Neuroscience

ScienceDaily (July 13, 2012) — A new study by University of North Carolina School of Medicine researchers found that 31 percent of children identified as at risk for autism spectrum disorders (ASD) at 12 months received a confirmed diagnosis of ASD by age 3 years.

In addition, 85 percent of the children found to be at risk for ASD based on results from the First Year Inventory (FYI), a 63-item questionnaire filled out by their parents, had some other developmental disability or concern by age three, said Grace Baranek, PhD, senior author of the study and an autism researcher with the Program for Early Autism, Research, Leadership and Service (PEARLS) in the Department of Allied Health Sciences at the UNC School of Medicine.

"These results indicate that an overwhelming majority of children who screen positive on the FYI indeed experience some delay in development by age three that may warrant early intervention," she said.

Lead author of the study, Lauren Turner-Brown, PhD, also a researcher with PEARLS and the Carolina Institute for Developmental Disabilities said, “Identification of children at risk for ASD at 12 months could provide a substantial number of children and their families with access to intervention services months or years before they would otherwise receive a traditional diagnosis.”

The First Year Inventory was developed by Grace Baranek, PhD, Linda Watson, EdD, Elizabeth Crais, PhD and J. Steven Reznick, PhD, who are all researchers with PEARLS. All are also co-authors of the study with Turner-Brown, published online ahead of print on July 10, 2012 by Autism: The International Journal of Research & Practice.

In the study, parents of 699 children who had completed the FYI when their child was 12 months old completed additional screening questionnaires when their child reached age 3. In addition, children who were found to be at risk for ASD based on these measures were invited for in-person diagnostic evaluations.

"These findings are encouraging and suggest promise in the approach of using parent report of infant behaviors as a tool for identifying 12-month-olds who are at risk for an eventual diagnosis of ASD," Turner-Brown said.

Source: Science Daily

ScienceDaily (July 12, 2012) — Millions of people suffering from multiple sclerosis, Parkinson’s, muscular dystrophy, spinal cord injuries or amputees could soon interact with their computers and surroundings using just their eyes, thanks to a new device that costs less than £40.

Researchers from Imperial College London demonstrated the functionality of the new system by getting a group of people to play the classic computer game Pong without any kind of handset. (Credit: Image courtesy of Institute of Physics (IOP))

Composed from off-the-shelf materials, the new device can work out exactly where a person is looking by tracking their eye movements, allowing them to control a cursor on a screen just like a normal computer mouse.

The technology comprises an eye-tracking device and “smart” software that have been presented July 13, in IOP Publishing’s Journal of Neural Engineering. Researchers from Imperial College London demonstrated its functionality by getting a group of people to play the classic computer game Pong without any kind of handset. In addition users were able to browse the web and write emails “hands-off.”

A video of somebody using the device to play Pong can be viewed here (https://www.youtube.com/watch?v=zapK5wvYU84)

The GT3D device is made up of two fast video game console cameras, costing less than £20 each, that are attached, outside of the line of vision, to a pair of glasses that cost just £3. The cameras constantly take pictures of the eye, working out where the pupil is pointing, and from this the researchers can use a set of calibrations to work out exactly where a person is looking on the screen.

Even more impressively, the researchers are also able to use more detailed calibrations to work out the 3D gaze of the subjects — in other words, how far into the distance they were looking. It is believed that this could allow people to control an electronic wheelchair simply by looking where they want to go or control a robotic prosthetic arm.

To demonstrate the effectiveness of the eye-tracker, the researchers got subjects to play the video game Pong. In this game, the subject used his or her eyes to move a bat to hit a ball that was bouncing around the screen — a feat that is difficult to accomplish with other read-out mechanisms such as brain waves (EEG).

Dr Aldo Faisal, Lecturer in Neurotechnology at Imperial’s Department of Bioengineering and the Department of Computing, is confident in the ability to utilise eye movements given that six of the subjects, who had never used their eyes as a control input before, could still register a respectable score within 20 per cent of the able bodied users after just 10 minutes of using the device for the first time.

The commercially viable device uses just one watt of power and can transmit data wirelessly over Wi-Fi or via USB into any Windows or Linux computer.

The GT3D system has also solved the ‘Midas touch problem’, allowing users to click on an item on the screen using their eyes, instead of a mouse button.

This problem has previously been resolved by staring at an icon for a prolonged period or blinking; however, the latter is part of our natural behaviour and happens unintentionally. Instead, the researchers calibrated the system so that a simple wink would represent a mouse click, which only occurs voluntarily unlike the blink.

Dr Faisal said: “Crucially, we have achieved two things: we have built a 3D eye tracking system hundreds of times cheaper than commercial systems and used it to build a real-time brain machine interface that allows patients to interact more smoothly and more quickly than existing invasive technologies that are tens of thousands of times more expensive.

"This is frugal innovation; developing smarter software and piggy-backing existing hardware to create devices that can help people worldwide independent of their healthcare circumstances."

Source: Science Daily

ScienceDaily (July 12, 2012) — Negative suggestion can induce symptoms of illness. Nocebo effects are the adverse events that occur during sham treatment and/or as a result of negative expectations. While the positive counterpart — the placebo effect — has been intensively studied in recent years, the scientific literature contains few studies on nocebo phenomena. In the latest issue of Deutsches Ärzteblatt International, Winfried Häuser of the Technical University of Munich and his co-authors present the underlying neurobiological mechanisms and highlight the relevance of the nocebo effect in everyday clinical practice.

Nocebo responses can, for instance, be brought about by unintended negative suggestion on the part of doctors or nurses, e.g., when informing the patient about the possible complications of a proposed treatment. It is also assumed that a certain proportion of the undesired effects of drugs can be attributed to nocebo effects. The mechanisms behind this phenomenon are — as with placebo effects — learning by Pavlovian conditioning and reaction to induced expectations.

What are the consequences for clinical practice? Doctors find themselves in an ethical dilemma between their obligation to tell the patient about the possible side effects of a treatment and their duty to minimize the risk of a medical intervention and thus to avoid triggering nocebo effects. As one possible strategy to solve this dilemma, Häuser et al. suggest emphasizing the tolerability of therapeutic measures. Another option, with the patient’s permission, would be to desist from discussing undesired effects during the patient briefing.

Source: Science Daily

ScienceDaily (July 12, 2012) — University of Kansas researchers have found larger resting pupil size and lower levels of a salivary enzyme associated with the neurotransmitter norepinephrine in children with autism spectrum disorder.

However, even though the levels of the enzyme, salivary alpha-amylase (sAA), were lower than those of typically-developing children in samples taken in the afternoon in the lab, samples taken at home throughout the day showed that sAA levels were higher in general across the day and much less variable for children with ASD.

"What this says is that the autonomic system of children with ASD is always on the same level," Christa Anderson, assistant research professor, said. "They are in overdrive."

The sAA levels of typically-developing children gradually rise and fall over the day, said Anderson, who co-directed the study with John Colombo, professor of psychology.

Norepinephrine (NE) has been found in the blood plasma levels of individuals with ASD but some researchers have questioned whether these levels were just related to the stress from blood draws.

The KU study addressed this by collecting salivary measures by simply placing a highly absorbent sponge swab under the child’s tongue and confirmed that this method of collection did not stress the children by assessing their stress levels through cortisol, another hormone.

Collecting sAA levels has the potential for physicians to screen children for ASD much earlier, noninvasively and relatively inexpensively, said Anderson.

But Anderson and Colombo also see pupil size and sAA levels as biomarkers that could be the physiological signatures of a possible dysfunction in the autonomic nervous system.

"Many theories of autism propose that the disorder is due to deficits in higher-order brain areas," said Colombo. "Our findings, however, suggest that the core deficits may lie in areas of the brain typically associated with more fundamental, vital functions."

The study, published online in the May 29, 2012 Developmental Psychobiology compared children between the ages of 20 and 72 months of age diagnosed with ASD to a group of typically developing children and a third group of children with Down Syndrome.

Both findings address the Centers for Disease Control’s urgent public health priority goals for ASD: to find biological indicators that can both help screen children earlier and lead to better understanding of how the nervous system develops and functions in the disorder.

Source: Science Daily

ScienceDaily (July 12, 2012) — Researchers at Emory University School of Medicine have identified five rare mutations in a single gene that appear to increase the chances that a boy will develop an autism spectrum disorder (ASD).

Mutations in the AFF2 gene, and other genes like it on the X chromosome, may explain why autism spectrum disorders affect four times as many boys as girls.

The mutations in AFF2 appeared in 2.5 percent (5 out of 202) boys with an ASD. Mutations in X chromosome genes only affect boys, who have one X chromosome. Girls have a second copy of the gene that can compensate.

The results were published July 5 in the journal Human Molecular Genetics.

"Our data suggest that AFF2 could be one of the major X-linked risk factors for ASD’s," says senior author Michael Zwick, PhD, assistant professor of human genetics at Emory University School of Medicine.

The finding bolsters a growing consensus among geneticists that rare variants in many different genes contribute significantly to risk for autism spectrum disorders.

The mutations in the AFF2 gene probably do not cause ASDs all by themselves, Zwick says.

"We do not think that the variants we have identified are monogenic causes of autism," he says. "Our data does support the idea that this is an autism susceptibility gene."

In some situations, mutations in a single gene are enough by themselves to lead to a neurodevelopmental disorder with autistic features, such as fragile X syndrome or tuberous sclerosis complex. But these types of mutations are thought to account for a small number of ASD cases.

Recent large-scale genetic studies of autism spectrum disorders have identified several “rare variants” that sharply increase ASD risk. Scientists believe rare variants could explain up to 15 or 20 percent of ASD cases. However, until now no single variant has been found in more than one percent of ASD cases.

Working with Zwick, postdoctoral fellow Kajari Mondal and her colleagues read the sequence of the AFF2 gene in DNA from 202 boys diagnosed with autism spectrum disorders. The patient samples came from the Autism Genetic Resource Exchange and the Simons Simplex Collection.

Tests showed that in four cases, the affected boys had inherited the risk-conferring mutations from their mothers. One boy had a “de novo” (not coming from the parents) mutation. Compared with X-linked genes in unaffected people, mutations in AFF2 were five times more abundant in the boys with ASDs.

The AFF2 gene had already been identified as responsible for a rare inherited form of intellectual disability with autistic features. This effect is seen when the AFF2 gene is deleted or silenced completely.

AFF2 has some similarity to FMR1, the gene responsible for fragile X syndrome. Like FMR1, it can be silenced by a triplet repeat. In these cases, the presence of the triplet repeat (three genetic bases repeated dozens of times) triggers a change in chromosomal structure that prevents the gene from being turned on.

In contrast, the mutations Zwick’s team found are more subtle, slightly changing the sequence of the protein AFF2 encodes. Little is known about the precise function of the AFF2 protein. A related gene in fruit flies called lilliputian also appears to regulate the development of neurons.

Zwick says one of his laboratory’s projects is to learn more about the function of the AFF2 gene, and to probe how the mutations identified by his team affect the function. His team is also working on gauging the extent to which other genes on the X chromosome contribute to autism risk.

Source: Science Daily

ScienceDaily (July 12, 2012) — Diagnosing multiple sclerosis (MS) is a challenge even for experienced neurologists. This autoimmune disease has many symptoms and rarely presents a uniform clinical picture. New scientific findings on the immune response involved in MS could now help improve the diagnosis of this illness. Scientists analyzing the blood of MS patients have discovered antibodies that attack a specific potassium channel in the cell membrane. Potassium channels play an important role in transmitting impulses to muscle and nerve cells and it is exactly these processes that are inhibited in MS patients.

Right: The autoantibody can be seen binding to the membrane of glial cells in the MS serum. By comparison, the image on the left shows a blood sample from a patient with another neurological disease. (Credit: KKNMS)

The results are published in the current issue of the New England Journal of Medicine.

For the first time, scientists in Germany’s multiple sclerosis competence network have been able to identify an antibody that bonds with the potassium channel KIR4.1. “We found this autoantibody in almost half of the MS patients in our study,” explains Bernhard Hemmer, Professor of Neurology at the Klinikum rechts der Isar hospital at Technische Universität München (TUM). The biomarker was not present in healthy patients. The findings could therefore indicate that KIR4.1 is one of the targets of the autoimmune response in MS. Humans and animals without the KIR4.1 channel experience neurological failure and cannot coordinate their movements properly. Furthermore, their bodies do not create sufficient amounts of myelin, a layer of insulation that protects the nerve cells.

KIR4.1 is primarily present in the membrane of glial cells, which are responsible for controlling metabolism in the brain and forming myelin. The neurologists will now be conducting follow-up studies into how KIR4.1 antibodies influence the development of MS. This autoantibody is extremely rare in people with other neurological diseases, making it an important potential diagnostic marker for MS in the future. “This autoantibody could improve diagnosis of MS and help us differentiate it more clearly from other neurological diseases,” continues Hemmer. This will also be the focus of further research.

Source: Science Daily

July 12, 2012

(HealthDay) — A supplement mixture (Souvenaid) containing dietary precursors and specific nutrients can improve memory in drug-naive patients with mild Alzheimer’s disease (AD), according to a study published in the July issue of the Journal of Alzheimer’s Disease.

Philip Scheltens, M.D., from the VU University Medical Center in Amsterdam, and colleagues conducted a 24-week, randomized, controlled trial in which drug-naive patients with mild AD were randomized in a 1:1 ratio to receive Souvenaid or an iso-caloric control product once daily. Memory function was assessed using the domain z-score of the Neuropsychological Test Battery (NTB).

