quinta-feira, 11 de setembro de 2014

A Super-Strong and Lightweight New Material

 

Nanostructured ceramics could be used to build lighter, stronger airplanes and batteries.

Why It Matters

The energy efficiency of aircraft, cars, and batteries depends heavily on the weight of the materials used to make them.

Tiny trusses: A scanning electron microscope image of the new material reveals its ceramic nano-lattices.

A new type of material, made up of nanoscale struts crisscrossed like the struts of a tiny Eiffel Tower, is one of the strongest and lightest substances ever made.

If researchers can figure out how to make the stuff in large quantities, it could be used as a structural material for making planes and trucks, as well as in battery electrodes.

Researchers led by Caltech materials scientist Julia Greer found that by carefully designing nanoscale struts and joints, they could make ceramics, metals, and other materials that can recover after being crushed, like a sponge. The materials are very strong and light enough to float through the air like a feather. The work is published today in the journal Science.

In conventional materials, strength, weight, and density are correlated. Ceramics, for example, are strong but also heavy, so they can’t be used as structural materials where weight is critical—for example, in the bodies of cars. And when ceramics fail, they tend to fail catastrophically, shattering like glass.

But at the nanoscale the same rules do not apply. In this size range, the structural and mechanical properties of ceramics become less tied to properties such as weight, and they can be altered more precisely.

“For ceramics, smaller is tougher,” says Greer, who was named one of MIT Technology Review’s 35 Innovators Under 35 in 2008 for her work on nanoscale mechanics. This means that nanoscale trusses made from ceramic materials can be both very light—unsurprising, since they are mostly air—and extremely strong.

In 2011, working with researchers at HRL Laboratories, a private engineering research company, Greer created one of the lightest materials ever made, a microlattice of hollow metal tubes. She later chose to take on the greater challenge of making ceramics with similar properties. This required fine-tuning structures at the nanoscale, meaning the materials are even more difficult to produce.

To make the ceramic nano-trusses, Greer’s lab uses a technique called two-photon interference lithography. It’s akin to a very low-yield 3-D laser printer.

First they use this method to create the desired structure, a lattice, out of a polymer. The polymer lattice is then coated with a ceramic such as alumina. Oxygen plasma etches out the polymer, leaving behind a lattice of hollow ceramic tubes.

Greer’s lab showed that by changing the thickness of the tube walls, it’s possible to control how the material fails. When the walls are thick, the ceramic shatters under pressure as expected. But trusses with thinner walls, just 10 nanometers thick, buckle when compressed and then recover their shape.

“You don’t expect these materials to recover—you expect them to be brittle and to fracture,” says Christopher Spadaccini, an engineer who specializes in materials manufacturing at the U.S. Department of Energy’s Lawrence Livermore National Laboratory in California.

The new materials might be particularly interesting for use in batteries, notes Nicholas Fang, a mechanical engineer at MIT who is also working on nanostructured ceramics. Nanostructures have a very high surface area and are lightweight, a combination that could make for a fast-charging battery that stores a lot of energy in a convenient package. In fact, Greer says she is collaborating with German electronics company Bosch to apply her designs to lithium-ion batteries.

Snap 2014-09-11 at 20.03.19

Impact of violent media on the brain: Depends on each individual's brain circuitry, study finds

 


With the longstanding debate over whether violent movies cause real world violence as a backstop, a study published in PLOS One found that each person's reaction to violent images depends on that individual's brain circuitry, and on how aggressive they were to begin with.

The study, which was led by researchers at the Icahn School of Medicine at Mount Sinai and the NIH Intramural Program, featured brain scans which revealed that both watching and not watching violent images caused different brain activity in people with different aggression levels. The findings may have implications for intervention programs that seek to reduce aggressive behavior starting in childhood.

"Our aim was to investigate what is going on in the brains of people when they watch violent movies," said lead investigator Nelly Alia-Klein, PhD, Associate Professor of Neuroscience and Psychiatry at the Friedman Brain Institute and Icahn School of Medicine at Mount Sinai. "We hypothesized that if people have aggressive traits to begin with, they will process violent media in a very different way as compared to non-aggressive people, a theory supported by these findings."

After answering a questionnaire, a group of 54 men were split by the research team into two groups -- one with individuals possessing aggressive traits, including a history of physical assault, and a second group without these tendencies. The participants' brains were then scanned as they watched a succession of violent scenes (shootings and street fights) on day one, emotional, but non-violent scenes (people interacting during a natural disaster) on day two, and nothing on day three.

The scans measured the subjects' brain metabolic activity, a marker of brain function. Participants also had their blood pressure taken every 5 minutes, and were asked how they were feeling at 15 minute intervals.

Investigators discovered that during mind wandering, when no movies were presented, the participants with aggressive traits had unusually high brain activity in a network of regions that are known to be active when not doing anything in particular. This suggests that participants with aggressive traits have a different brain function map than non-aggressive participants, researchers said.

Interestingly, while watching scenes from violent movies, the aggressive group had less brain activity than the non-aggressive group in the orbitofrontal cortex, a brain region associated by past studies with emotion-related decision making and self-control. The aggressive subjects described feeling more inspired and determined and less upset or nervous than non-aggressive participants when watching violent (day 1) versus just emotional (day 2) media. In line with these responses, while watching the violent media, aggressive participants' blood pressure went down progressively with time while the non-aggressive participants experienced a rise in blood pressure.

"How an individual responds to their environment depends on the brain of the beholder," said Dr. Alia-Klein. "Aggression is a trait that develops together with the nervous system over time starting from childhood; patterns of behavior become solidified and the nervous system prepares to continue the behavior patterns into adulthood when they become increasingly coached in personality. This could be at the root of the differences in people who are aggressive and not aggressive, and how media motivates them to do certain things. Hopefully these results will give educators an opportunity to identify children with aggressive traits and teach them to be more aware of how aggressive material activates them specifically."


Story Source:

The above story is based on materials provided by Mount Sinai Medical Center. Note: Materials may be edited for content and length.


Journal Reference:

  1. Nelly Alia-Klein, Gene-Jack Wang, Rebecca N. Preston-Campbell, Scott J. Moeller, Muhammad A. Parvaz, Wei Zhu, Millard C. Jayne, Chris Wong, Dardo Tomasi, Rita Z. Goldstein, Joanna S. Fowler, Nora D. Volkow. Reactions to Media Violence: It’s in the Brain of the Beholder. PLoS ONE, 2014; 9 (9): e107260 DOI: 10.1371/journal.pone.0107260

U.S. cityscapes show consistent patterns of 'urban evolution'

 


Most people think of city landscapes as simpler, diminished versions of the wild forests and free-flowing streams found in remote places. But in a series of studies published Sept. 10, 2014 in a special issue of the journal Biogeochemistry, scientists specializing in urban ecosystems say just the opposite is true. Urban landscapes are more complex than they seem, and from coast to coast these ecosystems can work in surprisingly similar ways, regardless of local conditions. And they have the potential to change quickly -- for better or worse -- depending on how people manage them.

In 14 studies, scientists from across the U.S. examined the impacts of human actions on the geology, chemistry and biology of urban ecosystems. The studies were carried out in a broad range of climates from Boston and Baltimore to San Juan, Puerto Rico;Tucson, Arizona; and Southern California, including sites in the National Science Foundation's Long Term Ecological Research (LTER) network. Results were published in a special issue of Biogeochemistry exclusively devoted to urban ecosystems, edited by University of Maryland geologist Sujay Kaushal and University of New Hampshire ecologists William McDowell and Wilfred Wollheim.

