Posts tagged science

ScienceDaily (May 30, 2012) — Bipolar disorder is a serious and debilitating condition where individuals experience severe swings in mood between mania and depression. The episodes of low or elevated mood can last days or months, and the risk of suicide is high.

Antidepressants are commonly prescribed to treat or prevent the depressive episodes, but they are not universally effective. Many patients still continue to experience periods of depression even while being treated, and many patients must try several different types of antidepressants before finding one that works for them. In addition, it may take several weeks of treatment before a patient begins to feel relief from the drug’s effects.

For these reasons, better treatments for depression are desperately needed. A new study in Biological Psychiatry this week confirms that scientists may have found one in a drug called ketamine.

A group of researchers at the National Institute of Mental Health, led by Dr. Carlos Zarate, previously found that a single dose of ketamine produced rapid antidepressant effects in depressed patients with bipolar disorder. They have now replicated that finding in an independent group of depressed patients, also with bipolar disorder. Replication is an important component of the scientific method, as it helps ensure that the initial finding wasn’t accidental and can be repeated.

In this new study, they administered a single dose of ketamine and a single dose of placebo to a group of patients on two different days, two weeks apart. The patients were then carefully monitored and repeatedly completed ratings to ‘score’ their depressive symptoms and suicidal thoughts.

When the patients received ketamine, their depression symptoms significantly improved within 40 minutes, and remained improved over 3 days. Overall, 79% of the patients improved with ketamine, but 0% reported improvement when they received placebo.

Importantly, and for the first time in a group of patients with bipolar depression, they also found that ketamine significantly reduced suicidal thoughts. These antisuicidal effects also occurred within one hour. Considering that bipolar disorder is one of the most lethal of all psychiatric disorders, these study findings could have a major impact on public health.

"Our finding that a single infusion of ketamine produces rapid antidepressant and antisuicidal effects within one hour and that is fairly sustained is truly exciting," Dr. Zarate commented. "We think that these findings are of true importance given that we only have a few treatments approved for acute bipolar depression, and none of them have this rapid onset of action; they usually take weeks or longer to have comparable antidepressant effects as ketamine does."

Ketamine is an N-methyl-D-aspartate (NMDA) receptor antagonist, which means that it works by blocking the actions of NMDA. Dr. Zarate added, “Importantly, confirmation that blocking the NMDA receptor complex is involved in generating rapid antidepressant and antisuicidal effects offers an avenue for developing the next generation of treatments for depression that are radically different than existing ones.”

Source: Science Daily

May 30, 2012

(Medical Xpress) — The first large non-commercial study to investigate whether the main active constituent of cannabis (tetrahydrocannabinol or THC) is effective in slowing the course of progressive multiple sclerosis (MS) shows that there is no evidence to suggest this; although benefits were noted for those at the lower end of the disability scale.

The CUPID (Cannabinoid Use in Progressive Inflammatory brain Disease) study was carried out by researchers from the Peninsula College of Medicine and Dentistry (PCMD), Plymouth University. The study was funded by the Medical Research Council (MRC) and managed by the National Institute for Health Research (NIHR) on behalf of the MRC-NIHR partnership, the Multiple Sclerosis Society and the Multiple Sclerosis Trust.

The preliminary results of CUPID were presented by lead researcher Professor John Zajicek at the Association of British Neurologists’ Annual Meeting in Brighton on Tuesday 29th May.

CUPID enrolled nearly 500 people with MS from 27 centres around the UK, and has taken eight years to complete. People with progressive MS were randomised to receive either THC capsules or identical placebo capsules for three years, and were carefully followed to see how their MS changed over this period. The two main outcomes of the trial were a disability scale administered by neurologists (the Expanded Disability Status Scale), and a patient report scale of the impact of MS on people with the condition (the Multiple Sclerosis Impact Scale 29).

Overall the study found no evidence to support an effect of THC on MS progression in either of the main outcomes. However, there was some evidence to suggest a beneficial effect in participants who were at the lower end of the disability scale at the time of enrolment but, as the benefit was only found in a small group of people rather than the whole population, further studies will be needed to assess the robustness of this finding. One of the other findings of the trial was that MS in the study population as a whole progressed slowly, more slowly than expected. This makes it more challenging to find a treatment effect when the aim of the treatment is that of slow progression.