The researchers found that, over the intervention period, the NTB memory domain z-score was significantly increased in patients taking Souvenaid versus the control group (P = 0.023), with a trend toward improvement in the NTB total composite z- score (P = 0.053). Functional connectivity in the delta band, as measured by an electroencephalography, was significantly different between the study groups in favor of the active group. There was very high adherence to the intervention (96.6 percent for the control and 97.1 percent for the active group). Both products were well tolerated and there was no between-group difference in the occurrence of serious adverse events.

"In conclusion, this study confirms that Souvenaid is well tolerated and improves memory performance,” the authors write. “Our results warrant further investigation of the clinical potential of Souvenaid in preclinical or clinical conditions characterized by synaptic loss, in particular AD.”

Several authors disclosed financial ties to Danone Research BV and Nutricia Advanced Medical Nutrition, which sponsored the study and manufacture Souvenaid.

Source: medicalxpress.com

ScienceDaily (July 12, 2012) — Obesity is not to blame for poor educational performance, according to early findings from research funded by the Economic and Social Research Council (ESRC). In a study that combines statistical methods with genetic information, researchers dispel the false idea that being overweight has damaging educational consequences.

Previous studies have shown that children who are heavier are less likely to do well at school. However, Dr Stephanie von Hinke Kessler Scholder from University of York argues it’s vital to understand what drives this association. “We sought to test whether obesity ‘directly’ hinders performance due to bullying or health problems, or whether kids who are obese do less well because of other factors that are associated with both obesity and lower exam results, such as coming from a disadvantaged family,” Dr Scholder explains.

Researchers examined data on almost 4,000 members of the Children of the 90s Birth Cohort Study. These data include the children’s DNA. It is well known that genes are randomly allocated within a population, irrespective of factors such as socio-economic position. The researchers combined the latest developments from genetic epidemiology with statistical methodologies in economic and econometric research. Using two carefully chosen ‘genetic markers’, the research team was able to identify children with a slightly higher genetic pre-disposition to obesity.

“Based on a simple correlation between children’s obesity as measured by their fat mass and their exam results, we found that heavier children did do slightly worse in school,” Dr Scholder points out. “But, when we used children’s genetic markers to account for potentially other factors, we found no evidence that obesity causally affects exam results. So, we conclude that obesity is not a major factor affecting children’s educational outcomes.”

These findings suggest that the previously found negative relationship between weight and educational performance is driven by factors that affect both weight and educational attainment. Future research should focus on other determinants of poor educational outcomes, such as social class or a family’s socio-economic circumstances, Dr Scholder points out.

The finding that obesity is not a cause of poorer educational performance is, the researchers suggest, a positive thing. “Clearly there are reasons why there are differences in educational outcomes, but our research shows that obesity is not one of them,” Dr Scholder argues.

Source: Science Daily

July 12, 2012

Biologists at UC San Diego have discovered a chemical that offers a completely new and promising direction for the development of drugs to treat metabolic disorders such as type 2 diabetes—a major public health concern in the United States due to the current obesity epidemic.

Their discovery, detailed in a paper published July 13 in an advance online issue of the journal Science, initially came as a surprise because the chemical they isolated does not directly control glucose production in the liver, but instead affects the activity of a key protein that regulates the internal mechanisms of our daily night and day activities, which scientists call our circadian rhythm or biological clock.

Scientists had long suspected that diabetes and obesity could be linked to problems in the biological clock. Laboratory mice with altered biological clocks, for example, often become obese and develop diabetes. Two years ago, a team headed by Steve Kay, dean of the Division of Biological Sciences at UC San Diego, discovered the first biochemical link between the biological clock and diabetes. It found that a key protein, cryptochrome, that regulates the biological clocks of plants, insects and mammals also regulates glucose production in the liver and that altering the levels of this protein could improve the health of diabetic mice.

Now Kay and his team have discovered a small molecule—one that can be easily developed into a drug—that controls the intricate molecular cogs or timekeeping mechanisms of cryptochrome in such a manner that it can repress the production of glucose by the liver. Like mice and other animals, humans have evolved biochemical mechanisms to keep a steady supply of glucose flowing to the brain at night, when we’re not eating or otherwise active.

"At the end of the night, our hormones signal that we’re in a fasting state," said Kay. "And during the day, when we’re active, our biological clock shuts down those fasting signals that tell our liver to make more glucose because that’s when we’re eating."

Read More →

ScienceDaily (July 11, 2012) — Widely held beliefs about Neuro-Linguistic Programming and lying are unfounded.

Twenty portrait of a woman with different expressions. (Credit: © gemenacom / Fotolia)

Proponents of Neuro-Linguistic Programming (NLP) have long claimed that it is possible to tell whether a person is lying from their eye movements.  Research published July 11 in the journal PLoS ONE reveals that this claim is unfounded, with the authors calling on the public and organisations to abandon this approach to lie detection.

For decades many NLP practitioners have claimed that when a person looks up to their right they are likely to be lying, whilst a glance up to their left is indicative of telling the truth.

Professor Richard Wiseman (University of Hertfordshire, UK) and Dr Caroline Watt (University of Edinburgh, UK) tested this idea by filming volunteers as they either lied or told the truth, and then carefully coded their eye movements.  In a second study another group of participants was asked to watch the films and attempt to detect the lies on the basis of the volunteers’ eye movements.

"The results of the first study revealed no relationship between lying and eye movements, and the second showed that telling people about the claims made by NLP practitioners did not improve their lie detection skills,” noted Wiseman. 

A final study involved moving out of the laboratory and was conducted in collaboration with Dr Leanne ten Brinke and Professor Stephen Porter from the University of British Columbia, Canada.  The team analysed films of liars and truth tellers from high profile press conferences in which people were appealing for missing relatives or claimed to have been the victim of a crime. 

"Our previous research with these films suggests that there are significant differences in the behaviour of liars and truth tellers," noted Dr Leanne ten Brinke. "However, the alleged tell-tale pattern of eye movements failed to emerge."

"A large percentage of the public believes that certain eye movements are a sign of lying, and this idea is even taught in organisational training courses.  Our research provides no support for the idea and so suggests that it is time to abandon this approach to detecting deceit" remarked Watt.

Source: Science Daily

ScienceDaily (July 11, 2012) — When humans learn, their brains relate new information with past experiences to derive new knowledge, according to psychology research from The University of Texas at Austin.

The study, led by Alison Preston, assistant professor of psychology and neurobiology, shows this memory-binding process allows people to better understand new concepts and make future decisions. The findings could lead to better teaching methods, as well as treatment of degenerative neurological disorders, such as dementia, Preston says.

"Memories are not just for reflecting on the past; they help us make the best decisions for the future," says Preston, a research affiliate in the Center for Learning and Memory, which is part of the university’s College of Natural Sciences. "Here, we provide a direct link between these derived memories and the ability to make novel inferences."

The paper was published online in July in the journal Neuron. The authors include University of Texas at Austin researchers Dagmar Zeithamova and April Dominick.

In the study, 34 subjects were shown a series of paired images composed of different elements (for example, an object and an outdoor scene). Each of the paired images would then reappear in more presentations. A backpack, paired with a horse in the first presentation, would appear alongside a field in a later presentation. The overlap between the backpack and outdoor scenery (horse and field) would cause the viewer to associate the backpack with the horse and field. The researchers used this strategy to see how respondents would delve back to a recent memory while processing new information.

Using functional Magnetic Resonance Imaging (fMRI) equipment, the researchers were able to look at the subjects’ brain activity as they looked at image presentations. Using this technique, Preston and her team were able to see how the respondents thought about past images while looking at overlapping images. For example, they studied how the respondents thought about a past image (a horse) when looking at the backpack and the field. The researchers found the subjects who reactivated related memories while looking at overlapping image pairs were able to make associations between individual items (i.e. the horse and the field) despite the fact that they had never studied those images together.

To illustrate the ways in which this cognitive process works, Preston describes an everyday scenario.

Imagine you see a new neighbor walking a Great Dane down the street. At a different time and place, you may see a woman walking the same dog in the park. When experiencing the woman walking her dog, the brain conjures images of the recent memory of the neighbor and his Great Dane, causing an association between the dog walkers to be formed in memory. The derived relationship between the dog walkers would then allow you to infer the woman is also a new neighbor even though you have never seen her in your neighborhood.

"This is just a simple example of how our brains store information that goes beyond the exact events we experience," Preston says. "By combining past events with new information, we’re able to derive new knowledge and better anticipate what to expect in the future."

During the learning tasks, the researchers were able to pinpoint the brain regions that work in concert during the memory-binding process. They found the hippocampal-ventromedial prefrontal cortex (VMPFC) circuit is essential for binding reactivated memories with current experience.

Source: Science Daily

July 11, 2012

Two powerful brain chemical systems work together to paralyze skeletal muscles during rapid eye movement (REM) sleep, according to new research in the July 11 issue of The Journal of Neuroscience. The finding may help scientists better understand and treat sleep disorders, including narcolepsy, tooth grinding, and REM sleep behavior disorder.

During REM sleep — the deep sleep where most recalled dreams occur — your eyes continue to move but the rest of the body’s muscles are stopped, potentially to prevent injury. In a series of experiments, University of Toronto neuroscientists Patricia L. Brooks and John H. Peever, PhD, found that the neurotransmitters gamma-aminobutyric acid (GABA) and glycine caused REM sleep paralysis in rats by “switching off” the specialized cells in the brain that allow muscles to be active. This finding reversed earlier beliefs that glycine was a lone inhibitor of these motor neurons.

"The study’s findings are relevant to anyone who has ever watched a sleeping pet twitch, gotten kicked by a bed partner, or has known someone with the sleep disorder narcolepsy," said Dennis J. McGinty, PhD, a behavioral neuroscientist and sleep researcher at the University of California, Los Angeles, who was not involved in the study. "By identifying the neurotransmitters and receptors involved in sleep-related paralysis, this study points us to possible molecular targets for developing treatments for sleep-related motor disorders, which can often be debilitating," he said

The researchers measured electrical activity in the facial muscles responsible for chewing of sleeping rats. Brain cells called trigeminal motor neurons communicate the brain’s message to move to these muscles. Previous research suggested neurotransmitter receptors called ionotropic GABAA/glycine receptors in the motor neurons caused REM sleep paralysis. However, when the researchers blocked these receptors, REM sleep paralysis still occurred.

The researchers found that to prevent REM sleep paralysis, they had to block both the ionotropic receptors and metabotropic GABAB receptors, a different receptor system. In other words, when the motor cells were cut off from all sources of GABA and glycine, the paralysis did not occur, allowing the rats to exhibit high levels of muscle activity when their muscles should have been inactive. The data suggest the two neurotransmitters must both be present together to maintain motor control during sleep, rather than working separately.

The finding could be especially helpful for those with REM sleep disorder, a disease that causes people to act out their dreams. This can cause serious injuries to patients and others around them. It is also often an early indicator of neurodegenerative diseases, such as Parkinson’s.

"Understanding the precise mechanism behind these chemicals’ role in REM sleep disorder is particularly important because about 80 percent of people who have it eventually develop a neurodegenerative disease, such as Parkinson’s disease," study author Peever added. "REM sleep behavior disorder could be an early marker of these diseases, and curing it may help prevent or even stop their development,” he said.

Provided by University of Toronto

Source: medicalxpress.com

July 11, 2012

A new study shows that taking part in a stress management program may help people with multiple sclerosis (MS) prevent new disease activity. The study is published in the July 11, 2012, online issue of Neurology, the medical journal of the American Academy of Neurology.

A weekly stress management program for patients with multiple sclerosis (M.S.) prevented the development of new brain lesions, a marker of the disease’s activity in the brain, according to new Northwestern Medicine research. Brain lesions in M.S. often precede flare-ups of symptoms such as loss of vision or use of limbs or pain.

"This is the first time counseling or psychotherapy has been shown to affect the development of new brain lesions," said David Mohr, principal investigator of the study and professor of preventive medicine at Northwestern University Feinberg School of Medicine. "In M.S., the prevention of new brain lesions is an important marker used to judge how effective medications are."

"The new finding is an important step and the strongest evidence we have to date that stress is involved in M.S.," Mohr added.

The results indicate that stress management therapy may be a useful adjunct treatment with drug therapy for M.S., but a larger clinical trial is needed to confirm this, Mohr said.

The study is published in the July 11, 2012 issue of Neurology, the medical journal of the American Academy of Neurology.

Mohr’s previous research showed a connection between psychological distress and the development of new brain lesions. Stress is one of many factors, he said, that influence whether the underlying M.S. disease processes escalate to the point of a new lesion or a relapse. Mohr has spent more than a decade studying the link between emotional distress, including a study on depression, and M.S.

For an event to be stressful, a person has to feel it is a threat to something important, and that he or she doesn’t have any control over it.

"We taught patients strategies to evaluate how much of a threat something truly is," Mohr said. "When people overestimate the threat of an event or underestimate their ability to manage it, we teach them how to evaluate their own thinking about the stress and how to challenge and change that thinking to a more realistic and helpful appraisal of the actual threat. That often leads to improved ability to manage stressful events."

Patients also were taught how to calm their physical reactions to stress through relaxation and meditation to cope with stressful events that couldn’t be avoided.

In the national clinical trial, 121 patients were randomized to receive stress management therapy for M.S. or be in a control group. Those in the therapy group received 16 sessions over a 24-week period during which they were taught coping skills to enhance their ability to prevent stressful events from occurring and to improve their capacity to manage their responses to stressful events that did arise. They also received a 24-week post-treatment follow-up. Two-thirds of the patients were women, who have a higher incidence of M.S.

MRI neuroimaging showed the stress management therapy reduced two types of new brain lesions common in multiple sclerosis.

The first type, gadolinium-enhancing brain lesions, indicates a breakdown of the blood-brain barrier, allowing the immune system access to attack and damage brain cells. Gadolinium is injected into an M.S. patient during the MRI and can be observed passing through the blood-brain barrier, if these types of lesions are present. These lesions may disappear over time or may leave more permanent damage in the brain.