"Urban ecosystems change relatively quickly in response to human activities," says Kaushal. "These changes can result in rapid losses of ecosystem functions, like flood protection and pollution filtration, or they can result in progress toward ecological health and productivity. The difference depends in large part on how they are managed."

In an overview article, Kaushal, McDowell and Wollheim point out some key factors that affect the evolution of urban ecosystems. For example, the streams, lakes and land surfaces that make up cities' watersheds show consistent patterns of change over time:

  • They are becoming saltier, partly due to road salt used for de-icing, and partly because the salt that people eat ends up in urban streams. Excess salt in the human diet is excreted in human waste, and captured by sewer systems. Crumbling sewage pipes leak this chloride-laden waste into groundwater, where it eventually mingles with surface water, say the authors of the overview paper. The researchers propose that one way to track the spread of urbanization is by looking at the chloride content of cities' freshwater rivers and streams.
  • They carry the chemical signature of dissolving concrete, a major building material in urban areas since the mid-20th century. Most concrete contains cement made of powdered limestone, which weathers easily when exposed to acid rain or chemicals. The authors say many cities now have their own human-made geology: concrete surfaces that mimic a type of limestone called karst. This "urban karst" is constantly breaking down into its constituent elements, including calcium and carbonate minerals, which flow into urban streams and affect their pH content, and therefore their ability to sustain aquatic life.
  • Urban ecosystems develop "hot spots," like road crossings where automobile exhaust, litter, de-icing salt and other human-made substances can sharply alter downstream water quality. They also experience "hot moments," such as heavy rainstorms that wash large pulses of organic matter and manufactured chemicals into streams, or cause sewage overflows. These hot moments can suddenly change water chemistry in ways that shock natural systems.
  • The networks that supply cities with water evolve and expand over time, including not just surface waters, but also storm drains, leaking water and sewer pipes, roofs and gutters, groundwater, and waste water that humans bring into the area from other watersheds. The boundaries between nearby cities' watersheds are blurring, making it hard to define, study and manage them.

"There is a lot of good urban restoration work underway," says McDowell, "but often it only has a short-term effect, because urban watersheds follow their own evolutionary paths. For example, utility managers may build a stormwater retention pond to capture polluted runoff, such as excess nitrogen from urban runoff. And it may work very well for a few years. But then it fills in with sediment, and becomes a wetland, and it's no longer working the way the engineers designed it to work."

"We hope scientists, managers and citizens will work together to make decisions that allow for what we call 'urban evolution,' -- that is, changes in the ecology of cities over time, " says Kaushal. "If we do that, we can find effective ways to understand and manage the trajectory of urban ecosystems, from decline towards sustainability."

"This synthesis brings the power of evolutionary biology to understanding ecosystem processes in urban environments, some of the most rapidly changing habitats globally," says Saran Twombly, NSF's LTER program director. "Merging evolutionary biology with ecosystem sciences is an exciting frontier for long-term ecological research, beginning with this issue on biogeochemical cycles."


Story Source:

The above story is based on materials provided by University of Maryland. Note: Materials may be edited for content and length.


Journal Reference:

  1. Sujay S. Kaushal, William H. McDowell, Wilfred M. Wollheim. Tracking evolution of urban biogeochemical cycles: past, present, and future. Biogeochemistry, 2014; 121 (1): 1 DOI: 10.1007/s10533-014-0014-y

A Mexican plant could lend the perfume industry more green credibility

 


The mere whiff of a dreamy perfume can help conjure new feelings or stir a longing for the past. But the creation of these alluring scents, from the high-end to the commonplace, can also incur an environmental toll. That could change as scientists, reporting in the journal ACS Sustainable Chemistry & Engineering, examine a more sustainable way to produce a key perfume ingredient and supply it to fragrance makers around the world.

José M. Ponce-Ortega and colleagues explain that out of the three main ingredients in perfumes, the fixatives, which allow a scent to linger on a wearer's skin rather than quickly dissipate, are often pricey. A particularly coveted fixative comes from a rare whale digestive excretion called ambergris. Not only is its cost exorbitant, but its use is in perfumes in the U.S. and other countries is illegal. That's why many perfumeries long ago turned to a synthetic version. Although not as costly, the substitute still commands a high price, and requires considerable time and energy to make.

A simpler way to make synthetic ambergris exists, but the catch is that the starting material is a flowering plant found in Mexico. That means the plant would have to take a fuel-consuming, environmentally unfriendly journey across the ocean to Europe, where many perfumes are made. So Ponce-Ortega's team wanted to see whether the process would be worth it.

To find out, the researchers conducted a supply-chain analysis. They found that producing the fixative using the Mexican plant would generate considerable local profits to the tune of $20 million per year and create hundreds of jobs along the supply routes. They did find an environmental cost to the process, but that could be mitigated by using renewable energy sources to produce the fixative.


Story Source:

The above story is based on materials provided by American Chemical Society. Note: Materials may be edited for content and length.


Journal Reference:

  1. Sergio Ivan Martinez-Guido, Janett Betzabe Gonzalez-Campos, Rosa Elva Del Rio, José María Ponce-Ortega, Fabricio Napoles-Rivera, Medardo Serna-González, Mahmoud M El-Halwagi. A Multiobjective Optimization Approach for the Development of a Sustainable Supply Chain of a New Fixative in the Perfume Industry. ACS Sustainable Chemistry & Engineering, 2014; 140902082410008 DOI: 10.1021/sc500409g

Apple Watch is the long-rumored iWatch

 

 

The Apple Watch comes with a number of ways to personalize

The Apple Watch comes with a number of ways to personalize

Image Gallery (23 images)

It's official. Apple is making a smartwatch called simply "Apple Watch," but you're going to have to wait for the opportunity to pay at least $349 for one until early next year. If the Apple Watch works as well as the company claimed during its lengthy unveiling on Tuesday, it just may be worth the wait.

Like the existing watches that run Android Wear or the Pebble or Samsung's Tizen-powered watches, the Apple Watch starts with the basic capability of being able to check your phone's notifications and the time, but then it adds functionality that goes far beyond what's been done before.

Multiple infrared and visible light LEDs on the back of the watch work to detect a pulse rate, which then interact with Apple's own health and workout apps to create what Tim Cook calls a "comprehensive health and fitness device." Case in point is the new health app that tracks steps, heart rate and active calories, just for starters.

The other big smart watch innovation on the Apple Watch is actually quite small. In fact, it's the little rotating button on the side of the watch that also functions as a control that Apple calls the "digital crown." Turning the digital crown allows you to zoom in on photos or to scroll through selections like the scroll wheel in the center of a mouse. It's a novel but simple addition typical of Apple that now seems an obvious choice after seeing it in action.

Four rear sensors measure heart rate

The Apple Watch also gets that scratch-proof sapphire touch screen we've been hearing about for so long now. It will also be able to tell the difference between a quick tap and holding your finger down on the screen, which Apple calls a "force touch" and provides another means of controlling apps on the device.

"We’ve developed multiple technologies and an entirely new user interface specifically for a device that’s designed to be worn. It blurs the boundary between physical object and user interface,” said Jony Ive, Apple’s senior vice president of Design.

