UPDATE 1-Toshiba says to operate new chip plant with SanDisk

July 15, 2010 By Leave a Comment

YOKKAICHI, Japan, July 14 (Reuters) – Toshiba Corp (6502.T), Japan’s biggest chipmaker, said on Wednesday it would form a new partnership with SanDisk Corp (SNDK.O) to operate its latest NAND flash memory plant in Yokkaichi, western Japan.

SanDisk, the world’s top maker of flash memory cards, is a production partner at Toshiba’s existing plants. It said it would provide half of the investment cost for production equipment and would take half the output.

Toshiba, the world’s second-biggest NAND chip maker after Samsung Electronics (005930.KS), said construction of the new plant, called Fab 5, would be completed in early 2011 and the initial manufacturing process would use 20-29 nanometre circuitry.

A nanometre is one-billionth of a metre. Smaller circuitry allows chipmakers to pack more power onto smaller chips and lower per-chip costs.

With the new plant, Toshiba and SanDisk aim to boost their competitiveness when they see strong demand for NAND flash memories that are used in devices such as smartphones and tablet PCs. (Reporting by Kentaro Hamada, Writing by Sachi Izumi; Editing by Michael Watson)

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REFILE-Toshiba says to operate new chip plant with SanDisk

July 15, 2010 By Leave a Comment

July 14 (Reuters) – Toshiba Corp (6502.T), Japan’s biggest chipmaker, said on Wednesday it would form a new partnership with SanDisk Corp (SNDK.O) to operate its latest NAND flash memory plant in Yokkaichi, western Japan.

Toshiba, the world’s second-biggest NAND chip maker after Samsung Electronics (005930.KS), said the construction of the new plant, Fab 5, would be completed in early 2011 and the initial manufacturing process would use 20-29 nanometre circuitry. A nanometre is one-billionth of a metre. (Reporting by Kentaro Hamada, Writing by Sachi Izumi)

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UPDATE 1-Japan’s Elpida to raise $200 mln from Kingston

April 3, 2010 By Leave a Comment

* Elpida to raise $125 mln in shares, $75 mln in conv bond

Stocks | Technology

* To use funds for capital investment

* Elpida struggling to keep up with rivals in DRAM market

TOKYO, April 2 (Reuters) – Japanese memory chipmaker Elpida Memory Inc (6665.T) said it would raise about $200 million by issuing new shares and convertible bonds to U.S. DRAM module supplier Kingston Technology.

Elpida, which is struggling to keep pace with Samsung Electronics (005930.KS) and Hynix Semiconductor (000660.KS) in the DRAM chip market, said it would raise 11.7 billion yen ($125 million) by selling Kingston 6.47 million shares.

Elpida also plans to issue a $75 million convertible bond maturing in 2013 to Kingston.

Elpida said it would use the funds for capital investment as it aims to advance to finer circuitry to produce DRAM chips more efficiently.

Hit by the global economic downturn, Elpida received an injection of public money last year. [ID:nTOE60R07I] (Editing by Chris Gallagher)

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UPDATE 1-Japan’s Elpida to raise $200 mln from Kingston

April 3, 2010 By Leave a Comment

* Elpida to raise $125 mln in shares, $75 mln in conv bond

Stocks | Technology

* To use funds for capital investment

* Elpida struggling to keep up with rivals in DRAM market

TOKYO, April 2 (Reuters) – Japanese memory chipmaker Elpida Memory Inc (6665.T) said it would raise about $200 million by issuing new shares and convertible bonds to U.S. DRAM module supplier Kingston Technology.

Elpida, which is struggling to keep pace with Samsung Electronics (005930.KS) and Hynix Semiconductor (000660.KS) in the DRAM chip market, said it would raise 11.7 billion yen ($125 million) by selling Kingston 6.47 million shares.

Elpida also plans to issue a $75 million convertible bond maturing in 2013 to Kingston.

Elpida said it would use the funds for capital investment as it aims to advance to finer circuitry to produce DRAM chips more efficiently.

Hit by the global economic downturn, Elpida received an injection of public money last year. [ID:nTOE60R07I] (Editing by Chris Gallagher)

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Scientists create world’s smallest semiconductor laser

September 1, 2009 By Leave a Comment

Washington, August 31 (ANI): Researchers at the University of California (UC), Berkeley, have created the world’s smallest semiconductor laser, capable of generating visible light in a space smaller than a single protein molecule, an invention that breaks new ground in the field of optics.

The UC Berkeley team not only successfully squeezed light into such a tight space, but found a novel way to keep that light energy from dissipating as it moved along, thereby achieving laser action.