As well as evaluating the potential neuroprotective effects and safety of THC over the long-term, one of the aims of the CUPID study was to improve the way that clinical trial research is done by exploring newer methods of measuring MS and using the latest statistical methods to make the most of every piece of information collected. This analysis will continue for several months. The CUPID study will therefore provide important information about conducting further large scale clinical trials in MS.

Professor John Zajicek, Professor of Clinical Neuroscience at PCMD, Plymouth University, said: “To put this study into context: current treatments for MS are limited, either being targeted at the immune system in the early stages of the disease or aimed at easing specific symptoms such as muscle spasms, fatigue or bladder problems. At present there is no treatment available to slow MS when it becomes progressive. Progression of MS is thought to be due to death of nerve cells, and researchers around the world are desperately searching for treatments that may be ‘neuroprotective’. Laboratory experiments have suggested that certain cannabis derivatives may be neuroprotective.”

He added: “Overall our research has not supported laboratory based findings and shown that, although there is a suggestion of benefit to those at the lower end of the disability scale when they joined CUPID, there is little evidence to suggest that THC has a long term impact on the slowing of progressive MS.”

Dr. Doug Brown, Head of Biomedical Research at the MS Society, said: “There are currently no treatments for people with progressive MS to slow or stop the worsening of disability. The MS Society is committed to supporting research in this area and this was an important study for us to fund. While this study sadly suggests THC is ineffective at slowing the course of progressive MS, we will not stop our search for effective treatments. We are encouraged by the possibility shown by this study that THC may have potential benefits for some people with MS and we welcome further investigation in this area.”

Provided by University of Plymouth

Source: medicalxpress.com

ScienceDaily (May 29, 2012) — A specific antioxidant supplement may be an effective therapy for some features of autism, according to a pilot trial from the Stanford University School of Medicine and Lucile Packard Children’s Hospital that involved 31 children with the disorder.

The antioxidant, called N-Acetylcysteine, or NAC, lowered irritability in children with autism as well as reducing the children’s repetitive behaviors. The researchers emphasized that the findings must be confirmed in a larger trial before NAC can be recommended for children with autism.

Irritability affects 60 to 70 percent of children with autism. “We’re not talking about mild things: This is throwing, kicking, hitting, the child needing to be restrained,” said Antonio Hardan, MD, the primary author of the new study. “It can affect learning, vocational activities and the child’s ability to participate in autism therapies.”

The study appears in the June 1 issue of Biological Psychiatry. Hardan is an associate professor of psychiatry and behavioral sciences at Stanford and director of the Autism and Developmental Disabilities Clinic at Packard Children’s. Stanfordis filing a patent for the use of NAC in autism, and one of the study authors has a financial stake in a company that makes and sells the NAC used in the trial.

Finding new medications to treat autism and its symptoms is a high priority for researchers. Currently, irritability, mood swings and aggression, all of which are considered associated features of autism, are treated with second-generation antipsychotics. But these drugs cause significant side effects, including weight gain, involuntary motor movements and metabolic syndrome, which increases diabetes risk. By contrast, side effects of NAC are generally mild, with gastrointestinal problems such as constipation, nausea, diarrhea and decreased appetite being the most common.

The state of drug treatments for autism’s core features, such as social deficits, language impairment and repetitive behaviors, is also a major problem. “Today, in 2012, we have no effective medication to treat repetitive behavior such as hand flapping or any other core features of autism,” Hardan said. NAC could be the first medication available to treat repetitive behavior in autism — if the findings hold up when scrutinized further.

The study tested children with autism ages 3 to 12. They were physically healthy and were not planning any changes in their established autism treatments during the trial. In a double-blind study design, children received NAC or a placebo for 12 weeks. The NAC used was a pharmaceutical-grade preparation donated by the drug manufacturer Bioadvantex Inc. Subjects were evaluated before the trial began and every four weeks during the study using several standardized surveys that measure problem behaviors, social behaviors, autistic preoccupations and drug side effects.

During the 12-week trial, NAC treatment decreased irritability scores from 13.1 to 7.2 on the Aberrant Behavior Checklist, a widely used clinical scale for assessing irritability. The change is not as large as that seen in children taking antipsychotics. “But this is still a potentially valuable tool to have before jumping on these big guns,” Hardan said.