Apple also introduced something called "Glimpses" for the watch that are essentially the same as the cards that Android Wear users are familiar with that show useful information like location, weather and upcoming appointments. Siri is also accessible and the Apple Watch allows you to respond to texts via dictation.

The digital crown is a new smart watch interface

The latest text analysis in iOS also attempts to extract likely responses to incoming messages and then allows you to simply respond by choosing from a few pre-determined response options, something not available on Android Wear.

The Apple Watch goes way beyond what any early smartwatch can do by integrating Apple's new payment system, Apple Pay, basically allowing the watch to stand in for a wallet or credit card at hundreds of thousands of locations in the United States. Apple has also clearly done more legwork with developers to ensure that a useful array of apps will make use of the Apple Watch. It announced WatchKit, a package of tools and APIs for developers during the event.

The company has already announced that Starwood Hotels will allow guests to use their Apple Watch as a room key, and apps for Pinterest, Nike and many others are already in the works. One of the strangest features Apple touted is the ability of the watch to measure your heart rate and then share it with another watch wearer who can then feel that heartbeat as simulated by the Apple Watch's "Taptic Engine."

The workout app for the Apple Watch

Taptic feedback is basically just a word Apple has chosen to describe the watch's use of haptic feedback. Apple claims that its system is more advanced than just basic vibrations of your wrist, and that different types of taptic feedback can actually tell you which way to turn while navigating, simply by the type of buzz the watch gives your wrist. The Taptic Engine also works in tandem with a tiny speaker to provide an even broader selection of possible alerts.

The heart of the Apple Watch is what the company has dubbed the S1 SiP (System in Package) that sounds a lot like a miniaturized version of a system-on-a-chip. Also inside are magnets to work with the wireless inductive charging system, Wi-Fi and Bluetooth 4.0 radios to connect to your iPhone.

And yes, the Apple Watch does require an iPhone, but any iPhone 5 and up will work, including the 5, 5S, 5C, and the new iPhone 6 or 6 Plus.

The watch's health app integrates with an iPhone

Staying with the theme of choice and being "truly personal," which was Tim Cook's mantra for the day, there will be two sizes and three different styles of Apple Watch. There's your basic Apple Watch with a choice of straps, Apple Watch Sport with a stronger silver anodized aluminum case and sport band, or Apple Watch Edition that introduces an 18-karat gold case and premium straps to the equation.

The Apple Watch will start at US$349. Now for the bad news: It won't be available until "early 2015."

So much for the perfect holiday gift. Stay tuned to Gizmag for news on the Apple Watch as it comes in.

Snap 2014-09-11 at 19.35.16

Air pollution harmful to young brains, study finds

 


Aerial view of Mexico City.

Findings by University of Montana Professor Dr. Lilian Calderón-Garcidueñas, MA, MD, Ph.D., and her team of researchers reveal that children living in megacities are at increased risk for brain inflammation and neurodegenerative changes, including Alzheimer's or Parkinson's disease.

Calderón-Garcidueñas' findings are detailed in a paper in the Journal of Alzheimer's Disease.

The study found when air particulate matter and their components such as metals are inhaled or swallowed, they pass through damaged barriers, including respiratory, gastrointestinal and the blood-brain barriers and can result in long-lasting harmful effects.

Calderón-Garcidueñas and her team compared 58 serum and cerebrospinal fluid samples from a control group living in a low-pollution city and matched them by age, gender, socioeconomic status, education and education levels achieved by their parents to 81 children living in Mexico City.

The results found that the children living in Mexico City had significantly higher serum and cerebrospinal fluid levels of autoantibodies against key tight-junction and neural proteins, as well as combustion-related metals.

"We asked why a clinically healthy kid is making autoantibodies against their own brain components," Calderón-Garcidueñas said. "That is indicative of damage to barriers that keep antigens and neurotoxins away from the brain. Brain autoantibodies are one of the features in the brains of people who have neuroinflammatory diseases like multiple sclerosis."

The issue is important and relevant for one reason, she explained. The breakdown of the blood-brain barrier and the presence of autoantibodies to important brain proteins will contribute to the neuroinflammation observed in urban children and raises the question of what role air pollution plays in a 400 percent increase of MS cases in Mexico City, making it one of the main diagnoses for neurology referrals.

Calderón-Garcidueñas points out that there is a need for a longitudinal follow-up study to determine if there is a relationship between the cognition deficits and brain MRI alterations previously reported in Mexico City children, and their autoimmune responses. But what is clear is that the kids are suffering from immune dysregulation.

Once there is a breakdown in the blood-brain barrier, not only will particulate matter enter the body but it also opens the door to harmful neurotoxins, bacteria and viruses.

"The barriers are there for a reason," she explains. "They are there to protect you, but once they are broken the expected results are not good."

The results of constant exposure to air pollution and the constant damage to all barriers eventually result in significant consequences later in life. She explains that the autoimmune responses are potentially contributing to the neuroinflammatory and Alzheimer's and Parkinson's pathology they are observing in young urban children.

While the study focused on children living in Mexico City, others living in cities where there are alarming levels of air pollution such as Los Angeles, Philadelphia-Wilmington, New York City, Salt Lake City, Chicago, Tokyo, Mumbai, New Delhi or Shanghai, among others, also face major health risks. In the U.S. alone, 200 million people live in areas where pollutants such as ozone and fine particulate matter exceed the standards.

"Investing in defining the central nervous system pathology associated with exposure to air pollutants in children is of pressing importance for public health," Calderón-Garcidueñas said.


Story Source:

The above story is based on materials provided by The University of Montana. Note: Materials may be edited for content and length.


Journal Reference:

  1. Lilian Calderón-Garcidueñas, MA, MD, Ph.D. et al. Air Pollution and Children: Neural and Tight Junction Antibodies and Combustion Metals, the Role of Barrier Breakdown and Brain Immunity in Neurodegeneration. Journal of Alzheimer's Disease, August 2014 DOI: 10.3233/JAD-141365

Can your blood type affect your memory in later years?

 

September 10, 2014

American Academy of Neurology (AAN)

People with blood type AB may be more likely to develop memory loss in later years than people with other blood types, according to a study. AB is the least common blood type, found in about 4 percent of the U.S. population. The study found that people with AB blood were 82 percent more likely to develop the thinking and memory problems that can lead to dementia than people with other blood types.


New research suggests that people with blood type AB may be more likely to develop memory loss in later years than people with other blood types.

People with blood type AB may be more likely to develop memory loss in later years than people with other blood types, according to a study published in the September 10, 2014, online issue of Neurology®, the medical journal of the American Academy of Neurology.

AB is the least common blood type, found in about 4 percent of the U.S. population. The study found that people with AB blood were 82 percent more likely to develop the thinking and memory problems that can lead to dementia than people with other blood types. Previous studies have shown that people with type O blood have a lower risk of heart disease and stroke, factors that can increase the risk of memory loss and dementia.

The study was part of a larger study (the REasons for Geographic And Racial Differences in Stroke, or REGARDS Study) of more than 30,000 people followed for an average of 3.4 years. In those who had no memory or thinking problems at the beginning, the study identified 495 participants who developed thinking and memory problems, or cognitive impairment, during the study. They were compared to 587 people with no cognitive problems.

People with AB blood type made up 6 percent of the group who developed cognitive impairment, which is higher than the 4 percent found in the population.