While it is traditionally accepted that an electromagnetic wave – including laser light – cannot be focused beyond the size of half its wavelength, research teams around the world have found a way to compress light down to dozens of nanometers by binding it to the electrons that oscillate collectively at the surface of metals.

This interaction between light and oscillating electrons is known as surface plasmons.

Scientists have been racing to construct surface plasmon lasers that can sustain and utilize these tiny optical excitations.

However, the resistance inherent in metals causes these surface plasmons to dissipate almost immediately after being generated, posing a critical challenge to achieving the buildup of the electromagnetic field necessary for lasing.

Zhang and his research team took a novel approach to stem the loss of light energy by pairing a cadmium sulfide nanowire – 1,000 times thinner than a human hair – with a silver surface separated by an insulating gap of only 5 nanometers, the size of a single protein molecule.

In this structure, the gap region stores light within an area 20 times smaller than its wavelength.

Because light energy is largely stored in this tiny non-metallic gap, loss is significantly diminished.

With the loss finally under control through this unique “hybrid” design, the researchers could then work on amplifying the light.

Trapping and sustaining light in radically tight quarters creates such extreme conditions that the very interaction of light and matter is strongly altered, the study authors explained.

“This work shatters traditional notions of laser limits, and makes a major advance toward applications in the biomedical, communications and computing fields,” said Xiang Zhang, professor of mechanical engineering and director of UC Berkeley’s Nanoscale Science and Engineering Center.

The achievement helps enable the development of such innovations as nanolasers that can probe, manipulate and characterize DNA molecules; optics-based telecommunications many times faster than current technology; and optical computing in which light replaces electronic circuitry with a corresponding leap in speed and processing power.

Scientists hope to eventually shrink light down to the size of an electron’s wavelength, which is about a nanometer. (ANI)

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How practice improves zebra finch’s singing performance

July 8, 2009 By Leave a Comment

Washington, July 7 (ANI): A study on zebra finches conducted by neuroscientists at the Massachusetts Institute of Technology (MIT) has shed some light on how practice improves performance.

The researchers say that studying the chirps of zebra finches helped them determine that as these tiny songbirds fine-tune their songs, their brains initially store improvements in one brain pathway, before transferring this learned information to the motor pathway for long-term storage.

They believe that their findings may further scientists’ understanding of the complicated circuitry of the basal ganglia, brain structures that play a key role in learning and habit formation in humans.

The basal ganglia are also linked to disorders like Parkinson’s disease, obsessive-compulsive disorder and drug addiction.

“Birds provide a great system to study the fundamental mechanisms of how the basal ganglia contributes to learning. Our results support the idea that the basal ganglia are the gateway through which newly acquired information affects our actions,” said senior author Michale Fee, an investigator in the McGovern Institute for Brain Research at MIT.

The researchers point out that young zebra finches learn to sing by mimicking their fathers, whose song contains multiple syllables in a particular sequence.

Like the babbling of human babies, young birds initially produce a disorganized stream of tones, but after practicing thousands of times they master the syllables and rhythms of their father’s song.

Studies conducted in the past have identified two distinct brain circuits that contribute to this behaviour in zebra flinches.

A motor pathway is responsible for producing the song, and a separate pathway is essential for learning to imitate the father. The learning pathway, called the anterior forebrain pathway (AFP), has similarities to basal ganglia circuits in humans.

“For this study, we wanted to know how these two pathways work together as the bird is learning. So we trained the birds to learn a new variation in their song and then we inactivated the AFP circuit to see how it was contributing to the learning,” said first author Aaron Andalman, a graduate student in Fee’s lab.

With a view to training the birds, the research team monitored their singing and delivered white noise whenever a bird sang a particular syllable at a lower pitch than usual.

“The bird hears this unexpected noise, thinks it made a ‘mistake’, and on future attempts gradually adjusts the pitch of that syllable upward to avoid repeating that error. Over many days we can train the bird to move the pitch of the syllable up and down the musical scale,” Fee said.

On a particular day, after four hours of training in which the birds learned to raise the pitch, the researchers temporarily inactivated the AFP with a drug. The pitch immediately slipped back to where it had been at the start of that day’s training session – suggesting that the recently learned changes were stored within the AFP.

The research group, however, observed that over the course of 24 hours, the brain had transferred the newly learned information from the AFP to the motor pathway. The motor pathway was storing all of the accumulated pitch changes from previous training sessions. (ANI)

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Study links more gene mutations to autism risk

June 27, 2009 By Leave a Comment

Washington, June 26 (ANI): A collaborative team of geneticists from The Children’s Hospital of Philadelphia, the University of Pennsylvania School of Medicine, and several other institutions say that they have found more autism susceptibility genes.