The second type, a T2 brain lesion, is a more global marker of the effect of M.S. on the brain and is a more permanent lesion. These markers are commonly used in evaluating M.S. medications in Phase II trials. If the lesions are decreased, the implication is the drug is working.

Among patients who received stress management therapy, 55 percent had a new gadolinium-enhancing brain lesion during the treatment period, compared to 77 percent of those in the control group. Similarly, 43 percent receiving stress management therapy had a new T2 brain lesion during the treatment period, compared to 70 percent in the control group. The stress reduction prevented new lesions whether or not the patients were taking M.S. disease-modifying medications (e.g., beta-interferons or glatiramer acetate).

But the improvement in brain lesions didn’t last after the stress management program ended.

"This suggests that we will need to develop treatments that are more sustainable over longer periods of time," Mohr said. "It’s difficult for people to come in for treatment once a week over long periods of time, due both to cost and time constraints. We are looking at telemedicine programs that can be delivered via a computer or a smartphone to people in their environment at much lower costs than traditional therapy."

The study did not show a statistical difference in the rate of clinical M.S. symptoms, but Mohr said he didn’t expect one in such a small number of participants. The outcome goal of this trial was only to see if the stress reduction affected the brain lesions.

While the results are positive, Mohr said, it’s premature to make recommendations for patients regarding use of stress management therapy. “I don’t want to see patients decide not to take their medication and use this instead,” he emphasized.

Provided by American Academy of Neurology

Source: medicalxpress.com

July 11, 2012

Communication between the brain and muscle must be strong for us to eat, breathe or walk. Now scientists have found that a protein known to be on the surface of muscle cells must be present in both tissues to ensure the conversation is robust.

Communication between the brain and muscle must be strong for us to eat, breathe or walk. Now scientists have found that a protein known to be on the surface of muscle cells must be present in both tissues to ensure the conversation is robust. Credit: Phil Jones

Scientists at the Medical College of Georgia at Georgia Health Sciences University have shown that without LRP4 in muscle cells and neurons, communication between the two cells types is inefficient and short-lived.

Problems with the protein appear to contribute to disabling disorders such as myasthenia gravis and other forms of muscular dystrophy. The MCG scientists reported finding antibodies to LRP4 in the blood of about 2 percent of patients with muscle-degenerating myasthenia gravis in Archives of Neurology earlier this year.

Scientists know that LRP4 plays an important role in the muscle cell, where it receives cues from the brain cell that it’s time to form the receptors that will be enable ongoing communication between the two, said Dr. Lin Mei, Director of the GHSU Institute of Molecular Medicine and Genetics and corresponding author of the study in the journal Neuron.

However when Dr. Haitao Wu deleted LRP4 just from muscle cells, a connection – albeit a weak one – still formed between muscle and brain cells. The mice survived several days during which they experienced some of the same muscle weakness as patients with myasthenia gravis. “That’s against the dogma,” Mei said. “If LRP4 is essential only in the muscle cells, how could the mice survive?” When they totally eliminated LRP4, neuromuscular junctions never formed and the mice didn’t survive.

Additional evidence suggests that LRP4 in the neurons is vital, said Wu, postdoctoral fellow and the study’s first author. “When we knocked out the LRP4 gene in the muscles, there was some redundant function coming from the motor neuron, like a rescue attempt,” he said. They documented the neuron reaching out to share LRP4 with the muscle cell. Unfortunately, the gesture was not sufficient.

"The nerve does not get the stop signal," Mei said, referencing images of too-long neurons that never got the message from the muscle that they have gone far enough. When they cut the elongated nerves, they found they didn’t contain enough vesicles, little packages of chemical messengers that are the hallmark of brain cell communication. On the receiving end, muscle cells developed receptors that were too small and too few – hence, the tenuous communication network. "When LRP4 in the muscle is taken out, not surprisingly, the muscle has some kind of a problem," Mei said. "What was very surprising was that the motor neurons also have problems.”

"The talk between motor neurons and muscle cells is very critical to the synapse formation and the very precise action between the two," Wu said. Mei’s lab earlier established that the conversation goes both ways.

The scientists believe about 60 percent of the LRP4 comes from muscle cells, about 20 percent from brain cells – which helps explain why the brain’s effort to share is insufficient – and the remainder from cells in spaces between the two. In addition to better explaining nerve-muscle communication, the scientists hope their findings will eventually enable gene therapy that delivers LRP4 to bolster insufficient levels in patients.

Other early and key players in establishing nerve-muscle conversation include agrin, a protein that motor neurons release to direct construction of the synapse, a sort of telephone line between the nerve and muscle. MuSK on the muscle cell surface initiates critical internal cell talk so synapses can form and receptors that enable specific commands will cluster at just the right spot.

Mei’s lab reported in Neuron in 2008 that agrin starts talking with LRP4 on the muscle cell surface, then recruits the enzyme MuSK to join the conversation. LRP4 and MuSK become major components of the receptor needed for the muscle cell to receive the message agrin is sending.

The agrin-MuSK signaling pathway has been implicated in muscular dystrophy, a group of genetic diseases that lead to loss of muscle control because of problems with neurons, muscle cells and/or their communication. Some reports have implicated a mutant MuSK as a cause of muscular dystrophy and autoantibodies (antibodies the body makes against itself) to MuSK have been found in the blood of some patients.

Provided by Georgia Health Sciences University

Source: medicalxpress.com

July 11, 2012

An inflated sense of memory function in people with dementia may influence their likelihood of seeking help, new Flinders University research shows.

As part of her PhD, Flinders research associate Dr. Chris Materne studied the disparity between memory perception and performance in people with dementia.

In the first stage of the project, Dr. Materne analysed data from the Australian Longitudinal Study of Aging which showed that most survey participants believed their memory had remained stable over the 11-year assessment, despite tests showing a decline in memory performance.

She then conducted an intervention with 13 individuals, from a larger group of 23 people with dementia, using spaced retrieval memory training to help them achieve a specific task or activity, such as remembering to lock the front door or keep their glasses in the same spot.

“Spaced retrieval works by helping people remember specific information or tasks by getting them to respond to a prompt question over progressively increasing intervals of time,” Dr. Materne said.

“In one case we helped a man remember to put his glasses in the same place because he was always losing them which made both him and his wife quite distressed,” she said.

“We think the training taps into procedural memory so it becomes habitual rather than explicit memory, such as memory for facts, which tends to decline before procedural memory when you have dementia.”

The technique was conducted once a week for six weeks, with seven out of the 13 participants still able to perform their nominated activity or task after six months.

The 23 participants were also asked to rate their performance based on a specific question, such as how many people they could name in a photo with 10 faces.

While most respondents were initially over-confident in their abilities, with some claiming to be able to name all 10 faces, their perceptions did change over time to more accurately reflect their cognitive function.

About one third of family carers, however, initially considered their loved ones memory to be better than what the person with dementia actually reported.

“In the longitudinal sample people didn’t feel their memory had changed over time because the questions were more general but when we asked specific, detailed questions about memory in the smaller study, the respondents came to recognise their declining performance.”

Dr. Materne said the research highlighted the need for more comprehensive assessments when diagnosing dementia to increase the accuracy of peoples’ perceptions, and therefore their likelihood of seeking help.

Provided by Flinders University

Source: medicalxpress.com

ScienceDaily (July 11, 2012) — Stanford University School of Medicine scientists have laid bare a novel molecular mechanism responsible for the most important symptom of major depression: anhedonia, the loss of the ability to experience pleasure. While their study was conducted in mice, the brain circuit involved in this newly elucidated pathway is largely identical between rodents and humans, upping the odds that the findings point toward new therapies for depression and other disorders.

Additionally, opinion leaders hailed the study’s inventive methodology, saying it may offer a much sounder approach to testing new antidepressants than the methods now routinely used by drug developers.

While as many as one in six Americans is likely to suffer a major depression in their lifetimes, current medications either are inadequate or eventually stop working in as many as 50 percent of those for whom they’re prescribed.

"This may be because all current medications for depression work via the same mechanisms," said Robert Malenka, MD, PhD, the Nancy Friend Pritzker Professor in Psychiatry and Behavioral Sciences. "They increase levels of one or another of two small molecules that some nerve cells in the brain use to signal one another. To get better treatments, there’s a great need to understand in greater detail the brain biology that underlies depression’s symptoms." The study’s first author is Byung Kook Lim, PhD, a postdoctoral scholar in Malenka’s laboratory.

Malenka is senior author of the new study, published July 12 in Nature, which reveals a novel drug target by showing how a hormone known to affect appetite turns off the brain’s ability to experience pleasure when an animal is stressed. This hormone, melanocortin, signals to an ancient and almost universal apparatus deep in the brain called the reward circuit, which has evolved to guide animals toward resources, behaviors and environments — such as food, sex and warmth — that enhance their prospects for survival.

"This is the first study to suggest that we should look at the role of melanocortin in depression-related syndromes," said Eric Nestler, MD, PhD, professor and chair of neuroscience and director of the Friedman Brain Institute at Mount Sinai School of Medicine in New York. Nestler was not involved in the study but is familiar with its contents.

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ScienceDaily (July 11, 2012) — In the current online issue of PLoS ONE, researchers at the University of California, San Diego School of Medicine say they have identified a set of laboratory-based biomarkers that can be useful for understanding brain-based abnormalities in schizophrenia. The measurements, known as endophenotypes, could ultimately be a boon to clinicians who sometimes struggle to recognize and treat the complex and confounding mental disorder.

"A major problem in psychiatry is that there are currently no laboratory tests that aid in diagnosis, guide treatment decisions or help predict treatment response or outcomes," said Gregory A. Light, PhD, associate professor of psychiatry and the study’s first author. "Diagnoses are currently based on a clinician’s ability to make inferences about patients’ inner experiences."

Diagnosing and treating schizophrenia is a particularly troubling challenge. The disorder, which affects about 1 percent of the U.S. population or roughly 3 million people, is characterized by a breakdown of normal thought processes and erratic, sometimes dangerous or harmful, behaviors.

"Schizophrenia is among the most severe and disabling conditions across all categories of medicine," said Light, who also directs the Mental Illness, Research, Education and Clinical Center at the San Diego VA Healthcare System.

The precise cause or causes of schizophrenia are not known, though there is a clear genetic component, with the disorder more common in some families.

Clinicians typically diagnose schizophrenia based upon inferences drawn from the patient’s inner experiences. That is, their ability to describe what’s happening inside their minds.

"But even the best clinicians struggle with diagnostic complexities based on sometimes fuzzy clinical phenomenology," said Light. The clinical challenge is compounded by the fact that "many schizophrenia patients have cognitive and functional impairments," said Light. They may not be able to reasonably explain how or what they think.

Light and colleagues investigated whether a select battery of neurophysiological and neurocognitive biomarkers could provide clinicians with reliable, accurate, long-term indicators of brain dysfunction, even when overt symptoms of the disorder were not apparent. These markers ranged from tests of attention and memory to physiological assessments of basic perceptual processes using scalp sensors to measure brain responses to simple sounds.

The researchers measured the biomarkers in 550 schizophrenia patients, and then re-tested 200 of the patients one year later. They found that most of the markers were significantly abnormal in schizophrenia patients, were relatively stable between the assessments and were not affected by modest fluctuations in clinical status of the patient.

Light said further research is required, including whether the endophenotypes can differentiate other psychiatric disorders, be used to anticipate patient response to different kinds of drugs or non-pharmacological interventions or even be used to predict which subjects are at high risk of developing a psychotic illness.

"We believe this paper is an important step towards validating laboratory-based biomarkers for use in future genomic and clinical treatment studies of schizophrenia," Light said.

Source: Science Daily

July 11, 2012

(Medical Xpress) — Johns Hopkins researchers say they have discovered that the central nervous system’s oligodendroglia cells, long believed to simply insulate nerves as they “fire” signals, are unexpectedly also vital to the survival of neurons. Damage to these insulators appears to contribute to brain injury in neurodegenerative diseases such as amyotrophic lateral sclerosis (ALS), also known as Lou Gehrig’s disease for the Yankee baseball great who died from the disease.

The discovery, described online in the journal Nature, suggests that a previously unknown — and unexpected — function of these cells is to supply nutrition to the principal brain cells, neurons. This new pathway may prove to be an important and novel therapeutic target for ALS, the researchers say, and potentially other diseases that attack the body’s nerve fibers, such as multiple sclerosis.

"More than 100 years after their discovery, we have now found a fundamentally new property in the way oligodendroglia work in the brain, laying the foundation for a new approach to try to treat debilitating neurodegenerative diseases,” says Jeffrey D. Rothstein, M.D., Ph.D., a professor of neurology and neuroscience at the Johns Hopkins University School of Medicine, and the study’s leader. “We’ve added a whole new category to what they do in the brain.”

The cells responsible for the transfer of information and electrical impulses around the body, neurons work by transferring electrical charges from neuron to neuron. Axons, the wire-like extensions of the neurons, help move the messages, in some cases over many feet, from cell to cell. Oligodendroglia insulate axons, like rubber coating around an electrical wire, to speed up the conduction of information. Axonal death is a hallmark of ALS and most other neurodegenerative disorders, Rothstein says.

Rothstein and his colleagues say the other principal brain cells, the astroglia, were believed to be primarily responsible for providing energy to neurons in the form of glucose, but their experiments show that oligodendroglia are surprisingly crucial in feeding neurons — in the form of less energy-rich lactate, without which neurons and their axons die. Lactate has long been seen as a minor player in this process, but the Johns Hopkins team says it appears to be far more important to nerve cell survival. Moreover, they found that the protein MCT1, the dominant transporter of lactate in the brain, is only found in oligodendroglia.