"Our study looks at blood type and risk of cognitive impairment, but several studies have shown that factors such as high blood pressure, high cholesterol and diabetes increase the risk of cognitive impairment and dementia," said study author Mary Cushman, MD, MSc, of the University of Vermont College of Medicine in Burlington. "Blood type is also related to other vascular conditions like stroke, so the findings highlight the connections between vascular issues and brain health. More research is needed to confirm these results."

Researchers also looked at blood levels of factor VIII, a protein that helps blood to clot. High levels of factor VIII are related to higher risk of cognitive impairment and dementia. People in this study with higher levels of factor VIII were 24 percent more likely to develop thinking and memory problems than people with lower levels of the protein. People with AB blood had a higher average level of factor VIII than people with other blood types.


Story Source:

The above story is based on materials provided by American Academy of Neurology (AAN). Note: Materials may be edited for content and length.


Journal Reference:

  1. Kristine S. Alexander, Neil A. Zakai, Sarah Gillett, Leslie A. Mcclure, Virginia Wadley, Fred Unverzagt, and Mary Cushman. ABO blood type, factor VIII, and incident cognitive impairment in the REGARDS cohort. Neurology, September 2014 DOI: 10.1212/WNL.0000000000000844

Quarter of people with diabetes worldwide live in China, but new approach could help transform their care

 


Diabetes has become a major public health crisis in China, with an annual projected cost of 360 billion RMB (nearly 35 billion British pounds) by 2030, but a new collaborative approach to care that uses registries and community support could help improve diabetes care, according to a new three-part Series about diabetes in China published in The Lancet Diabetes & Endocrinology.

China has the largest number of people with diabetes of any country in the world, and the disease has reached epidemic proportions in the adult population. In 1980, less than 1% of Chinese adults had diabetes, but this increased to almost 12% (113.9 million adults) by 2010. Latest estimates indicate that around half of Chinese adults have prediabetes, putting them at high risk of diabetes and multiple related illnesses.

"Especially alarming is that most adults with diabetes are undiagnosed (70% of all cases), only a quarter of people with diabetes have received treatment and that the disease is controlled in just 40% of those treated", says Professor Guang Ning, one of the Series authors, and immediate past president of the Chinese Endocrine Society, who led the Chinese national survey of diabetes in 2010.

Worryingly, say the authors, these figures herald a major epidemic of diabetes-related complications such as cardiovascular disease, chronic kidney disease, and cancer in the near future unless there is effective national intervention.

The epidemic is the result of rapid economic development and urbanisation that has culminated in an "obesogenic environment" characterised by food abundance, physical inactivity, and psychosocial stress. What is more, Chinese people are particularly susceptible to type 2 diabetes compared with white people, and they tend to develop the disease at a much lower body mass index (BMI). The average BMI of Chinese patients with diabetes is 25 kg/m2, compared with 30 kg/m2 in non-Asians.

Over the past 30 years, China's standard of living and life expectancy have improved for many, but the aging population, dietary changes, reduced physical activity, and exceptionally high rates of smoking have contributed to the diabetes epidemic. The health consequences of this epidemic threaten to overwhelm health-care systems and urgent action is needed, warn the authors.

In future decades, the double burden of an aging population and rising rates of young-onset diabetes will have an enormous toll on productivity and health-care systems. Series co-leader Professor Ronald Ma, from the Chinese University of Hong Kong, explains: "Given the increased long-term risk of complications in people with young-onset diabetes, the potential economic and health burden associated with this epidemic is very alarming. In 1993, the cost of diabetes treatment in China was 2.2 billion RMB, but the projected cost for 2030 is 360 billion RMB, which highlights the critical importance of prevention."

There is much to be done, says Professor Juliana Chan from the Chinese University of Hong Kong, who co-led the Series: "While we await the results of long-term strategies from the China National Plan for Non-Communicable Disease Prevention and Treatment (2012-15) including tobacco control and universal screening for gestational diabetes, we advocate the use of a targeted proactive approach to identify people at high risk of diabetes for prevention, and of private-public community partnerships that make care more accessible, sustainable, and affordable focusing on registry, empowerment, and community support."

For example, community-based coordinating centres and targeted screening programs in schools and workplaces, run by trained community health workers and graduate students under medical supervision, could identify high-risk individuals and provide education about the benefits of early intervention, treatment and continuing support. Additionally, more research is needed to identify the best drug treatments for Chinese people with type 2 diabetes, who have several unique clinical characteristics.

According to Professor Chan, "As this epidemic continues to unfold, every individual must join in the grand challenge of creating a multidimensional solution to minimise its effects on societal, family, and personal health."


Story Source:

The above story is based on materials provided by The Lancet. Note: Materials may be edited for content and length.


Journal References:

  1. Wenying Yang, Jianping Weng. Early therapy for type 2 diabetes in China. The Lancet Diabetes & Endocrinology, 2014; DOI: 10.1016/S2213-8587(14)70136-6
  2. Juliana C N Chan, Yuying Zhang, Guang Ning. Diabetes in China: a societal solution for a personal challenge. The Lancet Diabetes & Endocrinology, 2014; DOI: 10.1016/S2213-8587(14)70144-5
  3. Ronald Ching Wan Ma, Xu Lin, Weiping Jia. Causes of type 2 diabetes in China. The Lancet Diabetes & Endocrinology, 2014; DOI: 10.1016/S2213-8587(14)70145-7

Neuroscientists decode brain maps to discover how we take aim

 


Boy swinging tennis racket (stock image). A recent study shows that different regions of the brain help to visually locate objects relative to one's own body and those relative to external visual landmarks.

Serena Williams won her third consecutive US Open title a few days ago, thanks to reasons including obvious ones like physical strength and endurance. But how much did her brain and its egocentric and allocentric functions help the American tennis star retain the cup?

Quite significantly, according to York University neuroscience researchers whose recent study shows that different regions of the brain help to visually locate objects relative to one's own body (self-centred or egocentric) and those relative to external visual landmarks (world-centred or allocentric).

"The current study shows how the brain encodes allocentric and egocentric space in different ways during activities that involve manual aiming," explains Distinguished Research Professor Doug Crawford, in the Department of Psychology. "Take tennis for example. Allocentric brain areas could help aim the ball toward the opponent's weak side of play, whereas the egocentric areas would make sure your muscles return the serve in the right direction."

The study finding will help healthcare providers to develop therapeutic treatment for patients with brain damage in these two areas, according to the neuroscientists at York Centre for Vision Research. "As a neurologist, I am excited by the finding because it provides clues for doctors and therapists how they might design different therapeutic approaches," says Ying Chen, lead researcher and PhD candidate in the School of Kinesiology and Health Science.

The study, "Allocentric versus Egocentric Representation of Remembered Reach Targets in Human Cortex," published in the Journal of Neuroscience, was conducted using the state-of-the-art fMRI scanner at York U's Sherman Health Science Research Centre. A dozen participants were tested using the scanner, which Chen modified to distinguish brain areas relating to these two functions.

The participants were given three different tasks to complete when viewing remembered visual targets: egocentric reach (remembering absolute target location), allocentric reach (remembering target location relative to a visual landmark) and a nonspatial control, colour report (reporting color of target).

participants remembered egocentric targets' locations, areas in the upper occipital lobe (at the back of the brain) encoded visual direction. In contrast, lower areas of the occipital and temporal lobes encoded object direction relative to other visual landmarks. In both cases, the parietal and frontal cortex (near the top of the brain) coded reach direction during the movement.When


Story Source:

The above story is based on materials provided by York University. Note: Materials may be edited for content and length.