The researchers said that they identified 27 different genetic regions where rare copy number variations – missing or extra copies of DNA segments – were found in the genes of children with autism spectrum disorders (ASDs), but not in the healthy controls.

The complex combination of multiple genetic duplications and deletions is thought to interfere with gene function, which can disrupt the production of proteins necessary for normal neurological development.

“We focused on changes in the exons of DNA-protein-coding areas in which deletions or duplications are more likely to directly disrupt biological functions,” said study leader Dr. Hakon Hakonarson, director of the Center for Applied Genomics at The Children’s Hospital of Philadelphia and associate professor of Pediatrics at the University of Pennsylvania School of Medicine.

“We identified additional autism susceptibility genes, many of which, as we previously found, belong to the neuronal cell adhesion molecule family involved in the development of brain circuitry in early childhood,” he added.

According to him, the study also revealed many “private” gene mutations, those found only in one or a few individuals or families-an indication of genetic complexity, in which many different gene changes may contribute to an autism spectrum disorder.

“We are finding that both inherited and new, or de novo, genetic mutations are scattered throughout the genome and we suspect that different combinations of these variations contribute to autism susceptibility,” said Dr. Maja Bucan, professor of Genetics at the University of Pennsylvania School of Medicine and Chair of the Steering committee for Autism Speaks’ Autism Genetic Resource Exchange (AGRE).

“We are grateful to families of children with autism spectrum disorders for their willingness to participate in genetic studies because family-based studies have many advantages. We have learned a lot both from genetic analyses of children with autism as well as analyses of their patents and their unaffected siblings,” the researcher added.

During the study, the researchers compared genetic samples of 3,832 individuals from 912 families with multiple children with ASDs from the AGRE cohort against genetic samples of 1,070 disease-free children from The Children’s Hospital of Philadelphia.

They said that their research also unveiled two novel genes in which variations were found, BZRAP1 and MDGA2. According to them, they were thought to be important in synaptic function and neurological development, respectively.

Key variants of these genes, say the researchers, were transmitted in some, but not all, of the affected individuals in families.

A research article on the findings has been published in the journal PloS Genetics. (ANI)

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How drug-or-alcohol addiction tricks the brain

May 29, 2009 By Leave a Comment

Washington, May 29 (ANI): The brain’s pleasure center gets hijacked when someone becomes addicted to drugs or alcohol. This, in turn, disrupts the normal functioning of its reward circuitry.

Now, researchers investigating the addiction “switch” have implicated a naturally occurring protein, a dose of which allowed them to get rats hooked with no drugs at all.

The research has been published in the journal Science.

“If we can understand how the brain’s circuitry changes in association with drug abuse, it could potentially suggest ways to medically counteract the effects of dependency,” said Scott Steffensen, a neuroscientist at Brigham Young University who co-authored the study with two of his undergraduate students, one of his grad students, and a team of researchers at the University of Toronto.

Chronic drug users, as noted by previous research, can experience an increase of a naturally-occurring protein called BDNF (brain-derived neurotrophic factor) in the brain’s reward circuitry, a region scientists call the ventral tegmental area.

In the study, the researchers took the drugs out of the equation and directly infused extra BDNF onto this part of the brain in rats.

The Toronto team noted that a single injection of BDNF made rats behave as though they were dependent on opiates (which they had never received). Though rats instinctively prefer certain smells, lighting and texture, these rats left their comfort zone in search of a fix.

“This work may reveal a mechanism that underlies drug addiction,” said lead author Hector Vargas-Perez, a neurobiologist at the University of Toronto.

The BYU team confirmed that the protein is a critical regulator of drug dependency.

After the BDNF injection, specific chemicals that normally inhibit neurons in this part of the brain instead excited them, a “switch” known to occur when people become dependent on drugs. (ANI)

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How flowering plants originated about 130 million years ago

May 19, 2009 By Leave a Comment

Washington, May 19 (ANI): A new study is helping shed light on the mystery of the sudden origin of flowering plants about 130 million years ago, with information about what the first flowers looked like and how they evolved from non-flowering plants.

“There was nothing like them before and nothing like them since,” said Andre Chanderbali, lead author of the study and a postdoctoral associate at Unifersity of Florida’s (UF’s) Florida Museum of Natural History.

“The origin of the flower is the key to the origin of the angiosperms (flowering plants),” he added.

The flower is one of the key innovations of evolution, responsible for a massive burst of evolution that has resulted in perhaps as many as 400,000 angiosperm species.