Rothstein says their discovery was rooted in experiments during which scientists, using mice, knocked out the gene that makes the MCT1 protein and saw axons begin to die, even though they were still getting plenty of glucose.

As part of these experiments, the researchers engineered mice whose cells would light up if they were expressing MCT1. The scientists then determined that only oligodendroglia cells lit up, showing that MCTI is located on this type of cell alone. They also knocked out the MCT1 in cell cultures and found that neurons would begin to die, but would recover when fed lactate, proving the importance of MCT1 in providing this nutritional compound. They conducted the same experiments in mice and got similar results.

Finally, the researchers turned their attention to ALS, a disease where they had recently uncovered abnormalities related to oligodendroglia. In ALS mice, they found that MCT1 was missing in brain cells well before the disease developed, and they found similar results in ALS patients. Rothstein says the findings suggest that oligodendroglia injury — specifically injury to the mechanism that produces MCT1 — may be an important event in the onset and progression of ALS.

Rothstein, who is director of the Johns Hopkins University School of Medicine’s Brain Science Institute, says he hopes further research can establish that the activation of MCT1 in people will protect axons in those with ALS and other degenerative diseases.

Provided by Johns Hopkins University School of Medicine

Source: medicalxpress.com

July 11, 2012

In a paper published in the July 11 online issue of Science Translational Medicine, researchers at the University of California, San Diego School of Medicine have identified two key regulatory proteins critical to clearing away misfolded proteins that accumulate and cause the progressive, deadly neurodegeneration of Huntington’s disease (HD).

This is a human neuron. UC San Diego scientists have identified a pair of proteins that help clear away other misfolded proteins responsible for the progressive degeneration of brain cells in Huntington’s disease. Credit: UC San Diego School of Medicine

The findings explain a fundamental aspect of how HD wreaks havoc within cells and provides “clear, therapeutic opportunities,” said principal investigator Albert R. La Spada, MD, PhD, professor of cellular and molecular medicine, chief of the Division of Genetics in the Department of Pediatrics and associate director of the Institute for Genomic Medicine at UC San Diego.

"We think the implications are significant," said La Spada. "It’s a lead we can vigorously pursue, not just for Huntington’s disease, but also for similar neurodegenerative conditions like Parkinson’s disease and maybe even Alzheimer’s disease.”

In HD, an inherited mutation in the huntingtin (htt) gene results in misfolded htt proteins accumulating in certain central nervous system cells, leading to progressive deterioration of involuntary movement control, cognitive decline and psychological problems. More than 30,000 Americans have HD. There are no effective treatments currently to either cure the disease or slow its progression.

La Spada and colleagues focused on a protein called PGC-1alpha, which helps regulate the creation and operation of mitochondria, the tiny organelles that generate the fuel required for every cell to function.

"It’s all about energy," La Spada said. "Neurons have a constant, high demand for it. They’re always on the edge for maintaining adequate levels of energy production. PGC-1alpha regulates the function of transcription factors that promote the creation of mitochondria and allow them to run at full capacity.”

Previous studies by La Spada and others discovered that the mutant form of the htt gene interfered with normal levels and functioning of PGC-1alpha. “This study confirms that,” La Spada said. More surprising was the discovery that elevated levels of PGC-1alpha in a mouse model of HD virtually eliminated the problematic misfolded proteins.

Specifically, PGC-1alpha influenced expression of another protein vital to autophagy – the process in which healthy cells degrade and recycle old, unneeded or dangerous parts and products, including oxidative, damaging molecules generated by metabolism. For neurons, which must last a lifetime, the self-renewal is essential to survival.

"Mitochondria get beat up and need to be recycled," La Spada said. "PGC-1alpha drives this pathway through another protein called transcription factor EB or TFEB. We were unaware of this connection before, because TFEB is a relatively new player, though clearly emerging as a leading actor. We discovered that even without PGC-1alpha induction, TFEB can prevent htt aggregation and neurotoxicity."

In their experiments, HD mice crossbred with mice that produced greater levels of PGC-1alpha showed dramatic improvement. Production of misfolded proteins was essentially eliminated and the mice behaved normally. “Degeneration of brain cells is prevented. Neurons don’t die,” said La Spada.

PGC-1alpha and TFEB provide two new therapeutic targets for Huntington’s disease, according to La Spada. “If you can induce the bioenergetics and protein quality control pathways of nervous system cells to function properly, by activating the PGC-1alpha pathway and promoting greater TFEB function, you stand a good chance of maintaining neural function for an extended period of time. If we could achieve the level of increased function necessary to eliminate misfolded proteins, we might nip the disease process in the bud. That would go a long way toward treating this devastating condition.”

Provided by University of California - San Diego

Source: medicalxpress.com

July 11, 2012

Among patients with mild or no cognitive impairment, brain scans using a new radioactive dye can detect early evidence of Alzheimer’s disease that may predict future decline, according to a multi-center study led by researchers at Duke University Medical Center.

PET images using florbetapir dye to highlight beta-amyloid plaques show (A), a cognitively normal subject; (B) an amyloid-positive patient with Alzheimer’s disease; (C) a patient with mild cognitive impairment; and (D) a patient with mild cognitive impairment who progressed to dementia during the study. Credit: Slide courtesy of the journal Neurology.

The finding is published online July 11, 2012, in the journal Neurology, the medical journal of the American Academy of Neurology. It expands on smaller studies demonstrating that early detection of tell-tale plaques could be a predictive tool to help guide care and treatment decisions for patients with Alzheimer’s disease.

"Even at a short follow-up of 18 months we can see how the presence of amyloid plaques affects cognitive function," said P. Murali Doraiswamy, M.D., professor of psychiatry at Duke who co-led the study with R. Edward Coleman, M.D., professor of radiology at Duke . "Most people who come to the doctor with mild impairment really want to know the short-term prognosis and potential long-term effect."

Doraiswamy said such knowledge also has some pitfalls. There is no cure for Alzheimer’s disease, which afflicts 5.4 million people in the United States and is the sixth-leading cause of death among U.S. adults. But he said numerous drugs are being investigated, and identifying earlier disease would improve research into their potential benefits and speed new discoveries, while also enhancing care and treatment of current patients.

In the Neurology study, 151 people who had enrolled in a multi-center test of a new radioactive dye called florbetapir (Amyvid) were recruited to participate in a 36-month analysis. Of those participants, 69 had normal cognitive function at the start of the study, 51 had been diagnosed with mild impairment, and 31 had Alzheimer’s dementia.

All completed cognitive tests and underwent a brain scan using Positron Emission Tomography, or PET imaging. The technology uses radioactive tracers designed to highlight specific tissue to create a three-dimensional picture of an organ or a biological function.

The dye used in the study, florbetapir, was recently approved by the U.S. Food and Drug Administration for PET imaging of the brain to estimate beta-amyloid plaque density in patients who are being evaluated for cognitive impairment. It binds to the amyloid plaques that characterize Alzheimer’s disease, providing a window into the brain to see if the plaques have formed, and how extensively.

Patients in the study were reassessed with additional cognitive exams at 18 months and 36 months. At the 18-month point, patients with mild cognitive impairment who had PET evidence of plaque at the trial’s start worsened to a great degree on cognitive tests than patients who had no evidence of plaque at the trial’s start. Twenty-nine percent of the plaque-positive patients in this group developed Alzheimer’s dementia, compared to 10 percent who started with no plaque.

Cognitively normal patients with a plaque-positive PET scan at the start of the study also showed more mental decline at 18 months compared to those who were negative for plaque.

The study additionally found that people with negative scans reversed from minimally impaired to normal more often than people with positive PET scan, suggesting test anxiety or concentration problems could have affected their initial performance.

"For the most part we have been blind about who would progress and who wouldn’t, so this approach is a step toward having a biomarker that predicts risk of decline in people who are experiencing cognitive impairment," Doraiswamy said.

He said the study’s results provide initial data that needs to be verified by additional research. Final, 36-month data from the study has been completed and will be presented at the Alzheimer’s Association International Conference this week in Vancouver, Canada. Doraiswamy also cautioned that florbetapir is currently not approved to predict the development of dementia or other neurologic conditions and stressed that it should not be used as a screening tool in otherwise normal or minimally impaired people. Likewise, a positive scan is not necessarily diagnostic for Alzheimer’s by itself.

Provided by Duke University Medical Center

Source: medicalxpress.com

July 11, 2012

What can explain extreme differences in altruism among individuals, from Ebenezer Scrooge to Mother Teresa? It may all come down to variation in the size and activity of a brain region involved in appreciating others’ perspectives, according to a study published in the July 12th issue of the journal Neuron. The findings also provide a neural explanation for why altruistic tendencies remain stable over time.

The junction (yellow) between the parietal and the temporal lobes, in which the relative proportion of gray matter is significantly positively correlated with the propensity for altruistic behavior. Credit: University of Zurich

"This is the first study to link both brain anatomy and brain activation to human altruism,” says senior study author Ernst Fehr of the University of Zurich. “The findings suggest that the development of altruism through appropriate training or social practices might occur through changes in the brain structure and the neural activations that we identified in our study.”

Individuals who excel at understanding others’ intents and beliefs are more altruistic than those who struggle at this task. The ability to understand others’ perspectives has previously been associated with activity in a brain region known as the temporoparietal junction (TPJ). Based on these past findings, Fehr and his team reasoned that the size and activation of the TPJ would relate to individual differences in altruism.

In the new study, subjects underwent a brain imaging scan and played a game in which they had to decide how to split money between themselves and anonymous partners. Subjects who made more generous decisions had a larger TPJ in the right hemisphere of the brain compared with subjects who made stingy decisions.

Moreover, activity in the TPJ reflected each subject’s specific cutoff value for the maximal cost the subject was willing to endure to increase the partner’s payoff. Activity in the TPJ was higher during hard decisions—when the personal cost of an altruistic act was just below the cutoff value—than during easy decisions associated with a very low or very high cost.

"The structure of the TPJ strongly predicts an individual’s setpoint for altruistic behavior, while activity in this brain region predicts an individual’s acceptable cost for altruistic actions," says study author Yosuke Morishima of the University of Zurich. "We have elucidated the relationship between the hardware and software of human altruistic behavior."

Provided by Cell Press

Source: medicalxpress.com

July 10th, 2012

Guillain-Barre syndrome (GBS) is usually characterized by rapidly developing motor weakness and areflexia (the absence of reflexes). “The disease is thought to be autoimmune and triggered by a stimulus of external origin.

In 1976-1977, an unusually high rate of GBS was identified in the United States following the administration of inactivated ‘swine’ influenza A(H1N1) vaccines. In 2003, the Institute of Medicine (IOM) concluded that the evidence favored acceptance of a causal relationship between the 1976 swine influenza vaccines and GBS in adults.

Studies of seasonal influenza vaccines administered in subsequent years have found small or no increased risk,” according to background information in the article. “In a more recent assessment of epidemiologic studies on seasonal influenza vaccines, experimental studies in animals, and case reports in humans, the IOM Committee to Review Adverse Effects of Vaccines concluded that the evidence was inadequate to accept or reject a causal relationship.”

Analysis of recent H1N1 vaccination data indicated a small but significant risk of GBS following influenza A(H1N1) vaccinations.

Philippe De Wals, M.D., Ph.D., of Laval University, Quebec City, Canada and colleagues conducted a study to assess the risk of GBS following pandemic influenza vaccine administration. In fall 2009 in Quebec an immunization campaign was launched against the 2009 influenza A(H1N1) pandemic strain. By the end of the year, 4.4 million residents had been vaccinated. The study included follow-up over the 6-month period of October 2009 through March 2010 for suspected and confirmed GBS cases reported by physicians, mostly neurologists, during active surveillance or identified in the provincial hospital summary discharge database. Immunization status was verified.

Over the 6-month period, 83 confirmed GBS cases were identified. Twenty-five confirmed cases had been vaccinated against 2009 influenza A(H1N1) 8 or fewer weeks before disease onset, with most (19/25) vaccinated 4 or fewer weeks before onset. Analysis of data indicated a small but significant risk of GBS following influenza A(H1N1) vaccination. The number of cases attributable to vaccination was approximately 2 per 1 million doses. The excess risk was observed only in persons 50 years of age or older.

“In Quebec, the individual risk of hospitalization following a documented influenza A(H1N1) infection was 1 per 2,500 and the risk of death was 1/73,000. The H1N1 vaccine was very effective in preventing infections and complications. It is likely that the benefits of immunization outweigh the risks,” the authors write.

Source: Neuroscience News

ScienceDaily (July 10, 2012) — Researchers at Georgetown University Medical Center appear to have solved the mystery of why some patients infected with HIV, who are using antiretroviral therapy and show no signs of AIDS, develop serious depression as well as profound problems with memory, learning, and motor function. The finding might also provide a way to test people with HIV to determine their risk for developing dementia.

They say the answer, published in the July 11 issue of the Journal of Neuroscience, may ultimately lead to a therapeutic solution that helps these patients as well as others suffering from brain ailments that appear to develop through the same pathway, including those that occur in the aged.

"We believe we have discovered a general mechanism of neuronal decline that even explains what happens in some elderly folks," says the study’s lead investigator, Italo Mocchetti, Ph.D., professor and vice chair of the department of neuroscience at Georgetown University Medical Center. "The HIV-infected patients who develop this syndrome are usually quite young, but their brains act old."

The research team found that even though HIV does not infect neurons, it tries to stop the brain from producing a protein growth factor — mature brain derived neurotrophic factor (mature BDNF) — that Mocchetti says acts like “food” for brain neurons. Reduced mature BDNF results in the shortening of the axons and their branches that neurons use to connect to each other, and when they lose this communication, the neurons die.