Journal Reference:

  1. Ying Chen et al. Allocentric versus Egocentric Representation of Remembered Reach Targets in Human Cortex. Journal of Neuroscience, September 2014 DOI: 10.%u200B1523/%u200BJNEUROSCI.%u200B1445-14

Psychological study of Malaysia Airlines flight MH370 conspiracy theories

September 10, 2014

British Psychological Society (BPS)

Conspiracy theories flourish even when there is no official explanation to react against, finds a psychologist who has examined reactions to the disappearance of Malaysia Airlines flight MH370 -- the passenger jet that disappeared without a trace in March 2014. Scientists asked 250 participants to rate their agreement with a range of conspiracy explanations for the disappearance of MH370. They were also asked to rate their agreement with well-known conspiracy theories, such as those about the 9/11 attacks and the death of Princess Diana.


Conspiracy theories flourish even when there is no official explanation to react against, finds a psychologist who has examined reactions to the disappearance of Malaysia Airlines flight MH370 -- the passenger jet that disappeared without a trace in March 2014.

Dr Karen Douglas from the University of Kent presented her work today, Thursday 11 September, at the annual conference of the British Psychological Society's Social Psychology Section in Canterbury.

Dr Douglas asked 250 participants to rate their agreement with a range of conspiracy explanations for the disappearance of MH370. They were also asked to rate their agreement with well-known conspiracy theories, such as those about the 9/11 attacks and the death of Princess Diana. Participants were also asked to complete psychological measures of personality variables.

Dr Douglas said: "We expected that people who believe in MH370 conspiracy theories would also believe in other well-known conspiracy theories. However, we hypothesised that whilst variables such as paranoia, powerlessness and mistrust would predict beliefs in well-known conspiracy theories, variables such as the need for cognitive closure and belief in an unjust world may instead predict endorsement of MH370 conspiracy theories, where no official explanation exists.

"Results confirmed that people who believe in MH370 conspiracy theories also endorse well-known conspiracy theories. However, the psychological predictors of conspiracy beliefs may be the same whether an official explanation has been established or not."

Dr Douglas argued that these findings support the idea that conspiracy theories form part of a self-sustaining worldview composed of a network of mutually supportive beliefs. They do not necessarily need an official explanation to react against.


Story Source:

The above story is based on materials provided by British Psychological Society (BPS). Note: Materials may be edited for content and length.

Como Plantar Ideias na Mente dos Outros

 

Como Plantar Ideias na Mente dos Outros

Imagem de Solvent Magazine

Se alguma vez foi convencido por um vendedor de que precisava realmente de determinado produto, fez algo de forma muito instintiva, ou fez uma escolha que lhe pareceu completamente incompatível com a sua maneira de ser, então já foi alvo de uma ideia plantada na sua mente. Veja como acontece.

Antes de começar é importante notar que plantar uma ideia na mente de alguém sem que eles saibam é uma forma de manipulação. Não estamos aqui para julgá-lo, mas este é o tipo de coisas que a maioria das pessoas consideram erradas. Você não deve fazer o que está prestes a ler. Em vez disso, utilize estas informações para detetar quando alguém o está a fazer consigo.

Se já viu o filme Inception poderá pensar que plantar uma ideia na mente de alguém é algo difícil de conseguir. Não é. É ridiculamente fácil, o difícil é evitar. Vamos ver algumas maneiras sobre como plantar ideias na mente dos outros.

Psicologia Reversa Funciona de Verdade

A psicologia reversa tornou-se um enorme cliché. Acho que atingiu o auge em 1995 com o lançamento do filme Jumanji. O problema é que a maioria das pessoas olham para a psicologia reversa de uma forma simples e primária. Por exemplo, você pode dizer: “Não me importo minimamente que queiras arriscar a tua vida ao saltar de pára-quedas de um avião” para tentar convencer alguém a não saltar. Isto não é psicologia reversa – é passiva-agressiva. Portanto, vamos deixar todas essas ideias para trás e começar de novo.

Se está prestes a utilizar a lógica reversa a seu favor, precisa de ser subtil. Digamos que vive numa casa partilhada com um amigo/colega/conhecido e pretende que o seu companheiro de casa lave a loiça porque é a sua vez. Existe sempre esta abordagem:

Olha, importas-te de lavar a loiça? É a tua vez.

Neste exemplo, assumimos que o seu companheiro é preguiçoso e uma abordagem agradável não vai fazer com que ele faça o que lhe compete. Perante esta situação, o que você faz? Algo parecido com isto:

Olha, acabei de decidir que não quero mais lavar a loiça portanto vou começar a comprar material descartável, ok? Se quiseres dar-me dinheiro extra posso comprar também para ti.

Neste momento acabou de apresentar uma alternativa de baixa qualidade para o facto de ele não lavar a loiça e sem lhe colocar culpa alguma. Esta é a prova viva de como a psicologia reversa pode ser eficaz, desde que diga algo com significado.

Nunca Fale Sobre a Ideia – Fale à Volta Dela

Conseguir que alguém faça algo pode ser difícil se souber que essa pessoa não o vai querer fazer. Portanto, precisa de fazê-los acreditar que essa ideia já existia na cabeça dele. Esta é uma prática comum, especialmente para os vendedores, mas é muito mais fácil dizer que fazer. Neste caso precisa de olhar para a plantação de ideias como se tivesse a resolver um mistério. Lenta mas seguramente você vai oferecendo ao seu alvo uma série de pistas que o levarão até à conclusão óbvia do que você quer. A chave é ser paciente, porque se apressar o processo através das suas “pistas” o seu objetivo vai parecer-lhe óbvio. Se, por outro lado, o fizer lentamente, a ideia formar-se-á de forma natural.

Um exemplo prático. Suponha que está a tentar convencer um amigo a comer alimentos mais saudáveis. Começa com um objetivo positivo mas tem um inimigo extremamente difícil: o seu amigo está viciado em fast-food e tem que comer comida de plástico pelo menos uma vez por dia. Como amigo que é, você diz-lhe que devia comer comida mais saudável. Ele não só acha que não é uma boa ideia como continua com o seu mau hábito ou diz-lhe simplesmente para parar de o chatear. Ele precisa de sentir o quão mal está a fazer ao seu corpo e você pode fazer isso acontecer, conversando à volta da ideia que pretende transmitir.

Para o conseguir você precisa de ser inteligente e subtil, caso contrário tornar-se-á óbvio. Não pode simplesmente dizer “olha, ainda há pouco li que comer fast-food mata 10 milhões de crianças todos os anos”, porque essa informação vale zero e transmite uma motivação óbvia. Se o hambúrguer é o alvo, você precisa de fazer com que este pareça extremamente desagradável. Da próxima vez que espirrar, faça uma piada com uma doença qualquer nos animais que compõem o hambúrguer. Quando almoçarem juntos, transmita verbalmente o porquê da sua escolha relativamente ao que vai comer e decida por algo que não hambúrguer. Quando tiver feito o suficiente destas práticas e, mais uma vez, com bastante espaço temporal entre os acontecimentos, seja um pouco mais agressivo e tente novamente que ele deixe de comer fast-food. Ao mesmo tempo também pode agir para tomar medidas proativas que melhorem a sua própria saúde e diga ao seu amigo 1) o que está a fazer e 2) o quão bem essa escolha lhe tem vindo a fazer. Depois de algumas semanas, se ele não decidiu reconsiderar a sua posição relativamente à frequência de fast-food, pode menciona-lo casualmente e ele deverá estar mais aberto a uma discussão real.