In addition, according to two standardized measures of autism mannerisms and stereotypic behavior, children taking NAC showed a decrease in repetitive and stereotyped behaviors.

"One of the reasons I wanted to do this trial was that NAC is being used by community practitioners who focus on alternative, non-traditional therapies," Hardan said. "But there is no strong scientific evidence to support these interventions. Somebody needs to look at them."

Hardan cautioned that the NAC for sale as a dietary supplement at drugstores and grocery stores differs in some important respects from the individually packaged doses of pharmaceutical-grade NAC used in the study, and that the over-the-counter version may not produce the same results. “When you open the bottle from the drugstore and expose the pills to air and sunlight, it gets oxidized and becomes less effective,” he said.

Although the study did not test how NAC works, the researchers speculated on two possible mechanisms of action. NAC increases the capacity of the body’s main antioxidant network, which some previous studies have suggested is deficient in autism. In addition, other research has suggested that autism is related to an imbalance in excitatory and inhibitory neurotransmitters in the brain. NAC can modulate the glutamatergic family of excitatory neurotransmitters, which might be useful in autism.

The scientists are now applying for funding to conduct a large, multicenter trial in which they hope to replicate their findings.

"This was a pilot study," Hardan said. "Final conclusions cannot be made before we do a larger trial."

Source: Science Daily

ScienceDaily (May 29, 2012) — TAU research finds that existing diabetes medication may ease damage caused by brain-addling explosions.

Although the death toll is relatively low for people who suffer from traumatic brain injury (TBI), it can have severe, life-long consequences for brain function. TBI can impair a patient’s mental abilities, impact memory and behavior, and lead to dramatic personality changes. And long-term medical treatment carries a high economic cost.

Now, in research commissioned by the United States Air Force, Prof. Chaim Pick of Tel Aviv University’s Sackler Faculty of Medicine and Dr. Nigel Greig of the National Institute of Aging in the US have discovered that Exendin-4, an FDA-approved diabetes drug, significantly minimizes damage in TBI animal models when administered shortly after the initial incident. Originally designed to control sugar levels in the body, the drug has recently been found effective in protecting neurons in disorders such as Alzheimer’s disease.

Prof. Pick’s collaborators include his TAU colleagues Dr. Vardit Rubovitch, Lital Rachmany-Raber, and Prof. Shaul Schreiber, and Dr. David Tweedie of the National Institute of Aging in the US. Detailed in the journal Experimental Neurology, this breakthrough is the first step towards developing a cocktail of medications to prevent as much brain damage as possible following injury.

Diabetes medication to halt trauma

Prof. Pick has been researching TBI for many years, beginning with the effects of everyday injuries such as hitting the windshield in a car accident. As a result of his work for the Air Force, he has expanded his research to include trauma sustained when a person is exposed to an explosion, such as during a terrorist attack.

TBI causes long-term damage by changing the chemistry of the brain. During an explosion, increased pressure followed by an intense vacuum shakes the fluid inside the brain and damages the brain’s structure. This damage cannot be reversed, but mapping the injury through behavioral and physical tests is crucial to understanding and quantifying the damage and forming a treatment plan through therapy or medication.

Prof. Pick and his colleagues designed a pre-clinical experiment that exposed mice to controlled explosions from 23 and 33 feet away, and then analyzed the resulting injuries. They also studied the effect of Exendin-4 as an additional parameter in minimizing brain damage.

The researchers divided their mice into four groups: a control group; a second group that was exposed to the blast without medication; a third group that received the medication but was not exposed to the blast; and a fourth group, exposed to the explosion but given the medication within an hour after the blast and continuing for seven days afterwards. The mice were placed under anesthesia before the explosion.

Behavioral and physical tests showed that the mice that had been exposed to the blast had severely impaired brain function compared to the control group. However, the mice that had also received the Exendin-4 treatment were almost on a par with the control group in terms of brain function, proving that Exendin-4 significantly reduced the long-term damage done by an explosion. In separate experiments, the drug was also associated with an improved outcome in mice who sustained TBI by blunt force.