"The loss of neurons and their connections is profound in these patients," Mocchetti says. HIV-associated dementia occurs in two to three percent of HIV-infected patients using retroviral therapies, all of who appear to be otherwise healthy, and in 30 percent of HIV-positive patients who are not on medication.

Mocchetti believes that HIV stops production of mature BDNF because that protein interferes with the ability of the virus to attack other brain cells. It does this through the potent gp120 envelope protein that sticks out from the viral shell — the same protein that hooks on to brain macrophages and microglial cells to infect them. “In earlier experiments, when we dumped gp120 into neuronal tissue culture, there was a 30-40 percent loss of neurons overnight. That makes gp120 a remarkable neurotoxin.”

This study is the product of years of work that has resulted in a string of publications. It began when Mocchetti and his colleagues were given a grant from the National Institutes on Drug Abuse to determine whether there was a connection between the use of cocaine and morphine, and dementia. (A substantial number of HIV-positive patients have been or currently are intravenous drugs users.)

They found that it was the virus that was responsible for the dementia, not the drugs, and so they set out to discover how the virus was altering neuronal function.

Their scientific break came when the researchers were able to study the blood of 130 women who were enrolled in the 17 year-old, nationwide WIHS (Women’s Interagency HIV Study, directed at Georgetown by Mary Young, M.D.), which has focused on the effects of HIV in infected females. In one seminal discovery, Mocchetti and colleagues found that when there was less BDNF in the blood, patients were at risk of developing brain abnormalities. He published this finding in 2011 in the May 15 issue of AIDS.

In this study, Mocchetti, Alessia Bachis, Ph.D., and their colleagues studied the brains of HIV-positive patients who had died, and who had developed HIV-associated dementia. They also found that neurons had shrunk, and that mature BDNF had substantially decreased.

He and his colleagues then worked out the mechanism responsible for this destruction of neurons.

Normally, neurons release a long form of BDNF known as proBDNF, and then certain enzymes, including one called furin, cleave proBDNF to produce mature BDNF, which then nurtures brain neurons. When uncut, proBDNF is toxic, leading to “synaptic simplification,” or the shortening of axons. It does this by binding to a receptor, p75NTR, that contains a death domain.

"HIV interferes with that normal process of cleaving proBDNF, resulting in neurons primarily secreting a toxic form of BDNF," Mocchetti says. The same imbalance between mature BDNF and proBDNF occurs as we age, he says, although no one knows how that happens. "The link between depression and lack of mature BDNF is also known, as is the link to issues of learning and memory. That’s why I say HIV-associated dementia resembles the aging brain."

Loss of mature BDNF has also been suggested to be a risk factor in chronic diseases such as Parkinson’s and Huntington’s diseases, Mocchetti says.

The findings suggest a possible therapeutic intervention, he adds. “One way would be to use a small molecule to block the p75NTR receptor that proBDNF uses to kill neurons. A small molecule like that could get through the blood-brain barrier.

"If this works in HIV-dementia, it may also work in other brain issues caused by proBDNF, such as aging," Mocchetti adds.

The finding also suggests that measuring proBDNF in HIV-positive patients may provide a biomarker of risk for development of dementia, he adds.

"This finding is extremely important for both basic scientists and physicians, because it suggests a new avenue to understand, and treat, a fairly widespread cause of dementia," Mocchetti says.

Source: Science Daily

July 10, 2012

The ability for substances to pass through the blood-brain barrier is increased after adult stroke, but not after neonatal stroke, according to a new study the UCSF that will be published July 11 in the Journal of Neuroscience.

The blood-brain barrier is selectively permeable and blocks unwanted molecules from entering into the brain. The selectivity is achieved through fine coordination in function of many transporting systems in endothelial cells, which line the interior of blood vessels, and communication between endothelial cells and several types of cells in the brain. When blood flow in an artery to the brain is blocked by a blood clot, as occurs in arterial stroke, brain energy metabolism is compromised, and ion and other transporting systems malfunction, leading to blood-brain disruption.

The new finding suggests, the researchers said, that drugs used to treat stroke need to be tailored to the specific makeup of the neonate blood-brain barrier.

"How the blood-brain barrier responds to stroke in adults and neonates currently is poorly understood,” said senior author Zinaida Vexler, PhD, director of research at the Neonatal Brain Disorders Center at the Department of Neurology at UCSF.

"The assumption has been that at birth the blood-brain barrier is immature and thus permeable and that a neonatal brain responds in the same way to injury as an adult brain. This would mean that, after a stroke, the blood-brain barrier is an open gate and different molecules could go in and out, like a floodgate,” she said. “But in neonatal stroke the situation is very different, and this study shows that the neonatal brain has the ability to protect itself by limiting blood-brain barrier permeability.”

In the study, the scientists examined the structural and functional aspects of the blood-brain barrier in live rats that had acute stroke, and found that the blood-brain barrier was markedly more intact in neonatal rats than in adult rats.

The study compared vascular responses to injury in an adult arterial stroke model and an age-appropriate model of neonatal arterial stroke using several blood-brain barrier permeability procedures. Injected molecules that remained in blood vessels under normal conditions leaked into the injured tissue of the adult rats, but the same molecules remained in vessels of neonatal injured rats within 24 hours after injury.

Importantly, the vessels remained intact for molecules of various sizes. The study also showed a different composition of several barrier structural proteins in neonates versus adults, as well as a differential response to stroke at both ages, findings that likely are to contribute to the higher resistance of the neonatal blood-brain barrier after stroke. The study also showed age-related differences in communication between circulating white blood cells and the blood-brain barrier. Neutrophils — a subtype of leukocytes — stuck to injured vasculature and entered the adult brain shortly after stroke, releasing toxic molecules and reactive oxidants and producing damage. In contrast, only a few neutrophils were able to enter the injured neonatal brain. However, pharmacological change – in communication of neutrophils with injured vessels in the neonate made injury worse.

"This study is a very critical step towards developing therapeutics, but these findings are a tip of the iceberg and a lot is still to be learned," said Vexler. "We’re moving to characterize the potential for neonatal repair. Some brain damage can’t be diagnosed early, but might show up later. Now we are experimenting with postponing certain treatments or tweaking some signaling mechanisms to see if we can enhance the capacity of the immature brain to repair itself."

Provided by University of California, San Francisco

Source: medicalxpress.com

ScienceDaily (July 10, 2012) — People who are born deaf process the sense of touch differently than people who are born with normal hearing, according to research funded by the National Institutes of Health. The finding reveals how the early loss of a sense — in this case hearing — affects brain development. It adds to a growing list of discoveries that confirm the impact of experiences and outside influences in molding the developing brain.

People who are born deaf process the sense of touch differently than people who are born with normal hearing, according to research funded by the National Institutes of Health. The finding reveals how the early loss of a sense — in this case hearing — affects brain development. (Credit: © James Steidl / Fotolia)

The study is published in the July 11 online issue of The Journal of Neuroscience.

The researchers, Christina M. Karns, Ph.D., a postdoctoral research associate in the Brain Development Lab at the University of Oregon, Eugene, and her colleagues, show that deaf people use the auditory cortex to process touch stimuli and visual stimuli to a much greater degree than occurs in hearing people. The finding suggests that since the developing auditory cortex of profoundly deaf people is not exposed to sound stimuli, it adapts and takes on additional sensory processing tasks.

"This research shows how the brain is capable of rewiring in dramatic ways," said James F. Battey, Jr., M.D., Ph.D., director of the NIDCD. "This will be of great interest to other researchers who are studying multisensory processing in the brain."

Previous research, including studies performed by the lab director, Helen Neville Ph.D., has shown that people who are born deaf are better at processing peripheral vision and motion. Deaf people may process vision using many different brain regions, especially auditory areas, including the primary auditory cortex. However, no one has tackled whether vision and touch together are processed differently in deaf people, primarily because in experimental settings, it is more difficult to produce the kind of precise tactile stimuli needed to answer this question.

Dr. Karns and her colleagues developed a unique apparatus that could be worn like headphones while subjects were in a magnetic resonance imaging (MRI) scanner. Flexible tubing, connected to a compressor in another room, delivered soundless puffs of air above the right eyebrow and to the cheek below the right eye. Visual stimuli — brief pulses of light — were delivered through fiber optic cables mounted directly below the air-puff nozzle. Functional MRI was used to measure reactions to the stimuli in Heschl’s gyrus, the site of the primary auditory cortex in the human brain’s temporal lobe as well as other brain areas.

The researchers took advantage of an already known perceptual illusion in hearing people known as the auditory induced double flash, in which a single flash of light paired with two or more brief auditory events is perceived as multiple flashes of light. In their experiment, the researchers used a double puff of air as a tactile stimulus to replace the auditory stimulus, but kept the single flash of light. Subjects were also exposed to tactile stimuli and light stimuli separately and time-periods without stimuli to establish a baseline for brain activity.

Hearing people exposed to two puffs of air and one flash of light claimed only to see a single flash. However, when exposed to the same mix of stimuli, the subjects who were deaf saw two flashes. Looking at the brain scans of those who saw the double flash, the scientists observed much greater activity in Heschl’s gyrus, although not all deaf brains responded to the same degree. The deaf individuals with the highest levels of activity in the primary auditory cortex in response to touch also had the strongest response to the illusion.

"We designed this study because we thought that touch and vision might have stronger interactions in the auditory cortices of deaf people," said Dr. Karns." As it turns out, the primary auditory cortex in people who are profoundly deaf focuses on touch, even more than vision, in our experiment."

There are several ways the finding may help deaf people. For example, if touch and vision interact more in the deaf, touch could be used to help deaf students learn math or reading. The finding also has the potential to help clinicians improve the quality of hearing after cochlear implants, especially among congenitally deaf children who are implanted after the ages of 3 or 4. These children, who have lacked auditory input since birth, may struggle with comprehension and speech because their auditory cortex has taken on the processing of other senses, such as touch and vision. These changes may make it more challenging for the auditory cortex to recover auditory processing function after cochlear implantation. Being able to measure how much the auditory cortex has been taken over by other sensory processing could offer doctors insights into the kinds of intervention programs that would help the brain retrain and devote more capacity to auditory processing.

Source: Science Daily

July 10, 2012

A new study published in the July 11 issue of the Journal of Neuroscience details the development of the first mouse model engineered to carry the most common mutation in Usher syndrome III causative gene (Clarin-1) in North America. Further, the research team from Case Western Reserve University School of Medicine used this new model to understand why mutation in Clarin-1 leads to hearing loss.

Usher Syndrome is an incurable genetic disease and it is the most common cause of the dual sensory deficits of deafness and blindness. It affects an estimated 50,000 Americans and many more worldwide. Clinically it is subdivided into types I-III based on the degree of deafness and the presence of balance disorder and each type is associated with distinct genes. While the progression of the disease is different with each type, all patients ultimately arrive at the same consequence. The focus of this study is Usher type III. More than a dozen genetic mutations are associated with Usher III, with ‘N48K’ mutation in Clarin-1 being the most prevalent mutation in Usher III patients in North America. Since N48K mutation originated in Europe, results of this study will be of significance to a subset of Usher III patients in Europe as well.

"With the prospective of designing and exploring therapies for Usher III patients with N48K mutation, this is a significant preclinical finding," says Kumar Alagramam, PhD, associate professor of otolaryngology head & neck surgery, genetics, and neurosciences and senior author of the manuscript. "This key understanding of how deafness occurs in Usher III is based on three years of collaborative work."

This new study reports on the first mouse model that mimicked the N48K mutation in Usher III patients. The genetically engineered mouse developed hearing loss similar to clinical presentations observed in Usher III patients with N48K mutation. This model allowed researchers to understand the pathophysiology in fine detail, as there is no non-invasive way to evaluate soft tissue pathology in the human inner ear.

The new study explains why the mutation in the N48K mutation in Clarin-1 leads to hearing loss – mislocalization of mutant protein in mechanosensory hair cells of the inner ear. Using this new Usher III model, researchers can now explore prospective therapeutics to rescue mutant protein localization and hearing. If successful, this approach could serve as a model to treat Usher I and II associated with missense mutation.

In 2009, Alagramam et al reported on the first mouse model of Usher III. The first mouse model was gene knockout mutation and most recent mouse model is a missense mutation, the first model of its kind for Usher III.

Provided by Case Western Reserve University

Source: medicalxpress.com

July 9, 2012

In the last ten years, a new understanding of pediatric brain injury and recovery has emerged. Professionals now understand that recovery may be a lifelong process for the child’s entire circle of family, friends, and healthcare providers. The latest efforts to advance medical and rehabilitative services to move children from medical care and rehabilitation to community reintegration are discussed by the leading experts in a recently published special issue of NeuroRehabilitation.

“Recovery extends well beyond the technical period of rehabilitation,” say guest editors and noted authorities Peter D. Patrick, PhD, MS, Associate Professor Emeritus of the University of Virginia School of Medicine in Charlottesville, and Ronald C. Savage, EdD, Chairman, North American Brain Injury Society and International Pediatric Brain Injury Society. “Children, adolescents, and families struggle to regain the momentum of their life so as to reduce problems, increase opportunity, and support increased participation in work, play, home, and relationships.”

Neural plasticity introduces unknown challenges in the care of the recovering brain, and the issue addresses the most challenging and demanding medical conditions that children may confront following severe brain injury. However, children do most of their recovery at home, in school, and in the community, beyond medical surveillance. “Family-centered” approaches to developing interventions are emerging. For example, Dr. Damith T. Woods and colleagues report on a novel telephone support program to help parents manage challenging behavior associated with brain injury.