Subvalorização

A subvalorização é, provavelmente, uma das maneiras mais fáceis e eficazes para plantar uma ideia na mente de alguém. Esta é uma outra versão da psicologia reversa, mas num nível menos agressivo. Vamos supor que está a tentar vender um disco rígido. Um cliente pode comprar um disco de 250GB, 500GB ou 1TB. Você quer vender o disco rígido com maior capacidade porque os lucros são mais significativos. O cliente chega até si com a ideia de comprar o disco mais barato possível. A sua margem de manobra é curta, e não irá longe se lhe disser que deveria gastar mais dinheiro quando sabe de antemão que isso é precisamente o que ele não quer. Em vez disso, precisa de corresponder às pretensões do seu cliente: a opção mais barata. Aqui está um exemplo de diálogo:

Cliente: Pode falar-me um pouco sobre este disco rígido de 250GB? Tenho quase a certeza que me chega.

Você: Que tipo de computador você tem e de que forma vai utilizar o disco?

Cliente: Eu tenho um portátil com 2 anos, com Windows e preciso do disco para guardar fotos. Tenha cerca de 30GB de fotos.

Você: 250GB é mais do que suficiente para armazenar as suas fotos, por isso, enquanto não tem muito mais ficheiros e informação para guardar, este é suficiente para as suas necessidades.

Esta última frase insere dúvida no comprador. Você pode mesmo colmatar com “só precisa de um carro maior se quiser garantir que vai ter espaço suficiente no futuro”, mas pode parecer forçado. O importante é: transmitindo uma mensagem de que está a atuar dentro dos interesses do cliente irá fazê-lo pensar que quer comprar algo mais.

Mais uma vez, quero aproveitar esta oportunidade para lembrar a todos que plantar ideias na mente dos outros não é necessariamente uma coisa boa a fazer. Use essas informações para detetar quando alguém está a fazê-lo consigo, e não necessariamente como guia para fazê-lo a outra pessoa.

ScienceLives Interview with Steven Clark

Steven Clark, a Psychology Professor at the University of California, Riverside, has spent the last 29 years conducting research on human memory and decision-making. During that period of time, 269 people were convicted of crimes they did not commit and were exonerated based on DNA evidence. In the vast majority of those cases, the wrongful conviction was based in whole, or in part, on mistaken eyewitness identification. The challenge for the criminal justice system, according to Clark, is to devise identification procedures that reduce the risk of false identifications of the innocent, without losing correct identifications of the guilty. Credit: NSF

 

Snap 2014-09-11 at 11.06.18

Prying Open the Black Box of the Brain


NSF-funded workshop addresses brain structure and function

Graphic illustration showing a human head, light and waves

How does the brain record, process, use, store and retrieve vast quantities of information?
Credit and Larger Version

The human brain is the most complex biological structure on Earth. It has about 100 billion neurons--each of which has thousands of connections to other neurons.

Moreover, brains change with time for a variety of reasons. For example, as we age, our brains lose nerve cells (neurons). In addition, the wiring of our brains is continually altered as we learn, socialize, undergo stress and encounter varied environmental conditions. That's right: Our brains are anatomically and physiologically changed by normal intellectual and physical experiences.

So each of us--continually subjected to new and different brain-changing experiences--has a unique brain. In fact, even the brains of identical twins differ from one another. What's more, brain injuries may trigger various types of changes in the anatomy and physiology of the brain to compensate for lost function and/or maximize remaining functions.

Largely because the brain is so complex and dynamic, it is still akin to a locked black box--3 pounds of mystery lodged between our ears. Indeed, our understanding of the brain remains downright rudimentary compared to our understanding of other organs.

Desperately seeking a theory

Despite major technological advances in brain research during recent decades, scientists have yet to describe all of the various types of cells that comprise the brain and determine their functions. Complicating matters further, the brain is more than the sum of its parts. That is, the various components of the brain do not operate in isolation from one another; they must communicate with one another and work together to process information and produce memories, thoughts and behaviors.

But scientists still don't understand how information is processed in any organism, whether it be a lowly worm whose nervous system is comprised of only a few hundred neurons or a complex vertebrate. We simply do not know what happens in the brain when an organism thinks, maneuvers through the world, takes in sensory information or sleeps.

In other words, scientists lack a basic, overarching theory about healthy brain function that would explain how memories, thoughts and behaviors emerge from dynamic activities in the brain--any brain.

This theoretical vacuum has persisted even though molecular, cellular and neuronal activities in the brains of many species have been well studied, as has behavior in many species, including humans. Nevertheless, the relationships between these two types of phenomena and the sequence of events that translates one to the other remain mysterious.

By providing a framework for predicting how micro events in the brain produce behaviors, and vice-versa, a theory of healthy brain function would contribute as much to neuroscience as the theory of evolution contributes to the tree of life, the theory of plate tectonics contributes to geology and the theory of relativity contributes to cosmology.

But still unable to explain how a normal brain functions, scientists cannot yet explain how traumatic injuries and brain diseases, such as Alzheimer's, schizophrenia, autism and epilepsy, impair function. Nor can they determine how brain injuries and diseases should be treated. By comparison, imagine a mechanic trying to fix a car's engine without a parts list and/or understanding how it runs!

It is even difficult for scientists to so much as agree on which neurological variables should be studied. Such disagreement, however, would probably be reduced by a viable theory of healthy brain function because it would likely reveal particularly promising areas of future research. It could do so by, for example, helping scientists identify important neuronal nodes that warrant more attention than do thickets of rank-and-file neurons.

The new BRAIN Initiative

Responding to the need for a comprehensive understanding of the brain, President Barack Obama launched the Brain Research through Advancing Innovative Neurotechnologies (BRAIN) Initiative on April 2, 2013. Led by the National Science Foundation (NSF), the National Institutes of Health (NIH) and the Defense Advanced Research Projects Agency (DARPA), BRAIN is a bold new research effort.

Extending beyond mere mapping of the brain, the BRAIN Initiative is aimed at producing an array of tools that are needed to establish an integrated theory of how a healthy brain functions over an organism's life. This theory will provide a fundamental framework for interpreting new information on brain science and will change existing paradigms for explaining "who we are."

"When scientists do ultimately figure out how the brain works--however long it takes, this accomplishment will probably be considered the greatest scientific achievement in all of human history," said John Wingfield, NSF's assistant director for the Biological Sciences Directorate.

NSF'S role in BRAIN

Brain processes are multidisciplinary phenomena, incorporating the principles of biology, chemistry, physics, engineering and mathematics. Therefore, efforts to understand these processes under BRAIN require multidisciplinary approaches. "The kinds of challenges we are facing in the study of neuroscience require contributions from a wide range of scientific and engineering disciplines," said Denise Caldwell, NSF's division director for Physics.