Finding the ideal drug cocktail

Prof. Pick says this promising discovery can help researchers find the ideal combination of medications to minimize the lasting impact of TBI. “We are moving in the right direction. Now we need to find the right dosage and delivery system, then build a cocktail of drugs that will increase the therapeutic value of this concept,” he explains. He adds that in treating such traumatic injuries, one drug is unlikely to be sufficient.

Source: Science Daily

ScienceDaily (May 29, 2012) — New research from the University of Warwick could explain why the evil eyebrows and pointy chin of a cartoon villain make our ‘threat’ instinct kick in.

Triangular-shaped face. Psychologists have found that a downward pointing triangle can be perceived to carry a threat. (Credit: © Viktor Kuryan / Fotolia)

Psychologists have found that a downward pointing triangle can be perceived to carry threat just like a negative face in a crowd.

In a paper published in Emotion, a journal of the American Psychological Association, Dr Derrick Watson and Dr Elisabeth Blagrove have carried out a series of experiments with volunteers to find out if simple geometric shapes can convey positive or negative emotions.

Previous research by these scientists showed that people could pick out a negative face in a crowd more quickly than a positive or neutral face and also that it was difficult to ignore faces in general. The researchers carried out a series of experiments asking volunteers to respond to computer-generated images. They were shown positive, negative and neutral faces, and triangles facing upwards, downwards, inward and outward. This latest study shows that downward triangles are detected just as quickly as a negative face.

Dr Watson said: “We know from previous studies that simple geometric shapes are effective at capturing or guiding attention, particularly if these shapes carry the features present within negative or positive faces.”

"Our study shows that downward pointing triangles in particular convey negative emotions and we can pick up on them quickly and perceive them as a threat."

Dr Blagrove added: “If we look at cartoon characters, the classic baddie will often be drawn with the evil eyebrows that come to a downward point in the middle. This could go some way to explain why we associate the downward pointing triangle with negative faces. These shapes correspond with our own facial features and we are unconsciously making that link.”

Source: Science Daily

May 29, 2012

Researchers from South Korea, Sweden, and the United States have collaborated on a project to restore neuron function to parts of the brain damaged by Huntington’s disease (HD) by successfully transplanting HD-induced pluripotent stem cells into animal models.

Induced pluripotent stem cells (iPSCs) can be genetically engineered from human somatic cells such as skin, and can be used to model numerous human diseases. They may also serve as sources of transplantable cells that can be used in novel cell therapies. In the latter case, the patient provides a sample of his or her own skin to the laboratory.

In the current study, experimental animals with damage to a deep brain structure called the striatum (an experimental model of HD) exhibited significant behavioral recovery after receiving transplanted iPS cells. The researchers hope that this approach eventually could be tested in patients for the treatment of HD.

"The unique features of the iPSC approach means that the transplanted cells will be genetically identical to the patient and therefore no medications that dampen the immune system to prevent graft rejection will be needed,” said Jihwan Song, D.Phil. Associate Professor and Director of Laboratory of Developmental & Stem Cell Biology at CHA Stem Cell Institute, CHA University, Seoul, South Korea and co-author of the study.

The study, published online this week in Stem Cells, found that transplanted iPSCs initially formed neurons producing GABA, the chief inhibitory neurotransmitter in the mammalian central nervous system, which plays a critical role in regulating neuronal excitability and acts at inhibitory synapses in the brain. GABAergic neurons, located in the striatum, are the cell type most susceptible to degeneration in HD.

Another key point in the study involves the new disease models for HD presented by this method, allowing researchers to study the underlying disease process in detail. Being able to control disease development from such an early stage, using iPS cells, may provide important clues about the very start of disease development in HD. An animal model that closely imitates the real conditions of HD also opens up new and improved opportunities for drug screening.

"Having created a model that mimics HD progression from the initial stages of the disease provides us with a unique experimental platform to study Huntington’s disease pathology" said Patrik Brundin, M.D., Ph.D., Director of the Center for Neurodegenerative Science at Van Andel Research Institute (VARI), Head of the Neuronal Survival Unit at Lund University, Sweden, and co-author of the study.

Huntington’s disease (HD) is a neurodegenerative genetic disorder that affects muscle coordination and leads to cognitive decline and psychiatric problems. It typically becomes noticeable in mid-adult life, with symptoms beginning between 35 and 44 years of age. Life expectancy following onset of visual symptoms is about 20 years. The worldwide prevalence of HD is 5-10 cases per 100,000 persons. Key to the disease process is the formation of specific protein aggregates (essentially abnormal clumps) inside some neurons.