Children and adolescents with brain injuries have difficulty adjusting to their injuries and altered abilities, and frequently suffer from low self-esteem and loss of confidence. A study by Carol A. Hawley finds that children with traumatic brain injury have significantly lower self-esteem than normal children, and recommends that rehabilitation strategies promote a sense of self-worth.

Re-entry into school is a major milestone of recovery and the issue highlights a number of efforts to help children improve and return to a positive developmental trajectory. An article by Beth Wicks describes an innovative program in Britain that looks at “education as rehabilitation,” translating successful adult vocational programs into educational rehabilitation programs for children. Lucia Willadino Braga and colleagues report on a program based on cooperative learning that helped preadolescents with acquired brain injury develop metacognitive strategies and improve self-concept, thereby helping empower the preadolescents in their social relationships.

"Over the years and in multiple places around the world, innovative and creative efforts have slowly revealed effective interventions for recovery," comment Dr. Patrick and Dr. Savage. "Increasingly the interventions are evidence-based. This issue is a contribution to the effort to improve outcomes for children and families."

Provided by IOS Press

Source: medicalxpress.com

ScienceDaily (July 9, 2012) — Scientists showed in mice that disabling a gene linked to a common pediatric tumor disorder, neurofibromatosis type 1 (NF1), made stem cells from one part of the brain proliferate rapidly. But the same genetic deficit had no effect on stem cells from another brain region.

The results can be explained by differences in the way stem cells from these regions of the brain respond to cancer-causing genetic changes.

NF1 is among the world’s most common genetic disorders, occurring in about one of every 3,000 births. It causes a wide range of symptoms, including brain tumors, learning disabilities and attention deficits.

Brain tumors in children with NF1 typically arise in the optic nerve and do not necessarily require treatment. If optic gliomas keep growing, though, they can threaten the child’s vision. By learning more about the many factors that contribute to NF1 tumor formation, scientists hope to develop more effective treatments.

"To improve therapy, we need to develop better ways to identify and group tumors based not just on the way they look under the microscope, but also on innate properties of their stem cell progenitors," says David H. Gutmann, MD, PhD, the Donald O. Schnuck Family Professor of Neurology.

The study appears July 9 in Cancer Cell. Gutmann also is the director of the Washington University Neurofibromatosis Center.

In the new study, researchers compared brain stem cells from two primary sources: the third ventricle, located in the midbrain, and the nearby lateral ventricles. Before birth and for a time afterward, both of these areas in the brain are lined with growing stem cells.

First author Da Yong Lee, PhD, a postdoctoral research associate, showed that the cells lining both ventricles are true stem cells capable of becoming nerve and support cells (glia) in the brain. Next, she conducted a detailed analysis of gene expression in both stem cell types.

"There are night-and-day differences between these two groups of stem cells," Gutmann says. "These results show that stem cells are not the same everywhere in the brain, which has real consequences for human neurologic disease."

The third ventricle is close to the optic chiasm, the point where the optic nerves cross and optic gliomas develop in NF1 patients. Lee and Gutmann postulated that stem cells from this ventricle might be the source of progenitor cells that can become gliomas in children with NF1.

To test the theory, they disabled the Nf1 gene in neural stem cells from the third and lateral ventricles in the mice. This same gene is mutated in patients with NF1, increasing their risk of developing tumors.

Lee found that loss of Nf1 activity had little effect on stem cells from the lateral ventricle, but stem cells from the third ventricle began to divide rapidly, a change that puts them closer to becoming tumors.

The third ventricle usually stops supplying stem cells to the brain shortly after birth. When researchers inactivated the Nf1 gene before the third ventricle closed, the mice developed optic gliomas. When they waited until the third ventricle had closed to inactivate the Nf1 gene, gliomas did not develop.

Gutmann plans further studies to determine whether all NF1-related optic gliomas form in cells descended from the third ventricle. He suspects that additional factors are necessary for optic gliomas to form in cooperation with Nf1 gene loss in third-ventricle stem cells.

"We have to recognize that cancers which appear very similar actually represent a collection of quite different diseases," he says. "Tumors are like us — they’re defined by where they live, what their families are like, the traumas they experience growing up, and a variety of other factors. If we can better understand the interplay of these factors, we’ll be able to develop treatments that are much more likely to succeed, because they’ll target what is unique about a specific patient’s tumor."

Source: Science Daily

ScienceDaily (July 9, 2012) — Nearly a third of adults with the most common type of brain cancer develop recurrent, invasive tumors after being treated with a drug called bevacizumab. The molecular underpinnings behind these detrimental effects have now been published by Cell Press in the July issue of Cancer Cell. The findings reveal a new treatment strategy that could reduce tumor invasiveness and improve survival in these drug-resistant patients.

"Understanding how and why these tumors adopt this invasive behavior is critical to being able to prevent this recurrence pattern and maximizing the benefits of bevacizumab," says study author Kan Lu of the University of California, San Francisco (UCSF).

Glioblastoma multiforme (GBM) is the most aggressive type of tumor originating in the brain. GBM tumors express high levels of vascular endothelial growth factor (VEGF), a protein that promotes the growth of new blood vessels that provide nutrients that allow tumors to expand. In 2009, the Food and Drug Administration approved bevacizumab, a VEGF inhibitor, for GBM patients who don’t respond to first-line therapies. Although the drug is initially effective, up to 30% of patients develop tumors that infiltrate deep into the brain, making surgery and treatment difficult.

To study how bevacizumab can lead to adverse effects, senior study author Gabriele Bergers of UCSF and her collaborators focused on hepatocyte growth factor (HGF), a protein that controls the growth and movement of cells, because they previously found a link between VEGF and HGF in GBM cells. In the new study, they found that VEGF inhibits the migration of GBM cells by decreasing HGF signaling through its receptor MET. Moreover, tumors were much less invasive — and survival improved — in mice with GBM tumors lacking both VEGF and MET rather than just VEGF alone. The results suggest that MET plays a critical role in GBM invasion when VEGF is blocked.

"These findings provide a rationale for therapeutically combining VEGF and MET inhibition so that patients can benefit from bevacizumab without developing more invasive tumors," Lu says. Because the VEGF and HGF/MET signaling pathways are active in a variety of tumors, this combined treatment strategy may also be applied to other types of cancer.

Source: Science Daily

ScienceDaily (July 9, 2012) — A hormone with anti-diabetic properties also reduces depression-like symptoms in mice, researchers from the School of Medicine at the UT Health Science Center San Antonio reported July 9.

All types of current antidepressants, including tricyclics and selective serotonin reuptake inhibitors, increase the risk for type 2 diabetes. “The finding offers a novel target for treating depression, and would be especially beneficial for those depressed individuals who have type 2 diabetes or who are at high risk for developing it,” said the study’s senior author, Xin-Yun Lu, Ph.D., associate professor of pharmacology and psychiatry and member of the Barshop Institute for Longevity and Aging Studies at the UT Health Science Center.

The hormone, called adiponectin, is secreted by adipose tissue and sensitizes the body to the action of insulin, a hormone that lowers blood sugar. “We showed that adiponectin levels in plasma are reduced in a chronic social defeat stress model of depression, which correlates with the degree of social aversion,” Dr. Lu said.

Facing Goliath over and over

In the study mice were exposed to 14 days of repeated social defeat stress. Each male mouse was introduced to the home cage of an unfamiliar, aggressive resident mouse for 10 minutes and physically defeated. After the defeat, the resident mouse and the intruder mouse each were housed in half of the cage separated by a perforated plastic divider to allow visual, olfactory and auditory contact for the remainder of the 24-hour period. Mice were exposed to a new resident mouse cage and subjected to social defeat each day. Plasma adiponectin concentrations were determined after the last social defeat session. Defeated mice displayed lower plasma adiponectin levels.

Withdrawal, lost pleasure and helplessness

When adiponectin concentrations were reduced by deleting one allele of the adiponectin gene or by a neutralizing antibody, mice were more susceptible to stress-induced social withdrawal, anhedonia (lost capacity to experience pleasure) and learned helplessness.

Mice that were fed a high-fat diet (60 percent calories from fat) for 16 weeks developed obesity and type 2 diabetes. Administration of adiponectin to these mice and mice of normal weight produced antidepressant-like effects.

Possible innovative approach for depression

"These findings suggest a critical role of adiponectin in the development of depressive-like behaviors and may lead to an innovative therapeutic approach to fight depression," Dr. Lu said.

A novel approach would benefit thousands. “So far, only about half of the patients suffering from major depressive disorders are treated to the point of remission with antidepressant drugs,” Dr. Lu said. “The prevalence of depression in the diabetic population is two to three times higher than in the non-diabetic population. Unfortunately, the use of current antidepressants can worsen the control of diabetic patients. Adiponectin, with its anti-diabetic activity, would serve as an innovative therapeutic target for depression treatments, especially for those individuals with diabetes or prediabetes and perhaps those who fail to respond to currently available antidepressants.”

Source: Science Daily

ScienceDaily (July 9, 2012) — A new study of aged female rats found that long-term treatment with estrogen and a synthetic progesterone known as MPA increased levels of a protein marker of synapses in the prefrontal cortex, a brain region known to suffer significant losses in aging.

The new findings appear to contradict the results of the Women’s Health Initiative, a long-term study begun in 1991 to analyze the effects of hormone therapy on a large sample of healthy postmenopausal women aged 50 to 79. Among other negative findings, the WHI found that long-term exposure to estrogen alone or to estrogen and MPA resulted in an increased risk of stroke and dementia. More recent research, however, suggests that starting hormone replacement therapy at the onset of menopause, rather than years or decades afterward, yields different results.

The new study, from researchers at the University of Illinois, is the first to look at the effects of long-term treatment with estrogen and MPA on the number of synapses in the prefrontal cortex of aged animals. The researchers describe their findings in a paper in the journal Menopause.

"The prefrontal cortex is the area of the human brain that loses the most volume with age," said U. of I. psychology professor and Beckman Institute affiliate Janice Juraska, who led the study with doctoral student Nioka Chisholm. "So understanding how anything affects the prefrontal cortex is important."

The prefrontal cortex, just behind the forehead in humans, governs what researchers call “executive function” — planning, strategic thinking, working memory (the ability to hold information in mind just long enough to use it), self-control and other functions that tend to decline with age.

Most studies of the effects of hormone treatments on the brain have focused on the hippocampus, a structure important to spatial navigation and memory consolidation. The studies tend to use young animals exposed to hormones for very brief periods of time (one or two days to a few weeks at the most). They have yielded mixed results, with most research in young female animals indicating an increase in hippocampal synapses and hippocampal function after exposure to estrogen and MPA.

"For some reason, a lot of researchers still look at the effects of hormones in young animals," Chisholm said. "And there’s a lot of evidence now saying that the aged brain is different; the effect of these hormones is not going to be the same."

The new study followed middle-aged rats exposed to estrogen alone, to no additional hormones, or to estrogen in combination with MPA for seven months, a time period that more closely corresponds to the experience of women who start hormone therapy at the onset of menopause and continue into old age. The researchers removed the rats’ ovaries just prior to the hormone treatment (or lack of treatment) to mimic the changes that occur in humans during menopause.

"Our most important finding is that estrogen in combination with MPA can result in a greater number of synapses in the prefrontal cortex than (that seen) in animals that are not receiving hormone replacement," Chisholm said. "Estrogen alone marginally increased the synapses, but it took the combination with MPA to actually see the significant effect."

"Our data indicate that re-examining the effects of estrogen and MPA, when first given to women around the time of menopause, is merited," Juraska said.

Source: Science Daily

July 9, 2012

A study of patients with stroke admitted to English National Health Service public hospitals suggests that patients who were hospitalized on weekends were less likely to receive urgent treatments and had worse outcomes, according to a report published Online First by Archives of Neurology.

Studies from other countries have suggested higher mortality in patients who were admitted to the hospital on weekends for a variety of medical conditions, a phenomenon known as “the weekend effect.” However, other studies have not identified an association between the day of admission and mortality rates due to stroke, so the debate over “the weekend effect” continues, according to the study background.

William L. Palmer, M.A., M.Sc., of Imperial College and the National Audit Office, and colleagues conducted a study of patients admitted to hospitals with stroke from April 2009 through March 2010, accounting for 93,621 admissions.

Performance across five of six measures was lower on weekends, with one of the largest disparities seen in rates of same-day brain scans (43.1 percent on weekends compared with 47.6 percent on weekdays). Also, the rate of seven-day, in-hospital mortality for Sunday admissions was 11 percent compared with a mean (average) of 8.9 percent for weekday admissions, according to study results.

"We calculated that approximately 350 potentially avoidable in-hospital deaths occur within seven days each year and that an additional 650 people could be discharged to their usual place of residence within 56 days if the performance seen on weekdays was replicated on weekends," the authors comment.

Provided by JAMA and Archives Journals

Source: medicalxpress.com

July 9, 2012

(Medical Xpress) — Have you ever found yourself paying attention to the sound of your footsteps when walking down a quiet corridor? Or perhaps you enjoy creating rhythmic patterns by tapping on a surface? Almost every bodily movement we make generates an impact sound and a team of academics have been studying whether the perception of the physical dimensions of our body can be challenged by spatially altering the ‘action’ sounds we make.

Self-action sounds help us understand physical properties of objects and our own body. Picture by Antonio Caballero

The research team from Royal Holloway, University of London conducted various experiments to determine whether our action sounds influence the way we picture ourselves and whether these perceptions change when the sound is manipulated.

Dr Manos Tsakiris from Royal Holloway said: “These sounds provide an important source of information about the physical properties of the objects and the space around us, but they also inform us about the physical properties of one’s own body, although we are mostly not aware of this process.”