Needed basic research: Examples of the types of multidisciplinary advancements that are needed to advance BRAIN include:

  • Basic studies conducted by biologists, in collaboration with physicists, chemists, mathematicians and engineers, on the healthy functioning of the nervous systems of many types of species, from those with simple nervous systems to complex vertebrates--not just on humans and organisms that have traditionally served as model organisms in brain studies. Such studies would be based on a species comparative approach.
  • Theoretical and computational models created by physicists, mathematicians and computer scientists that will help reveal and predict complex neural activities in the healthy brain that drive thoughts and behavior.
  • New materials developed by materials scientists and engineers that are needed to create innovative types of brain probes that can be used to monitor and manipulate the brain.
  • Optical and electrical tools developed by physicists and engineers to better image the brain and brain activity.

NSF's key contributions: NSF is uniquely positioned to foster these and other types of needed innovations because the agency supports basic research across the scientific and engineering disciplines. What's more, NSF has already helped lay the groundwork for BRAIN by supporting many game-changing innovations in brain research, including the development of the following:

  • Optogenetics: A bioengeering technique that enables scientists to selectively turn on and off particular neurons and neuronal circuits in living organisms so that resulting behavioral changes can be observed in real time.
    Optogenetics is currently being used to help identify the functions of neurons and neuronal circuits and to help identify appropriate targets for drugs or technologies that address brain dysfunction. (See
    an NSF article about the contributions of optogenetics to research on Parkinson's disease and an NSF article on its contributions to research on anxiety.)
    A crucial prerequisite to the development of optogenetics was a discovery that was produced by research on a seemingly unrelated topic: algae. Specifically, this research identified the presence and molecular structure of light-sensitive proteins in algae. Turned on by light, these proteins help them find light that is needed by the algae to produce energy through photosynthesis.
    After the light-sensitive algae proteins were discovered, brain researchers found that they could impart the brain neurons and neuronal circuits of various species with light sensitivity by inserting into them the light-sensitive algae proteins. Once made light sensitive, the neurons and circuits could be turned on merely by shining a light on them, and turned off by other types of simple light manipulations.
    The basics of optogenetics were thus developed. This pivotal application of algae research to neuroscience underscores the importance to BRAIN of NSF-funded basic research--including basic research in seemingly far-flung disciplines.
  • CLARITY: A new brain imaging technology, announced on April 10, 2013, that can be used to generate detailed, 3-D images of intact brains that highlight specific neuronal networks. These images can be produced without slicing the brain and disrupting its biochemistry, as previously required.

Potential applications of NSF-funded BRAIN research

By supporting additional multidisciplinary research under BRAIN, NSF will help produce a deep foundation of fundamental information of healthy brain function. This foundation will help reveal "how the car is designed, rather than just how it might be fixed." It may thereby open up entirely new avenues for NIH's research on brain diseases and DARPA's research on traumatic brain injuries.

This foundation may also offer applications to important issues that are unrelated to health. For example, this research may help explain differences in individual learning styles, reveal the origins of cultural mores, and provide insight into what makes people "tick" as individuals. It may also inspire the development of new "smart" technologies that mimic the information processing capabilities of the human brain.

NSF-funded BRAIN research may also help improve resource management. For example, this research may help scientists identify environmental conditions that promote the development of the nervous systems and metabolic systems of animals, such as fish and livestock. Resulting insight may help resource managers design aquaculture and livestock facilities to maximize the growth and productivity of their animals.

Brain studies may also help scientists figure out why many species of endangered vertebrates do not reproduce well in captivity--and explain why some species easily adapt to climate change, while other, closely related species cannot do so.

"We think that these [and other] phenomena are related to how an organism perceives its environment, which, in turn, is related to its brain function," said Wingfield. "Therefore, advancements in our basic understanding of the brain may have important implications for conservation and--by extension--our quality of life."

The kick-off of BRAIN: A meeting of the minds

NSF set the stage for producing such advancements by sponsoring the first BRAIN event: A workshop called "Physical and Mathematical Principles of Brain Structure and Function," which was held in Arlington, Va., on May 6 and 7, 2013.

The workshop drew 150 leading researchers from varied disciplines including physics, mathematics and neurobiology. These researchers represented more than 60 institutions including NIH, DARPA, and other federal agencies, research institutions, academic journals and the private sector.

Good timing: Physical and Mathematical Principles of Brain Structure and Function was fortuitously timed to tap into the sense of possibility generated by the coincidental release of CLARITY just weeks before the conference began, and by the recent development of optogenetics and various other new technologies for creating high-resolution images of brains with electron microscopes and for recording electrical impulses from brains.

"This conference was particularly timely because the community has realized that technologies for brain research have advanced to the point where we can now make a real leap in knowledge," said Caldwell.

Discussions about salient past and future multidisciplinary contributions to neuroscience also helped to generate an air of excitement, esprit de corps and sense of purpose at the workshop.

Developing research priorities: Various workshop activities, including presentations, break-out sessions and an invitation to participants to submit white papers, were designed to solicit their input on technical topics. These topics included important challenges in brain research, the types of computational approaches and tools that are most needed for advancing brain research, best practices for integrating data to produce knowledge, and methods for incentivizing multidisciplinary brain research.

The workshop culminated with the development of consensus by participants on the following priorities for future neuroscience research:

  • Identifying signatures in neural activity that can be used to predict complex behaviors. These signatures may be identified through studies involving large-scale recordings from representative sets of neurons in multiple species and through high-resolution studies of neuro-anatomy in many species.
  • Developing theoretical and computational models that can be used to understand and analyze data produced by large-scale neural recordings.
  • Promoting unprecedented levels of international sharing of data on brain research and education. Doing so will involve developing standardized cyber tools and standards for data collection, analysis and integration--tasks that require solving complex "Big Data" problems.

"This initial set of over-arching priorities will set the stage for future detailed quantitative research," said Caldwell. "Results from this future research will drive advances in theoretical understanding that will, over the coming years, bring scientists closer to achieving the ultimate goal of understanding how the brain works and using this understanding to benefit human health."

For more information: To learn more about the goals of the workshop and potential follow-up activities, view the two video interviews with NSF and NIH executives that accompany this article. And to access various resources produced by the BRAIN workshop, including white papers, videos of conference presentations and the conference agenda, visit the workshop's website.

For more information on NSF-funded research on BRAIN-related topics, go to:

--
Lily Whiteman, National Science Foundation (703) 292-8310 lwhitema@nsf.gov

--
Abby Deift, National Science Foundation (703) 292-4934 adeift@nsf.gov

Related Websites
Mapping and Engineering the Brain: http://ieeexplore.ieee.org/stamp/stamp.jsp?tp=&arnumber=6615987
UA Study: Your Brain Sees Things You Don't: http://uanews.org/story/ua-study-your-brain-sees-things-you-don-t
NSF Workshop on Integrating Approaches to Computational Cognition: http://matt.colorado.edu/compcogworkshop/supplement.pdf
Phylogenetic Principles of Brain Structure and Function: Brain Maps Across Phylogeny: http://www.understandingthebrain.org/
Report from the NSF Workshop on Integrating Approaches to Computational Cognition: http://matt.colorado.edu/compcogworkshop/report.pdf
Report from the NSF Workshop on Linking Language and Cognition to Neuroscience via Computation: http://www.psych.nyu.edu/clash/dp_papers/NSF-Workshop-report.pdf
Report of the Physical and Mathematical Principles of Brain Structure and Function Workshop: http://physicsoflivingsystems.org/brainstructureandfunction/wp-content/uploads/sites/2/2013/10/Report-on-NSF-Kavli-BRAIN-Mtg-1.pdf

Snap 2014-09-11 at 11.06.18

Martinho da Vila, o sorriso brasileiro.

