish to mice to humans — though they may control somewhat different outcomes in each species.

In the latest study, Sive and her colleagues focused on a genetic region known as 16p11.2, first identified by Mark Daly, a former Whitehead Fellow who discovered a type of genetic defect known as a copy number variant. A typical genome includes two copies of every gene, one from each parent; copy number variants occur when one of those copies is deleted or duplicated, and this can be associated with pathology.

The central “core” 16p11.2 region includes 25 genes. Both deletions and duplications in this region have been associated with autism, but it was unclear which of the genes might actually produce symptoms of the disease. “At the time, there was an inkling about some of them, but very few,” Sive says.

Sive and her postdocs began by identifying zebrafish genes analogous to the human genes found in this region. (In zebrafish, these genes are not clustered in a single genetic chunk, but are scattered across many chromosomes.) The researchers studied one gene at a time, silencing each with short strands of nucleic acids that target a particular gene and prevent its protein from being produced.

For 21 of the genes, silencing led to abnormal development. Most produced brain deficits, including improper development of the brain or eyes, thinning of the brain, or inflation of the brain ventricles, cavities that contain cerebrospinal fluid. The researchers also found abnormalities in the wiring of axons, the long neural projections that carry messages to other neurons, and in simple behaviors of the fish. The results show that the 16p11.2 genes are very important during brain development, helping to explain the connection between this region and brain disorders.

Furthermore, the researchers were able to restore normal development by treating the fish with the human equivalents of the genes that had been repressed. “That allows you to deduce that what you’re learning in fish corresponds to what that gene is doing in humans. The human gene and the fish gene are very similar,” Sive says.

To figure out which of these genes might have a strong effect in autism or other disorders, the researchers set out to identify genes that produce abnormal development when their activity is reduced by 50 percent, which would happen in someone who is missing one copy of the gene. (This correlation is not seen for most genes, because there are many other checks and balances that regulate how much of a particular protein is made.)

The researchers identified two such genes in the 16p11.2 region. One, called kif22, codes for a protein involved in the separation of chromosomes during cell division, and one, aldolase a, is involved in glycolysis — the process of breaking down sugar to generate energy for the cell.

In work that has just begun, Sive’s lab is working with Stanford University researchers to explore in mice predictions made from the zebrafish study. They are also conducting molecular studies in zebrafish of the pathways affected by these genes, to get a better idea of how defects in these might bring about neurological disorders.

Source: Science Daily

June 19, 2012 By Janice Wood

Why do some people excel in sports, music and managing companies? New research points to uniquely high mind-brain development in those who excel.

“What we have found is an astonishing integration of brain functioning in high performers compared to average-performing controls,” said Fred Travis, Ph.D., director of the Center for Brain, Consciousness, and Cognition at Maharishi University of Management in Fairfield, Iowa.

He claims this research is the “first in the world to show that there is a brain measure of effective leadership.”

In the study, published in the journal Cognitive Processing, researchers found that 20 top-level managers scored higher on three measures — the Brain Integration Scale, Gibbs’s Socio-moral Reasoning questionnaire, and an inventory of peak experiences — compared to 20 low-level managers who served as controls.

“The current understanding of high performance is fragmented,” said co-researcher Harald Harung, Ph.D., of the Oslo and Akershus University College of Applied Sciences in Norway.

“What we have done in our research is to use quantitative and neurophysiological research methods on topics that so far have been dominated by psychology.”

The researchers carried out four studies comparing world-class performers to average performers. This recent study and two others examined top performers in management, sports and classical music. A number of years ago Harung and his colleagues published a study on a variety of professions, such as public administration, management, sports, arts, and education.

The studies include using electroencephalography (EEG) to look at the extent of integration and development of several brain processes.

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