The study, Action sounds recalibrate perceived tactile distance, is published in Current Biology and shows that increasing the distance to sound events produced when tapping on a surface with one’s arm influences the subsequent judgments of distance between two objects touching the arm. “Participants did not report feeling their own arm extended as a result of this test possibly because it is difficult for someone to accept that the dimensions of their body can change from one minute to the other. However, the increase in reported distance between two points touching one’s arm do suggest an unconscious change in the way participants mentally represented their arm, as if they would represent this arm as being longer,” Dr Tajadura-Jiménez explains.

The researchers hope this study could have clinical applications and help in the way chronic pain is treated or help motivate older people to move further or for longer than they previously thought was possibly by manipulating the action sounds they make.

Provided by Royal Holloway, University of London

Source: medicalxpress.com

July 9, 2012

(Medical Xpress) — Human brain cells showing aspects of Huntington’s Disease have been developed, opening up new research pathways for treating the fatal disorder.

An international consortium, including scientists from the School of Biosciences, has taken cells from Huntington’s Disease patients and generated human brain cells that develop aspects of the disease in the laboratory. The cells and the new technology will speed up research into understanding the disease and also accelerate drug discovery programs aimed at treating this terminal, genetic disorder.

Huntington’s Disease is an aggressive, neurodegenerative disorder which causes loss of co-ordination, psychiatric problems, dementia and death. Scientists have known the genetic cause of this disease for more than 20 years but research has been hampered by the lack of human brain cells with which to study the disease and screen for effective drugs.

The new breakthrough involves taking skin cells from patients with Huntington’s disease. The scientific team reprogrammed these cells into stem cells which were then turned into the brain cells affected by the disorder. The brain cells demonstrate characteristics of the disease and will allow the consortium to investigate the mechanisms that cause the brain cells to die.

Dr. Nicholas Allen, one of the lead investigators at the School of Biosciences, said: “This breakthrough allows us to generate brain cells with many of the hallmarks of this disease, within just a few weeks. This means that we can study both the normal physiology of these brain cells, and the pathological processes that lead to their death.”

The other Cardiff lead, Professor Paul Kemp, said: “Huntington’s Disease normally takes years to manifest in the human brain. Now we have a fast and reproducible model of this disease, offering fresh hope for the discovery of new therapies.”

The corresponding author of the paper, Professor Clive Svendsen, a UK scientist and now director of the Cedars-Sinai Regenerative Medicine Institute in the USA, said “This Huntington’s ‘disease in a dish’ will enable us for the first time to test therapies on human Huntington’s disease neurons. In addition to increasing our understanding of this disorder and offering a new pathway to identifying treatments, this study is remarkable because of the extensive interactions between a large group of scientists focused on developing this model. It’s a new way of doing trailblazing science.”

Director of the School of Biosciences, Professor Ole Petersen said: “This is an extremely important development and I am delighted to see colleagues from the School of Biosciences playing their part in this distinguished international team. I look forward to seeing future stages, when this new technique is put to work modeling the diseases and testing potential treatments.”

Provided by Cardiff University

Source: medicalxpress.com

ScienceDaily (July 9, 2012) — “Attentional blink” is the term psychologists use to describe our inability to recognize a second important object if we see it less than half a second after a first one. It always seemed impossible to overcome, but in a new paper in the Proceedings of the National Academy of Sciences, Brown University psychologists report they’ve found a way.

So far it has seemed an irreparable limitation of human perception that we strain to perceive things in the very rapid succession of, say, less than half a second. Psychologists call this deficit “attentional blink.” We’ll notice that first car spinning out in our path, but maybe not register the one immediately beyond it. It turns out, we can learn to do better after all. In a new study researchers now based at Brown University overcame the blink with just a little bit of training that was never been tried before.

"A color change can be very conspicuous. If all items are black and white and all of a sudden a color item is shown, you pay attention to that." Credit: Mike Cohea/Brown University"Attention is a very important component of visual perception," said Takeo Watanabe, professor of cognitive, linguistic and psychological sciences at Brown. "One of the best ways to enhance our visual ability is to improve our attentional function."

Watanabe and his team were at Boston University when they performed experiments described in a paper published the week of July 9 in the Proceedings of the National Academy of Sciences. The bottom line of the research is that making the second target object a distinct color is enough to train people to switch their attention more quickly than they could before. After that, they can perceive a second target object presented as quickly as a fifth of a second later, even when it isn’t distinctly colored.

Read More →

ScienceDaily (July 9, 2012) — Alzheimer’s disease is one of the most dreaded and debilitating illnesses one can develop. Currently, the disease afflicts 6.5 million Americans and the Alzheimer’s Association projects it to increase to between 11 and 16 million, or 1 in 85 people, by 2050.

Cell death in the brain causes one to grow forgetful, confused and, eventually, catatonic. Recently approved drugs provide mild relief for symptoms but there is no consensus on the underlying mechanism of the disease.

"We don’t know what the problem is in terms of toxicity," said Joan-Emma Shea, professor of chemistry and biochemistry at the University of California, Santa Barbara (UCSB). "This makes the disease difficult to cure."

Accumulations of amyloid plaques have long been associated with the disease and were presumed to be its cause. These long knotty fibrils, formed from misfolded protein fragments, are almost always found in the brains of diseased patients. Because of their ubiquity, amyloid fibrils were considered a potential source of the toxicity that causes cell death in the brain. However, the quantity of fibrils does not correspond with the degree of dementia and other symptoms.

New findings support a hypothesis that fibrils are a by-product of the disease rather than the toxic agent itself. This paradigm shift changes the focus of inquiry to smaller, intermediate molecules that form and dissipate quickly. These molecules are difficult to perceive in brain tissue.

Read More →

July 10, 2012 by Anne Trafton

A clinical trial of an Alzheimer’s disease treatment developed at MIT has found that the nutrient cocktail can improve memory in patients with early Alzheimer’s. The results confirm and expand the findings of an earlier trial of the nutritional supplement, which is designed to promote new connections between brain cells.

A graphic depicting a synapse, a connection between brain cells. Graphic: Christine Daniloff

Alzheimer’s patients gradually lose those connections, known as synapses, leading to memory loss and other cognitive impairments. The supplement mixture, known as Souvenaid, appears to stimulate growth of new synapses, says Richard Wurtman, a professor emeritus of brain and cognitive sciences at MIT who invented the nutrient mixture.

“You want to improve the numbers of synapses, not by slowing their degradation — though of course you’d love to do that too — but rather by increasing the formation of the synapses,” Wurtman says.

To do that, Wurtman came up with a mixture of three naturally occurring dietary compounds: choline, uridine and the omega-3 fatty acid DHA. Choline can be found in meats, nuts and eggs, and omega-3 fatty acids are found in a variety of sources, including fish, eggs, flaxseed and meat from grass-fed animals. Uridine is produced by the liver and kidney, and is present in some foods as a component of RNA.

These nutrients are precursors to the lipid molecules that, along with specific proteins, make up brain-cell membranes, which form synapses. To be effective, all three precursors must be administered together.

Results of the clinical trial, conducted in Europe, appear in the July 10 online edition of the Journal of Alzheimer’s Disease. The new findings are encouraging because very few clinical trials have produced consistent improvement in Alzheimer’s patients, says Jeffrey Cummings, director of the Cleveland Clinic’s Lou Ruvo Center for Brain Health.

“Memory loss is the central characteristic of Alzheimer’s, so something that improves memory would be of great interest,” says Cummings, who was not part of the research team.

Plans for commercial release of the supplement are not finalized, according to Nutricia, the company testing and marketing Souvenaid, but it will likely be available in Europe first. Nutricia is the specialized health care division of the food company Danone, known as Dannon in the United States.

Making connections

Wurtman first came up with the idea of targeting synapse loss to combat Alzheimer’s about 10 years ago. In animal studies, he showed that his dietary cocktail boosted the number of dendritic spines, or small outcroppings of neural membranes, found in brain cells. These spines are necessary to form new synapses between neurons.

Following the successful animal studies, Philip Scheltens, director of the Alzheimer Center at VU University Medical Center in Amsterdam, led a clinical trial in Europe involving 225 patients with mild Alzheimer’s. The patients drank Souvenaid or a control beverage daily for three months.

That study, first reported in 2008, found that 40 percent of patients who consumed the drink improved in a test of verbal memory, while 24 percent of patients who received the control drink improved their performance.

The new study, performed in several European countries and overseen by Scheltens as principal investigator, followed 259 patients for six months. Patients, whether taking Souvenaid or a placebo, improved their verbal-memory performance for the first three months, but the placebo patients deteriorated during the following three months, while the Souvenaid patients continued to improve. For this trial, the researchers used more comprehensive memory tests taken from the neuropsychological test battery, often used to assess Alzheimer’s patients in clinical research.

Patients showed a very high compliance rate: About 97 percent of the patients followed the regimen throughout the study, and no serious side effects were seen.

Both clinical trials were sponsored by Nutricia. MIT has patented the mixture of nutrients used in the study, and Nutricia holds the exclusive license on the patent.

Brain patterns

In the new study, the researchers used electroencephalography (EEG) to measure how patients’ brain-activity patterns changed throughout the study. They found that as the trial went on, the brains of patients receiving the supplements started to shift from patterns typical of dementia to more normal patterns. Because EEG patterns reflect synaptic activity, this suggests that synaptic function increased following treatment, the researchers say.

Patients entering this study were in the early stages of Alzheimer’s disease, averaging around 25 on a scale of dementia that ranges from 1 to 30, with 30 being normal. A previous trial found that the supplement cocktail does not work in patients with Alzheimer’s at a more advanced stage. This makes sense, Wurtman says, because patients with more advanced dementia have probably already lost many neurons, so they can’t form new synapses.

A two-year trial involving patients who don’t have Alzheimer’s, but who are starting to show mild cognitive impairment, is now underway. If the drink seems to help, it could be used in people who test positive for very early signs of Alzheimer’s, before symptoms appear, Wurtman says. Such tests, which include PET scanning of the hippocampus, are now rarely done because there are no good Alzheimer’s treatments available.

Provided by Massachusetts Institute of Technology

Source: medicalxpress.com

ScienceDaily (July 6, 2012) — In a forthcoming issue of Topics in Cognitive Science researchers from the University of Amsterdam (UvA) argue that at least two, seemingly trivial musical skills can be considered fundamental to the evolution of music: relative pitch — the skill to recognise a melody independent of its pitch level — and beat induction — the skill to pick up regularity (the beat) from a varying rhythm. Both are considered cognitive mechanisms that are essential to perceive, make and appreciate music, and, as such, could be argued to be conditional to the origin of music.

While it recently became quite popular to address the study of the origins of music from an evolutionary perspective, there is still little agreement on the idea that music is in fact an adaptation, that it influenced our survival, or that it made us sexually more attractive. Music appears to be of little use. It doesn’t quell our hunger, nor do we live a day longer because of it. So why argue that music is an adaptation? There are even researchers who claim that studying the evolution of cognition is virtually impossible (Lewontin, 1998; Bolhuis & Wynne, 2009).

Distinguishing between music and musicality

The alternative that Henkjan Honing and Annemie Ploeger of the UvA propose is, first, to distinguish between the notion of ‘music’ and ‘musicality’, with musicality being defined as a natural, spontaneously developing trait based on and constrained by our cognitive system, and music as a social and cultural construct based on that very musicality. And secondly, to collect accumulative evidence from a variety of sources (e.g., psychological, physiological, genetic, phylogenetic, and cross-cultural evidence) to be able to show that a specific cognitive trait is indeed an adaptation.

Both relative pitch and beat induction are suggested as primary candidates for such cognitive traits, musical skills that are considered trivial by most humans, but that turn out to be quite special in the rest of the animal world.

Once these fundamental cognitive mechanisms are identified, it becomes possible to see how these might have evolved. In short: the study of the evolution of music cognition is conditional on a characterisation of the basic mechanisms that make up musicality.

Source: Science Daily

ScienceDaily (July 6, 2012) — If you’re concerned about losing your hearing because of noise exposure (earbud deafness syndrome), a new discovery published online in the FASEB Journal offers some hope. That’s because scientists from Germany and Canada show that the protein, AMPK, which protects cells during a lack of energy, also activates a channel protein in the cell membrane that allows potassium to leave the cell. This activity is important because this mechanism helps protect sensory cells in the inner ear from permanent damage following acoustic noise exposure.

This information could lead to new strategies and therapies to prevent and treat trauma resulting from extreme noise, especially in people with AMPK gene variants that may make them more vulnerable to hearing loss.

"Future research on the basis of the present study may lead to the development of novel strategies preventing noise-induced hearing loss or accelerating recovery from acoustic trauma," said Florian Lang, Ph.D., a researcher involved in the work from the Department of Physiology at the University of Tübingen, in Tübingen, Germany.

To make this discovery, Lang and colleagues compared two groups of mice. The first group was normal and the second lacked the AMPK protein. Hearing of the mice was tested by measuring sound-induced brain activity. All mice were exposed to well-defined noise causing an acoustic trauma and leading to hearing impairment. Prior to noise exposure, the hearing ability was similar in normal mice and mice lacking AMPK. After exposure, the hearing of the normal mice mostly recovered after two weeks, but the recovery of hearing in AMPK-deficient mice remained significantly impaired.

"When it comes to preventing hearing loss, keeping the volume down is still the best strategy, and this discovery doesn’t prevent loud music from beating on our ear drums," said Gerald Weissmann, M.D., Editor-in-Chief of the FASEB Journal. “This discovery does help explain why some people seem more likely to lose their hearing than others. At the same time, it also provides a target for new preventive strategies — and perhaps even a treatment — for earbud deafness syndrome.”

Source: Science Daily

July 6, 2012

(Medical Xpress) — Scientists at the University of Liverpool have found that a protein produced by a gene identified in fruitflies, is responsible for communication between nerve cells in the brain.