 

Martinho da Vila faz parte da minha coleção de ídolos da MPB. Em 99% das suas fotos, e em qualquer evento do qual participe, ele exibe sua marca registrada, seu sorriso. Suas músicas são sempre alegres, bacanas, e já deve ter vendido muitos discos, muitos mesmo.

Alguns inícios de músicas de Martinho que eu curto:

1) É devagar, é devagar, é devagar, é devagar, devagarinho….

2) Felicidade, passei no vestibular, mas a Faculdade é particular..

3) Chora, chora, chora Carolina, que este choro é bom de chorar.  Canta, canta, canta Carolina, quanto tem vontade de cantar. ( E outras mais)

2108martinho1

 

images

Que é isso, Martinho! O meu não é tão grande assim. Uns 2 cm a menos.

Emotional Fitness

 

 

Harness the power of emotion to deepen your love with your partner, become more successful at work, and more

by Barton Goldsmith, Ph.D.

10 Instant Emotional Fitness Tools

10 Tools to help you regain your emotional balance.

When things get out of control and you momentarily lose your emotional balance, there are any number of little things you can do to regain it. Here are ten tools to help get you started.

1. Wash your hands and face and brush your teeth. It cools and cleans the parts of your body that you use most frequently, which is relaxing, and gives you that "fresh start" feeling.

2. Put on clean socks and some shoes that you haven't worn in a few days. Shoes take a day or two to release any moisture they have absorbed, and this is a very easy way to put a little pep back into your step.

3. Give yourself a good shave (face or legs). This is another instant refresher. Especially if you have sensitive skin or the weather is dry. Plus, when we know we are looking our best, we naturally feel better.

4. Look at any trophy, diploma, or certificate of achievement that you have earned. And if it isn't framed and on the wall, frame it now. These are reminders of your accomplishments, and taking in your success is important to maintaining your self-esteem.

5. Remember your last (or greatest) success and think about it for sixty seconds. Taking in your success as often as possible will help you reach another and another. Quite simply, it reminds you that if you've done it before, you can do it again.

6. Know you are the person your loved ones think you are. And yes, that goes for your dog too. Knowing that you are unconditionally loved can't help but make you feel good about yourself. It's so easy to beat yourself up, I recommend pulling yourself up instead.

7. Wash your car, inside and out. Hey, when our wheels are shiny, we feel better. If you don't think this applies to you, just remember how you felt the last time you got a ride in someone's very funky car. Race you to the car wash.

8. Organize your closet and get rid of anything that no longer fits. Old clothes may come back into style, but you really don't want them on hangers for the next twenty years. Throwing out the old makes room for the new. For some, the feeling they get from putting on a new "power suit" fills them with pride.

9. Cook a lovely meal. Even if you are by yourself, preparing a tasty dinner, setting the table, and treating yourself to a wonderful culinary experience will lift your spirits. Sharing it with someone you love and/or respect will make it even more nurturing.

10. Look around you, remember that you started with nothing, and know that everything you see, you created. We can all lose our feelings of self-worth, especially when something goes wrong in our world. The truth is that if you have done it before, you can do it again-no matter what.

None of these tasks has to be uncomfortable or take you much time. Finding ways to give yourself a little boost when you're not feeling like you're at the top of your game is a trick that truly happy people use on a regular basis.

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23 Reader comments join the discussion here!

 

Snap 2014-09-11 at 08.59.25

Free guided meditations

 

Meditations

 

1246405

Why do mushrooms turn brown?

 


The research team of Annette Rompel from the Institute for Biophysical Chemistry, University of Vienna explore the mechanisms behind the "browning reaction" during the spoilage of mushrooms. The researchers were able to demonstrate that the enzyme responsible is already formed prior to fungal spoiling. The detailed study is published online in the journals, Phytochemistry and Acta Crystallographica.

Understanding the mechanism of enzyme tyrosinase pigmentation is currently of both medical as well as technological interest. The copper-containing enzyme is present in animals and humans and is essential for the protective pathway against UV radiation, it also simultaneously provides the elucidation and potential means with which to prevent the spoilage of food. Mushrooms were selected for the study due to their low cost and ready availability. In addition they are also a valuable target for researchers, largely because of their high enzyme content, fungi are ideal sources for potential studies of tyrosinase. The mushrooms therefore serve as a model organism for the study of the pathway involved in food spoilage.

Elucidation of an inactive precursor

Since 2012, it has become established that six different tyrosinases (PPO1 to 6) exist within the mushroom, two of which (PPO3 and PPO4) occur in larger quantities. The enzyme responsible for the mechanism of food spoilage is formed within eukaryotes (organisms that have a nucleus) as an inactive precursor during the developmental phase of an organism. This precursor is then activated via specific chemical cleavage. At this cleavage site, the protein segment covering part of the enzyme active site is removed and the substrates (tyrosine and other monophenols) can be accessed and take part in key chemical reactions.

New Method of Isolation and unique reagent leads to success

None of the previously established methods of isolation present in the literature could be successfully applied for PPO4. For the first time, at the Institute for Biophysical Chemistry of the University of Vienna, a method was developed that allows for the one stage isolation of latent tyrosinase from their natural source. The enzyme characterization was undertaken at the Department of Chemistry with close cooperation with the Institute of Mass Spectrometry lead by Andreas Rizzi, both within the University of Vienna. After sufficiently large quantities were extracted from pure PPO4, the researchers were able to identify and optimize appropriate crystallization conditions which produced well formed protein crystals. This was only possible with the use of a relatively unusual co-crystallization reagent, a polyoxometalate of the Anderson type.

Integral for medicine and biotechnology

The PhD student Stephan Mauracher worked at the University of Vienna, taking an essential part in this project as part of the University Initiative termed "Functional Molecules." Following this research it has been made possible to purify the enzyme in sufficient quantities for characterization. Ulrich Kortz, working at the Jacobs University of Bremen was responsible for synthesizing the polyoxometalate used and was a key proponent of its usage as an additive for protein crystallization.

The research project was then continued as FWF Initiative. "This research has allowed for the crystallization and three-dimensional structure of PPO4 to be resolved," says Anette Rompel.


Story Source:

The above story is based on materials provided by University of Vienna. Note: Materials may be edited for content and length.


Journal References:

  1. Stephan Gerhard Mauracher, Christian Molitor, Rami Al-Oweini, Ulrich Kortz, Annette Rompel. Latent and activeabPPO4 mushroom tyrosinase cocrystallized with hexatungstotellurate(VI) in a single crystal. Acta Crystallographica Section D Biological Crystallography, 2014; 70 (9): 2301 DOI: 10.1107/S1399004714013777
  2. Stephan Gerhard Mauracher, Christian Molitor, Rami Al-Oweini, Ulrich Kortz, Annette Rompel. Crystallization and preliminary X-ray crystallographic analysis of latent isoform PPO4 mushroom (Agaricus bisporus)tyrosinase. Acta Crystallographica Section F Structural Biology Communications, 2014; 70 (2): 263 DOI: 10.1107/S2053230X14000582
  3. Stephan G. Mauracher, Christian Molitor, Claudia Michael, Martin Kragl, Andreas Rizzi, Annette Rompel. High level protein-purification allows the unambiguous polypeptide determination of latent isoform PPO4 of mushroom tyrosinase. Phytochemistry, 2014; 99: 14 DOI: 10.1016/j.phytochem.2013.12.016