Before flowering plants emerged, the seed-bearing plant world was dominated by gymnosperms, which have cone-like structures instead of flowers and include pine trees, sago palms and ginkgos.

Gymnosperms first appeared in the fossil record about 360 million years ago.

The new study provides insight into how the first flowering plants evolved from pre-existing genetic programs found in gymnosperms and then developed into the diversity of flowering plants we see today.

The study compares the genetic structure of two vastly different flowering plants to see whether differences exist in the set of circuits that create each species’ flower.

Researchers examined the genetic circuitry of Arabidopsis thaliana, a small flowering plant commonly used as a model organism in plant genetics research, and the avocado tree Persea americana, which belongs to an older lineage of so-called basal angiosperms.

“What we found is that the flower of Persea is a genetic fossil, still carrying genetic instructions that would have allowed for the transformation of cones into flowers,” Chanderbali said.

Advanced angiosperms have four organ types: female organs (carpels), male organs (stamens), petals (typically colorful) and sepals (typically green).

Basal angiosperms have three: carpels, stamens and tepals, which are typically petal-like structures.

The researchers expected each type of organ found in Persea’s flowers would have a unique set of genetic instructions. Instead they found significant overlap among the three organ types.

“Although the organs are developing to ultimately become different things, from a genetic developmental perspective, they share much more than you would expect,” Chanderbali said.

According to Virginia Walbot, a biology professor at Stanford University who is familiar with the research, the selection process arrived at a “narrow solution in terms of four discrete organs, but with fantastic diversity of organ numbers, shapes and colors that provide the defining phenotypes of each flowering plant species.” (ANI)

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How cocaine-linked genes enhance behavioural effects of addiction

May 14, 2009 By Leave a Comment

Washington, May 14 (ANI): Scientists from Mount Sinai School of Medicine have shed light on how cocaine-linked genes enhance behavioural effects of addiction – a find that will lead to new strategies for battling the habit.

The research team led by Dr Eric J. Nestler from the Department of Neuroscience at the Mount Sinai School of Medicine have provided fresh insights into the molecular pathways regulated by cocaine.

It is already known that addictive drugs induce persistent changes in the brain’s reward circuits.

Previous research has indicated that addiction to drugs such as cocaine is associated with altered gene expression in the nucleus accumbens (NAc), a region of the brain that is involved in motivation, pleasure, and reward.

“Although we have known for some time that changes in gene expression contribute to the long-lasting regulation of the brain’s reward circuitry that is seen during drug addiction, how those specific genes are regulated is not well understood,” said Nestler.

The research team studied the regulation of gene transcription in the mouse NAc, including regulation of chromatin structure, after repeated administration of cocaine.

The researchers also identified a previously unrecognized family of genes, called the sirtuins, as being involved in cocaine addiction in the NAc.

The study showed that chronic cocaine administration was linked with an increase in sirtuin gene transcription while increased sirtuin activity in NAc neurons was associated with a potentiation of the rewarding effects of cocaine.

The team suggests that inhibition of sirtuins in the NAc reduced the rewarding effects of cocaine and the motivation to self-administer the drug.

They identified the subset of genes that are highly likely to be targets of cocaine and shed light on the specific mechanisms that underlie cocaine-induced changes in the NAc.

“Our findings underscore the vast clinical potential of the many new gene targets identified in this study for the development of more effective treatments of cocaine and potentially other drug addictions,” said Nestler.

The study appears in the journal Neuron. (ANI)

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Past experiences do come in handy while making complex decisions

May 14, 2009 By Leave a Comment

Washington, May 14 (ANI): Past experiences do come in handy when people have to make complex decisions based on uncertain or confusing information, according to a study.

Funded by the Biotechnology and Biological Sciences Research Council (BBSRC), the study has shown that learning from experience actually changes the circuitry in the brain, and so a person can quickly categorise what he/she is seeing and make a decision or carry out appropriate actions.

“What we have found is that learning from past experience actually rewires our brains so that we can categorise the things we are looking at, and respond appropriately to them in any context,” said lead researcher Dr. Zoe Kourtzi, from the University of Birmingham.

“We have shown that this learning process is not just a matter of learning the structure of the physical world – when I look at something I’m not just playing a game of ‘snap’ in my head where I try to match images to each other. In fact, areas in our brains are actually trained to learn the rules that determine the way we interpret sensory information,” the researcher added.

Kourtzi’s team wanted to find out about the human brain mechanisms that mediate flexible decision making through learning, which have so far not been well understood, despite it being fairly clear that successful decisions benefit from previous experience.

The researchers combined measurements of behaviour and brain signals to study how volunteers learnt to discriminate between highly similar visual patterns and to assign them in different categories.