Provided by Van Andel Research Institute

Source: medicalxpress.com

May 29, 2012

What do physicists, chemists, mathematicians and biologists have in common? One of the answers at Cambridge is a shared interest in unravelling the processes behind neurodegenerative diseases such as Alzheimer’s, Parkinson’s and Motor Neurone Disease.

Dementia. Credit: ©freshidea Fotolia

As more people live to a ripe old age, an increasing number of us will develop neurodegenerative diseases such as Alzheimer’s. Despite the escalating economic costs and human misery associated with these diseases, we still know relatively little about how they develop or how best to tackle them.

Alzheimer’s is the most common neurodegenerative disease. “It’s an enormous problem and we’re not doing very well at the moment in slowing the disease or treating its symptoms effectively,” says Professor Peter St George-Hyslop.

Neurodegenerative diseases such as Alzheimer’s are difficult to study for several reasons. “One is that it’s not easy to get pieces of living brain,” he explains. “It’s also a disease where patients become unable to speak for themselves, so unlike people with AIDS or breast cancer they aren’t demonstrating outside the houses of Parliament demanding funding.”

Although charities and campaigners are doing sterling work raising the profile of Alzheimer’s, until recently attitudes to neurodegenerative disease had much in common with the way we viewed cancer 50 years ago.

“We are, for Alzheimer’s, like where we were for cancer in the 1950s, when people didn’t like to talk about it, were frightened or ashamed of it. And therapeutically we are in the same place; although we are beginning to learn about these diseases we don’t yet have much in the way of effective therapies,” Professor St George-Hyslop says.

One crucial discovery is that proteins misfolding in the brain form clumps or aggregates and these play a major role in causing neurodegenerative diseases. When these proteins misfold they take on certain characteristics that become noxious to cells, but what we need to know now is why these proteins misfold, which aggregates do the damage, and how that damage occurs. Which is where physics, chemistry and mathematics enter the biological picture.

Professor St George-Hyslop leads a group of experts from disparate disciplines, each bringing different tools and different ways of working to the study of neurodegenerative diseases.

What began in late 2008 as a series of meetings has now developed into a 12-strong group funded by a £5.3 million Strategic Award from the Wellcome Trust and Medical Research Council. “It’s a very interesting group of people who came together because they wanted to come together. They each knew they had something to contribute but also that they needed something else – some skills, some knowledge, some point of view – from another member of the group,” he says.

“The biologists among us knew there were techniques that the physicists and chemists had that could help us. They in turn knew we had some biological knowledge that would help them apply, in a sensible way, their very good and insightful physical and chemical tools.”

Among the group is Professor David Klenerman from the Department of Chemistry. One of the inventors of rapid, high-throughput DNA sequencing, he is now applying this knowledge to protein misfolding. From the same department comes Professor Michele Vendruscolo, a theoretical physicist working on the mechanics and thermodynamics of protein misfolding. Professor Chris Dobson, who is also from the Department of Chemistry works on protein misfolding in neurodegenerative diseases, while from the Department of Chemical Engineering and Biotechnology Dr. Clemens Kaminski brings modern laser spectroscopy tools that allow you to watch these proteins misfold inside living cells in real time.

The group has applied these physical tools to study nematode worms in which a mutation produces the same protein misfolding that causes disease in humans. “That ability to see these things as they happen in a living model give us a much greater understanding compared with previous techniques, which essentially involved grinding up biological samples and examining them after these processes had occurred,” Professor St George-Hyslop explains.

“What’s important is the marriage of the physical tool with the biological question,” he says. And he hopes that by revealing where these misfolded proteins act, these new tools could help researchers develop ways of blocking the damage they cause in both Alzheimer’s and other neurodegenerative diseases.

“The primary goal is to understand what the beginning and the middle parts of the process are. We know what the end is – the cell dies and you get a disease – but if you know why the cells get sick and what the mechanisms are then you have a better chance of preventing or halting it,” says Professor St George- Hyslop. “Our goal is to provide that fundamental knowledge of cause and mechanism. Hopefully from that will come some idea of which parts of those pathways you can monitor as a diagnostic and which parts you can block or change as a treatment.”