Dr Stephen Royle: “This research is another step towards fully understanding the complexities of the human brain.”

The ‘stoned’ gene was discovered in fruitflies by scientists in the 1970s. When this gene was mutated, the flies had problems walking and flying, giving rise to the term ‘stoned’ gene. The same gene was found in mammals some years later, but until now scientists have not known precisely what this gene is responsible for and why it causes problems with physical functions when it mutates.

‘Packets of chemicals’

Scientists at Liverpool have found that the protein the gene expresses in mammals, called stonin2, is responsible for retrieving ‘packets’ of chemicals that nerve cells in the brain release in order to communicate with each other.  The inability of the gene to express this protein in the fruitfly study, suggests why the insect appeared not to be able to walk or fly normally.

The team used advanced techniques to inactivate stonin2 for short and long periods of time in animal cells grown in the laboratory. The cells used where from an area of the brain associated with learning and memory.  They showed that without stonin2 the nerve cells could not retrieve the ‘packets’ needed to transport the chemicals required for communications between nerve cells.

Dr Stephen Royle, from the University’s Institute of Translational Medicine, explains: “Nerve cells in the brain communicate by releasing ‘packets’ of chemicals.  These ‘packets’ must be retrieved and refilled with chemicals so that they can be used once again. This recycling programme is very important for nerve cells to keep communicating with each other. 

“We have shown that a protein called stonin 2 is needed for the packets to be retrieved. There is currently no evidence to suggest that the gene which expresses this protein is mutated in human disease, but any failure in its function would be disastrous.  The research is another step towards fully understanding the complexities of the human brain.”

The research is published in the journal, Current Biology.

Provided by University of Liverpool

Source: medicalxpress.com

ScienceDaily (July 6, 2012) — Yona Goldshmit, Ph.D., is a former physical therapist who worked in rehabilitation centers with spinal cord injury patients for many years before deciding to switch her focus to the underlying science.

"After a few years in the clinic, I realized that we don’t really know what’s going on," she said.

Now a scientist working with Peter Currie, Ph.D., at Monash University in Australia, Dr. Goldshmit is studying the mechanisms of spinal cord repair in zebrafish, which, unlike humans and other mammals, can regenerate their spinal cord following injury. On June 23 at the 2012 International Zebrafish Development and Genetics Conference in Madison, Wisconsin, she described a protein that may be a key difference between regeneration in fish and mammals.

One of the major barriers to spinal regeneration in mammals is a natural protective mechanism, which incongruously results in an unfortunate side effect. After a spinal injury, nervous system cells called glia are activated and flood the area to seal the wound to protect the brain and spinal cord. In doing so, however, the glia create scar tissue that acts as a physical and chemical barrier, which prevents new nerves from growing through the injury site.

One striking difference between the glial cells in mammals and fish is the resulting shape: mammalian glia take on highly branched, star-like arrangements that appear to intertwine into dense tissue. Fish glia cells, by contrast, adopt a simple elongated shape — called bipolar morphology — that bridges the injury site and appears to help new nerve cells grow through the damaged area to heal the spinal cord.

"Zebrafish don’t have so much inflammation and the injury is not so severe as in mammals, so we can actually see the pro-regenerative effects that can happen," Dr. Goldshmit explained.

Studies in mice have found that mammalian glia can take up the same elongated shape, but in response to the environment around the injury they instead mature into scar tissue that does not allow nerve regrowth.

Dr. Goldshmit and her colleagues have focused on a family of molecules called fibroblast growth factors (Fgf), which have shown some evidence of improving recovery in mice and humans with spinal cord damage. The Monash University group found that Fgf activity around the damage site promotes the bipolar glial shape and encourages nerve regeneration in zebrafish.

Preliminary results in mice show that Fgf injections near a spinal injury increase both the number of glia cells at the site and the elongated morphology. Their evidence suggests that Fgfs may work to create an environment more supportive of regeneration in mammals as well and could be a valuable therapeutic target.

Spinal injury patients usually have few options, Dr. Goldshmit emphasized, and development of new, biologically-based approaches will be critical.

"This is a nice example of how we can use the zebrafish model," she said. "When we learn from the zebrafish what to look at, we can find things that give us hope for finding therapeutic approaches for spinal cord injury in humans."

Source: Science Daily

July 6, 2012 by Nancy Owano

(Phys.org) — Talk about fMRI may not be entirely familiar to many people, but that could change with new events that are highlighting efforts to link up humans and machines. fMRI (Functional Magnetic Resonance Imaging) is a promising technology that can help human move beyond joysticks to control robots via brain scanners instead. Now a research project exploring ways to develop robot surrogates with whom humans can interact has turned a corner. A university student‘s ability to make his robot surrogate move around, using fMRI technology, was successful. The experiment linked up Israeli student Tirosh Shapira in a lab at Bar-Ilan University, Israel, with a small robot in another lab far away at Beziers Technology Institute in France.

Shapira merely had to think about moving his arms or legs and the robot, with a camera on its head with an image displayed in front of Shapira, successfully would do the same. If Shapira thought about moving forward or backward, the robot responded accordingly.

fmri monitors blood flowing through the brain and can spot when areas associated with certain actions, such as movement, are in use. The fMRI read the student’s thoughts, which were translated via computer into commands relayed across the Internet to the robot in France.

There is much more work to be done to advance this approach, however. The researchers seek to devise a different type of scanning. An fMRI scanner is an expensive piece of equipment but the scientists believe that improvements in software might allow for a head-mounted device. Another research goal is to see if they can get humans to speak via the robot. The size of the robot will need modification, closer to the size and movement of a human, and engineered with a wider range of movement that would include hand gestures. In sum, according to the researchers, this experiment is only one of many steps ahead.

Medical applications for this technology are seen as promising, especially as scientists explore how patients with paralysis can interface with robots so that the patients can reconnect to the world. Another suggested application has been in the military, where robot surrogates rather than soldiers would be sent into battle.

Source: PHYS.ORG

July 6, 2012

(Medical Xpress) — Researchers decode a molecular mechanism that sheds light on how trauma can become engraved in the brain

Scientists at the Universities of Bonn and Berlin have discovered a mechanism which stops the process of forgetting anxiety after a stress event. In experiments they showed that feelings of anxiety don’t subside if too little dynorphin is released into the brain. The results can help open up new paths in the treatment of trauma patients. The study has been published in the current edition of the Journal of Neuroscience.

Feelings of anxiety very effectively prevent people from getting into situations that are too dangerous. Those who have had a terrible experience initially tend to avoid the place of tragedy out of fear. If no other oppressive situation arises, normally the symptoms of fear gradually subside. “The memory of the terrible events is not just erased.” states first author, PD Dr. Andras Bilkei Gorzo, from the Institute for Molecular Psychiatry at the University of Bonn. “Those impacted learn rather via an active learning process that they no longer need to be afraid because the danger has passed.” But following extreme psychical stress resulting from wars, hostage-takings, accidents or catastrophes chronic anxiety disorders can develop which even after months don’t subside.

Body’s own dynorphin weakens fears

Why is it that in some people terrible events are deeply engraved in their memory, while after a while others seem to have completely put aside any anxiety related to the incident? Scientists in the fields of psychiatry, molecular psychiatry and radiology at the University of Bonn are all involved in probing this issue. “We were able to demonstrate by way of a series of experiments that dynorphin plays an important role in weakening anxiety,” says Prof. Dr. Andreas Zimmer, Director of the Institute for Molecular Psychiatry at the University of Bonn. The substance group in question is opiods which also includes, for instance, endorphins. The latter are released by the body of athletes and have an analgesic and euphoric effect. The reverse, however, is true of dynorphins: They are known for putting a damper on emotional moods.

Mice with disabled gene exhibit persistent anxiety

The team working with Prof. Zimmer tested the exact impact of dynorphins on the brain using mice whose gene for the formation of this substance had been disabled. After being exposed to a brief and unpleasant electric shock, the animals exhibited persistent anxiety symptoms, even if they hadn’t been confronted with the negative stimulus over a longer time. Mice exhibiting a normal amount of released dynorphin were anxious to begin with as well, but the symptoms quickly subsided. “This behavior is the same in humans: If you burn your hand on the stove once, you don’t forget the incident that quickly,” explains Prof. Zimmer. “Learning vocabulary, on the other hand, typically tends to be more tedious because it’s not tied to emotions.”

Results are transferrable to people

Next the researchers showed that these results can be transferred to people. “We took advantage of the fact that people exhibit natural variations of the dynorphin gene that lead to different levels of this substance being released in the brain,” reports Prof. Dr. Henrik Walter, Director of the Research Area Mind and Brain at the Psychiatric University Clinic at the Charité in Berlin, who also used to perform research in this area at the University Clinic in Bonn. A total of 33 healthy probands were divided into two groups: One with the genetically stronger dynorphin release and the other which exhibits less gene activity.

Unpleasant stimulus leads to stress reactions in the probands

Equipped with computer glasses the probands observed blue and green squares which appeared and then disappeared again in a magnetic resonance tomograph (MRT). When the green square was visible the scientists repeatedly gave probands an unpleasant stimulus on the hand using a laser. Scientists were able to prove that these negative stimuli actually led to a stress reaction given the increased sweat on the skin. At the same time, researchers recorded the activities of various brain areas with the tomograph. After this conditioning stage came part two of the experiment: The researchers showed the colored squares without any unpleasant stimuli and recorded how long the stress reaction acquired earlier lasted. The next day the experiment was continued without the laser stimulus in an effort to monitor the longer-term development.

New paths in the treatment of trauma patients

It became apparent that, as in mice human, probands with lower gene activity for dynorphin exhibited stress reactions lasting considerably longer than those probands who released considerably more. Moreover, in brain scans it could be observed that the amygdala – a brain structure in the temporal lobes that processes emotional contents - was also active even if in later testing rounds a green square was shown without the subsequent laser stimulus.

“After the negative laser stimulus stopped this amygdala activity gradually became weaker. This means that the acquired anxiety reaction to the stimulus was forgotten,” reports Prof. Walter. This effect was not as pronounced in the group with less dynorphin activity and prolonged anxiety. “But the ‘forgetting’ of acquired anxiety reactions isn’t a fading, but, rather, an active process which involves the ventromedial prefrontal cortex,” emphasizes Prof. Walter. To corroborate this, researchers found that in the group with less dynorphin activity there was reduced coupling between the prefrontal cortex and the amygdala. “In all likelihood dynorphins affect fear forgetting in a crucial way through this structure,” says Prof. Walter. The scientists now hope that by using the results they will be able to develop long-term approaches for new strategies when it comes to the treatment of trauma patients.

Provided by University of Bonn

Source: medicalxpress.com

ScienceDaily (July 5, 2012) — A gene whose mutation results in malformed faces and skulls as well as mental retardation has been found by scientists.

They looked at patients with Potocki-Shaffer syndrome, a rare disorder that can result in significant abnormalities such as a small head and chin and intellectual disability, and found the gene PHF21A was mutated, said Dr. Hyung-Goo Kim, molecular geneticist at the Medical College of Georgia at Georgia Health Sciences University.

The scientists confirmed PHF21A’s role by suppressing it in zebrafish, which developed head and brain abnormalities similar to those in patients. “With less PHF21A, brain cells died, so this gene must play a big role in neuron survival,” said Kim, lead and corresponding author of the study published in The American Journal of Human Genetics. They reconfirmed the role by giving the gene back to the malformed fish — studied for their adeptness at regeneration — which then became essentially normal. They also documented the gene’s presence in the craniofacial area of normal mice.

While giving the normal gene unfortunately can’t cure patients as it does zebrafish, the scientists believe the finding will eventually enable genetic screening and possibly early intervention during fetal development, including therapy to increase PHF21A levels, Kim said. It also provides a compass for learning more about face, skull and brain formation.

The scientists zeroed in on the gene by using a distinctive chromosomal break found in patients with Potocki-Shaffer syndrome as a starting point. Chromosomes — packages of DNA and protein — aren’t supposed to break, and when they do, it can damage genes in the vicinity.

"We call this breakpoint mapping and the breakpoint is where the trouble is," said Dr. Lawrence C. Layman, study co-author and Chief of the MCG Section of Reproductive Endocrinology, Infertility and Genetics. Damaged genes may no longer function optimally; in PHF21A’s case it’s about half the norm.

"When you see the chromosome translocation, you don’t know which gene is disrupted," Layman said. "You use the break as a focus then use a bunch of molecular techniques to zoom in on the gene." Causes of chromosomal breaks are essentially unknown but likely are environmental and/or genetic, Kim said.

Little was known about PHF21A other than its role in determining how tightly DNA is wound in a package with proteins called histones. How tightly DNA is wound determines whether proteins called transcription factors have the access needed to regulate gene expression, which is important, for example, when a gene needs to be expressed only at a specific time or tissue. PHF21A is believed to primarily work by suppressing other genes, for example, ensuring that genes that should be expressed only in brain cells don’t show up in other cell types, Kim said.

Next steps include using PHF21A as a sort of geographic positioning system to identify other “depressor” genes it regulates then screening patients to look for mutations in those genes as well. “We want to find other people with different genes causing the same problem,” Layman said, and they suspect the genes PHF21A interacts with or regulates are the most likely suspects. It’s too early to know what percentage of Potocki-Shaffer syndrome patients have the PHF21A mutation, Kim noted. “Now that we know the causative gene, we can sequence the gene in more patients and see if they have a mutation,” Layman said.

They also want to look at less-severe forms of mental deficiency, including autism, for potentially milder mutations of PHF21A. More than a dozen of the 25,000 human genes are known to cause craniofacial defects and mental retardation, which often occur together, Kim said.

Source: Science Daily