They used two different rules to assign visual patterns into categories, and, consequently, patterns belonging to the same category based on one of the rules could be members of different categories based on the alternate rule.

“This flexible learning paradigm allowed us to test for brain changes related to the perceived rather than the physical similarity between visual patterns. Our use of brain imaging in combination with mathematical techniques enabled us to extract sensitive information about brain signals that reflected the participant’s choice,” said Kourtzi.

“What we’ve shown is that we don’t just get better at the task of picking out a familiar face amongst a crowd, for example. Our results tell us that previous experience can train circuits in our brains to recognise perceived categories rather than simply the physical similarity between visual patterns.

“Based on what we found, we propose that learned information about categories is actually retained in brain circuits in the posterior areas of the brain. From there we think it is fed through to circuits in frontal areas that translate this information into flexible decisions and appropriate actions depending on the requirements and context of the task,” added Kourtzi.

Dr Janet Allen, Director of Research, BBSRC said: “We have to be able to understand how healthy brains work before we can see what has gone wrong when a person’s brain is affected by disease. This work also shows that the complex human brain has evolved an incredibly effective mechanism for making good decisions that lead to successful everyday actions – something that has surely been a significant evolutionary advantage.”

The study has been reported in the journal Neuron. (ANI)

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How ‘angel’ and ‘devil’ brain areas interact while exercising self-control

May 3, 2009 By Leave a Comment

Washington, May 1 (ANI): When on diet, skipping a favourite calorie-laden dessert can take a whole lot of self-control – an ability that comes easier to some people than others. Now, US scientists have identified an “angel” centre in the brain which holds back another “devil” area to stop individuals giving in to temptation.

Scientists from the California Institute of Technology (Caltech) have uncovered differences in the brains of people who are able to exercise self-control versus those who find it almost impossible.

The key in the research is, while everyone uses the same single area of the brain to make these sorts of value-laden decisions, a second brain region modulates the activity of the first region in people with good self-control, allowing them to weigh more abstract factors like healthiness – in addition to basic desires such as taste to make a better overall choice.

The study has been published in the May 1 issue of the journal Science.

“A very basic question in economics, psychology, and even religion, is why some people can exercise self-control but others cannot,” notes Antonio Rangel, a Caltech associate professor of economics and the paper’s principal investigator.

“From the perspective of modern neuroscience, the question becomes, ‘What is special about the circuitry of brains that can exercise good behavioral self-control?’ This paper studies this question in the context of dieting decisions and provides an important insight,” he added.

That insight was the result of an innovative experiment: A group of volunteers- all self-reported dieters- were shown photos of 50 foods, including everything from Snickers bars to Jello to cauliflower. The participants were asked to rate each of the foods based on how good they thought that food would taste. Afterwards, they were shown the same slides again and asked to rate each of the foods based on its supposed health benefits.

From those ratings, the researchers selected an “index food” for each volunteer – a food that fell about in the middle of the pack in terms of tastiness and supposed health benefits.

The participant was then shown the 50 items one final time and was asked to choose between it and the index item. (To keep the choosers “honest” without forcing them to eat 50 different foods in one sitting, the researchers would randomly select a number corresponding to one of the slides, and the participant would have to eat whichever food had been chosen at that point.)

All three viewings of the slides were done with the participant inside an MRI scanner, so that the blood-oxygen level dependent signal (a proxy for neuronal activity) in specific areas of the brain could be measured.

After all the choices had been made, the researchers were able to pick out 19 volunteers who showed a significant amount of dietary self-control in their choices, picking mostly healthy foods, regardless of taste. They were also able to identify 18 additional volunteers who showed very little self-control, picking what they believed to be the tastier food most of the time, regardless of its nutritional value.

When they looked at the brain scans of the participants, researchers found significant differences in the brain activity of the self-control group as compared to the non-self-controllers.

Earlier studies have shown that value-based decisions are reflected in the activity of a region in the brain called the ventromedial prefrontal cortex, or vmPFC.

If activity in the vmPFC goes down, explains Todd Hare, a postdoctoral scholar in neuroeconomics and the first author on the Science paper, “it means the person is probably going to say no to that item; if it goes up, they’re likely to choose that item.”

In the non-self-controllers, Rangel notes, the vmPFC seemed to only take the taste of the food into consideration in making a decision.