More recently, the group has been enlarged by a £4.5 million grant from the National Institute of Health Research to support an extension of the Cambridge Biomedical Research Centre via the creation of a Biomedical Research Unit in Dementia for translational research. This has allowed the inclusion of researchers in immunology and in brain imaging from the Department of Medicine and the Wolfson Brain Imaging Centre.

Provided by University of Cambridge

Source: medicalxpress.com

ScienceDaily (May 28, 2012) — A team of researchers from Maastricht, Leuven, Bristol and Cambridge demonstrated the effectiveness of a new tinnitus treatment approach in the journal The Lancet. Tinnitus is the perception of a noxious disabling internal sound without an external source. Roughly fifteen percent of the population suffers from this disorder in varying degrees along with the associated concentration problems, sleep disturbances, anxiety, depression and extreme fatigue.

Tinnitus is the perception of a noxious disabling internal sound without an external source. (Credit: © BildPix.de / Fotolia)

Sometimes this disorder is so disruptive it seriously impairs their daily functioning and, unfortunately, there is no cure.

The research conducted by Rilana Cima and her colleagues, however, indicates that cognitive behavioural therapy can help improve the daily functioning of tinnitus patients.

The study, conducted at Adelante Audiology & Communication, followed 492 adult tinnitus patients for a period of twelve months. The effectiveness of an innovative tinnitus treatment protocol was compared to the standard treatment methods offered throughout the Netherlands. The ground-breaking, stepped treatment plan consists of cognitive behavioural therapy and combines elements from psychology and audiology. The therapy aims at reducing the negative thoughts and feelings surrounding tinnitus, symptoms through exposure techniques, movement and relaxation exercises, and mindfulness-based elements.

This is supplemented with elements from the so-called tinnitus retraining therapy (TRT), which examines the problems on a sound perception level. The treatment is offered by a multidisciplinary team of audiologists, psychologists, speech and movement therapists, physical therapists and social workers. The project was funded by the Netherlands Organisation for Health Research and Development (ZonMW), and directed by Johan Vlaeyen, professor behavioural medicine at KU Leuven and Maastricht University.

The results offer compelling evidence to support the effectiveness of this innovative and specialised tinnitus therapy over more traditional forms of treatment. The overall health of the tinnitus patient improves and the severity of their symptoms and perceived impairment decreases after therapy. Moreover, the new treatment is far more effective in reducing negative mood, dysfunctional beliefs and tinnitus-related fear). The specialised tinnitus treatment is effective for both milder and more severe forms of the disorder. The researchers are therefore advocating a widespread implementation of this new treatment protocol.

Source: Science Daily

May 29, 2012

Human brain functions have been studied in the past using relatively simple stimuli, such as pictures of faces and isolated sounds or words. Researchers from Aalto University Department of Biomedical Engineering and Computational Science have now taken a highly different approach: they have studied brain functions in lifelike circumstances.

In their new study, published in PLoS ONE, the group examined how the brain processes the film The Match Factory Girl by Aki Kaurismäki.

Films have been previously used to study brain activity, but the brain activity patterns have been integrated over the whole duration of the film, and thus time information is lost. This is like compressing a whole film into just one frame. In some studies, scientists have looked at dynamic brain activity, but focusing on a single brain region at a time.

The Aalto University scientists on the other hand study the full brain activity patterns with the time resolution allowed by functional magnetic resonance imaging. This way it possible to find out which events in the film cause changes in the brain activity, and which brain areas are activated at each moment.

This analysis revealed, for example, that parts of a brain network that usually respond to speech also become activated during other types of communication, such as writing. Some other areas of the network were very selective to speech.

The researchers combined two complementary approaches to disclose the brain activity. One based on dependencies of activation in different parts of the brain, and the other begins from detailed analysis of the visual and acoustic features of which the film is composed.

The results revealed brain networks in which activity follows remarkably well the complex model of the auditory and visual features of the film. For example, brain activity in the auditory cortex followed the soundtrack extremely well over the whole length of the film, and viewing the motions of characters’ hands reliably activated widespread areas of the brain.