“In the case of good self-controllers, however, another area of the brain-called the dorsolateral prefrontal cortex [DLPFC]–becomes active, and modulates the basic value signals so that the self-controllers can also incorporate health considerations into their decisions,” he explains. (ANI)

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New technique shrinks size of circuitry used in nanotechnology devices

April 17, 2009 By Leave a Comment

Washington, April 17 (ANI): A University of Colorado at Boulder team, US, has developed a new method of shrinking the size of circuitry used in nanotechnology devices like computer chips and solar cells by using two separate colors of light.

Like current methods in the nanoengineering field, one color of light inscribes a pattern on a substrate, according to CU-Boulder Assistant Professor Robert McLeod of the electrical, computer and energy engineering department.

But, the new system developed by McLeod’s team uses a second color to “erase” the edges of the pattern, resulting in much smaller structures.

“The team used tightly focused beams of blue light to record lines and dots thousands of times smaller than the width of a human hair into patterned lithography on a substrate,” said McLeod.

The researchers then “chopped off the edges” of the lines using a halo of ultraviolet light, trimming the width of the lines significantly.

“We are essentially drawing a line with a marker on a nanotechnology scale and then erasing its edges,” said McLeod.

The method offers potential new approaches in the search for ways to shrink transistor circuitry, a process that drives the global electronic market that is pursuing smaller, more powerful microchips, he added.

For the project, McLeod and his team used a tabletop laser to project tightly focused beams of visible blue light onto liquid molecules known as monomers.

A chemical reaction initiated a bonding of the monomers into a plastic-like polymer solid.

If the beam was focused in one place, it inscribed a small solid dot. If the beam was moving the focus through the material, it created a thin thread, or line.

The researchers then added a second ultraviolet laser focused into a halo, or donut, which surrounded the blue light.

The special monomer formulation was designed to be inhibited by the UV light, shutting down its transformation from a liquid to a solid.

This “halo of inhibition” prevented the edges of the spot or line from developing, resulting in a much finer final structure.

According to McLeod, the new technology has the potential to lead to the construction of a variety of nanotechnology devices, including “nanomotors”.

“We now have a set of new tools. We believe this is a new way to do nanotechnology,” he said. (ANI)

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Praying to God is like conversing with a friend

April 13, 2009 By Leave a Comment

London, April 13 (ANI): Praying to God is like talking to a friend, according to a new study.

“It’s like talking to another human. We found no evidence of anything mystical,” New Scientist quoted Uffe Schjodt, of the University of Aarhus, Denmark, as saying.

For the study, Schjodt and colleagues asked volunteers to carry out two tasks involving both religious and ‘secular’ activities.

In the first task, they silently recited the Lord’s Prayer, then a nursery rhyme. Using MRI, the researchers found that identical brain areas, typically associated with rehearsal and repetition, were activated.

In the second, they improvised personal prayers before making requests to Santa Claus.

The researchers found that improvised prayers triggered patterns that match those seen when people communicate with each other, and activated circuitry that is linked with the theory of mind – an awareness that other individuals have their own independent motivations and intentions.

Two of the activated regions are thought to process desire and consider how another individual – in this case God – might react.

Also activated were part of the prefrontal cortex linked to the consideration of another person’s intentions, and an area thought to help access memories of previous encounters with that person.

The prefrontal cortex is key to theory of mind. Crucially, this area was inactive during the Santa Claus task, suggesting volunteers viewed Santa as fictitious but God as a real individual.

Previous studies have shown that the prefrontal cortex is not activated when people interact with inanimate objects, such as a computer game.

“The brain doesn’t activate these areas because they don’t expect reciprocity, nor find it necessary to think about the computer’s intentions,” said Schjodt.

He said that the results show people believe they are talking to someone when they pray.

The study appears in the journal of Social Cognitive and Affective Neuroscience. (ANI)

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Indian American leads project to make CFLs more efficient

April 9, 2009 By Leave a Comment

Toronto, April 8 (IANS) Compact fluorescent lightbulbs (CFLs) use just one-third of the energy that old incandescent bulbs use to provide the same amount of light. Now CFLs are going to be even more efficient, thanks to research being led by an Indian American scientist.

CFLs also last 1,000 times longer than incandescent bulbs. However, Queen’s University researchers addressed two problems with CFLs – they don’t work with dimmer switches, and their energy efficiency is compromised because of a problem known as poor power factor.

Actually only part of the energy a CFL consumes is used to power the bulb, resulting in wasted power.

‘Consumer-grade CFLs need to be compact and inexpensive. Until now, the complicated circuitry needed to power these bulbs most efficiently has been too large and too costly for consumer-grade compact fluorescents,’ said Praveen Jain, professor of electrical and computer engineering at Queen’s University.

‘In fact, when a CFL is used with a dimmer switch, its bulb can burn out sooner than expected.’

The solution emerged when John Lam, a doctoral candidate working with Jain, developed a compact, simplified circuitry and controller design that overcomes the power problem while also meeting consumers’ need for a dimmable, inexpensive CFL, according to a Queen’s release.

The two main challenges were making the technology directly replaceable with existing designs, and economical to produce, said Jain.

‘We were able to develop a more power-efficient, dimmable and cost-effective CFL technology that can truly replace the power-hungry incandescent light bulbs. This makes it very attractive to the consumer market,’ he added.

The Queen’s innovation is timely, Jain said, since widespread use of today’s less efficient CFLs would reduce expected benefits to the global power grid.

Many countries, including Australia and the European Union, have already begun phasing out incandescent bulbs in favour of the compact fluorescents.

The global market for compact fluorescents is estimated at $80 billion.

Jain did his degree in electrical engineering from Allahabad University in India in 1980, then his Master’s and PhD from the University of Toronto, Canada, in 1984 and 1987 respectively.

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How the brain processes important information

April 3, 2009 By Leave a Comment

Washington, April 3 (ANI): Scientists at UT Southwestern Medical Center have gained fresh insights into how the neurotransmitter dopamine, which is used by nerve cells to communicate with one another, helps brain cells to process important information.

Studying cells in mice, the researchers have found that this neurotransmitter causes certain brain cells to become more flexible, and changes brain-cell circuitry to process important information differently than mundane information.

“This can help one remember a new, important episode as distinct from any other episode, such as remembering where you parked your car today versus yesterday,” said Dr. Robert Greene, professor of psychiatry at UT Southwestern.

“If we can one day manipulate the way that salient information is processed, we might be able to not only improve learning, but also improve the learning needed to extinguish severe fear responsiveness, such as when a soldier can’t forget emotional war memories associated with post-traumatic stress disorder,” he said.

Given that conditions like addictions and schizophrenia are associated with alterations in dopamine in the brain, the researchers believe that their findings may one day prove helpful in dealing with them.

It is known that dopamine is released in the brain in association with experiencing “important” events and remembering salient acts, such as learning to avoid a hot stove or that a good grade is rewarded.

Dr. Greene said that the current study focused on how dopamine operates on the cells associated with this type of memory formation.

He and his colleagues isolated slices of the hippocampus region of the animals’ brains, and electrically stimulated the cells.

To simulate what happens in the brain in response to a memory-worthy event, they then exposed the cells to a selective dopamine-like neurotransmitter agent and repeated the stimulation.

When the researchers compared the effects of the stimulation with and without the dopamine agent, they identified changes in the responses of NMDA receptors, proteins that mediate synaptic plasticity when activated.

“The NMDA responses changed to increase the cells’ plasticity, and we think that this facilitates learning and memory,” Dr. Greene said.

Besides that, according to the researchers, the changes in NMDA responses to dopamine agents changed the functional circuitry of the cells, making the cells more responsive to electrical impulses coming from an indirect route through three processing “stations” before they reached the output region of the hippocampus.

Dr. Greene said that in the absence of dopamine, the cells tend to respond instead to impulses travelling by a route that is more direct and requires less processing.

Information sent by this direct route may reflect what is already known, and is less likely to change the animal’s behaviour.

“While the current study involved isolated mouse brain tissue containing the memory circuits, the human brain likely works the same way,” Dr. Greene said.

“You don’t want to have interference from yesterday. You need to know where you parked your car today, and dopamine may help to ensure that information from today will be remembered as distinct from yesterday,” he added.

He and his colleagues will net study how dopamine modulation affects learning and memory-related behaviour, and exactly how dopamine acts on cells and their circuits.

The current study has been published in the Journal of Neuroscience. (ANI)

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Electronic bendy displays may change the face of reading

April 2, 2009 By Leave a Comment

London, April 2 (ANI): If some companies have their way, reading would never be the same again, with Hitachi, Fujitsu and Hewlett-Packard racing to develop bigger e-paper devices that are flexible and can display colour and video.

According to a report in Nature News, the technology uses tiny capsules 0.1 millimeters wide that are filled with a non-conducting fluid that contains particles of positively charged white and negatively charged black pigments.

Applying a positive charge causes the black particles to move to the top of the capsule and the white ones to the bottom, so that the surface appears black.

A negative charge switches the surface back to white.

An added plus is that once the particles have migrated, they stay in place, so no electricity is needed to maintain the image – only to change it, such as when turning a page.

Combined with the lack of an energy-devouring backlight, e-paper is much easier on batteries than devices such that use typical liquid-crystal displays (LCDs), such as desktop computers and laptops.