"Our study opens new ways for studying human brain functions. Many brain areas that process sensory information reveal their principles only if sufficiently complex and naturalistic stimuli are used,” explain researcher Juha Lahnakoski and Professor Mikko Sams from Aalto University Department of Biomedical Engineering and Computational Science.

The new methods also make it possible to study brain mechanisms’ underlying behaviour in normal everyday conditions – by simulating them in films.

Provided by Aalto University

Source: medicalxpress.com

ScienceDaily (May 28, 2012) — Do you smile when you’re frustrated? Most people think they don’t — but they actually do, a new study from MIT has found. What’s more, it turns out that computers programmed with the latest information from this research do a better job of differentiating smiles of delight and frustration than human observers do.

Can you tell which of these smiles is showing happiness? Or which one is the result of frustration? A computer system developed at MIT can. The answer: The smile on the right is the sign of frustration. (Credit: Images courtesy of Hoque et al.)

The research could pave the way for computers that better assess the emotional states of their users and respond accordingly. It could also help train those who have difficulty interpreting expressions, such as people with autism, to more accurately gauge the expressions they see.

"The goal is to help people with face-to-face communication," says Ehsan Hoque, a graduate student in the Affective Computing Group of MIT’s Media Lab who is lead author of a paper just published in the IEEE Transactions on Affective Computing. Hoque’s co-authors are Rosalind Picard, a professor of media arts and sciences, and Media Lab graduate student Daniel McDuff.

In experiments conducted at the Media Lab, people were first asked to act out expressions of delight or frustration, as webcams recorded their expressions. Then, they were either asked to fill out an online form designed to cause frustration or invited to watch a video designed to elicit a delighted response — also while being recorded.

When asked to feign frustration, Hoque says, 90 percent of subjects did not smile. But when presented with a task that caused genuine frustration — filling out a detailed online form, only to then find the information deleted after pressing the “submit” button — 90 percent of them did smile, he says. Still images showed little difference between these frustrated smiles and the delighted smiles elicited by a video of a cute baby, but video analysis showed that the progression of the two kinds of smiles was quite different: Often, the happy smiles built up gradually, while frustrated smiles appeared quickly but faded fast.

In such experiments, researchers usually rely on acted expressions of emotion, Hoque says, which may provide misleading results. “The acted data was much easier to classify accurately” than the real responses, he says. But when trying to interpret images of real responses, people performed no better than chance, assessing these correctly only about 50 percent of the time.

Understanding the subtleties that reveal underlying emotions is a major goal of this research, Hoque says. “People with autism are taught that a smile means someone is happy,” he says, but research shows that it’s not that simple.

While people may not know exactly what cues they are responding to, timing does have a lot to do with how people interpret expressions, he says, For example, former British prime minister Gordon Brown was widely seen as having a phony smile, largely because of the unnatural timing of his grin, Hoque says. Similarly, a campaign commercial for former presidential candidate Herman Cain featured a smile that developed so slowly — it took nine seconds to appear — that it was widely parodied, including a spoof by comedian Stephen Colbert. “Getting the timing right is very crucial if you want to be perceived as sincere and genuine with your smiles,” Hoque says.

Jeffrey Cohn, a professor of psychology at the University of Pittsburgh who was not involved in this research, says this work “breaks new ground with its focus on frustration, a fundamental human experience. While pain researchers have identified smiling in the context of expressions of pain, the MIT group may be the first to implicate smiles in expressions of negative emotion.”

Cohn adds, “This is very exciting work in computational behavioral science that integrates psychology, computer vision, speech processing and machine learning to generate new knowledge … with clinical implications.” He says this “is an important reminder that not all smiles are positive. There has been a tendency to ‘read’ enjoyment whenever smiles are found. For human-computer interaction, among other fields and applications, a more nuanced view is needed.”

In addition to providing training for people who have difficulty with expressions, the findings may be of interest to marketers, Hoque says. “Just because a customer is smiling, that doesn’t necessarily mean they’re satisfied,” he says. And knowing the difference could be important in gauging how best to respond to the customer, he says: “The underlying meaning behind the smile is crucial.”

The analysis could also be useful in creating computers that respond in ways appropriate to the moods of their users. One goal of the research of Affective Computing Group is to “make a computer that’s more intelligent and respectful,” Hoque says.

Source: Science Daily