To make sheets of e-paper, a thin-film of the capsules is then applied to a board that contains the circuitry needed to give the pixel pattern.

One of the leaders in making these circuit boards, which are called backplanes, is Plastic Logic, a spin-off from the University of Cambridge, UK.

The firm plans to start shipping an all-plastic flexible reader later this year, ramping up to mass commercial production in early 2010.

Its first flexible device, which uses a backplane of organic thin-film transistors, and E Ink’s e-paper, displays in black and white, but is magazine-size and weighs just 450 grams.

The firm expects to begin marketing colour versions in around three years.

The first commercial colour e-reader appeared in March, Fujitsu’s FLEPia reader. Rather than using e-ink, the device is based on the company’s cholesteric LCD technology, which like e-ink, doesn’t need power to maintain text or images.

A promising technology for improving colour displays is electrowetting, which has produced the brightest of all e-paper displays and seems to be the only e-paper technology with refresh rates that are fast enough to display video.

Whatever technologies prevail, magazine-sized monochrome displays will hit the shelves this year, followed by colour versions in 2-5 years, with video coming after that.

By then, e-paper displays will likely be everywhere, creating a multi-billion-dollar market from magazines and newspapers to advertising billboards, and that is likely to be just the start of a revolution in new media. (ANI)

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Evolution of fins and limbs linked with that of gills

March 24, 2009 By Leave a Comment

Washington, March 24 (ANI): A new research has suggested the genetic toolkit that animals use to build fins and limbs is the same genetic toolkit that controls the development of part of the gill skeleton in sharks.

The research was conducted by Andrew Gillis and Neil Shubin of the University of Chicago, and Randall Dahn of Mount Desert Island Biological Laboratory.

“In fact, the skeleton of any appendage off the body of an animal is probably patterned by the developmental genetic program that we have traced back to formation of gills in sharks,” said Andrew Gillis.

“We have pushed back the evolutionary origin of the developmental genetic program that patterns fins and limbs,” he added.

This new finding is consistent with an old theory, often discounted in science textbooks, that fins and (later) limbs evolved from the gills of an extinct vertebrate.

“A dearth of fossils prevents us from definitely concluding that fins evolved from gills. Nevertheless, this research shows that the genetic architecture of gills, fins and limbs is the same,” said Gillis.

The research builds on the breakthrough discovery of the fossil Tiktaalik, a “fish with legs,” by Neil Shubin and his colleagues in 2006.

“This is another example of how evolution uses common developmental programs to pattern different anatomical structures,” said Shubin, who is the Associate Dean of Organismal and Evolutionary Biology at the University of Chicago.

“In this case, shared developmental mechanisms pattern the skeletons of vertebrate gill arches and paired fins,” he added.

The research also showed for the first time that the gill arch skeleton of embryonic skates (a living relative of sharks that has gill rays) responds to treatment with the vitamin A derivative retinoic acid in the same way a limb or fin skeleton does, by making a mirror image duplicate of the structure as the embryo develops.

According to the researchers, the genetic circuitry that patterns paired appendages (arms, legs and fins) has a deep evolutionary origin that actually predates the origin of paired appendages themselves.

“These findings suggest that when paired appendages appeared, the mechanism used to pattern the skeleton was co-opted from the gills,” Gillis said.

“Perhaps we should think of shark gills as another type of vertebrate appendage-one that’s patterned in essentially the same way as fins and limbs,” he added. (ANI)

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New organic material may give Internet ‘superfast’ speeds

March 16, 2009 By Leave a Comment

London, March 16 (ANI): An International team of scientists have developed an organic material that may one day enable the Internet to work at “superfast” speeds.

Ivan Biaggio, an associate professor of physics at Lehigh University and member of the research team, says that the novel material has been developed with an unprecedented combination of high optical quality and strong ability to mediate light-light interaction.

He says that the integration of the novel material has been engineered with silicon technology so that it can be used in optical telecommunication devices.

He has revealed that the material is composed of small organic molecules with high non-linear optical susceptibilities.

It can cover the gap that separate silicon waveguides, which control the propagation of light beams on an integrated optical circuit.

“We have been able to make thin films by combining the molecules into a material that is perfectly transparent, flat, and free of any irregularities that would affect optical properties,” Nature magazine quoted Biaggio as saying.

The slot between the waveguides is the region where most of the light guided by the silicon propagates.

Biaggio and his colleagues say that by filling the slot, the molecules add an ultra-fast all-optical switching capability to silicon circuitry, creating a new ability to perform the light-to-light interactions necessary for data processing in all-optical networks.

A research article describing the material has been published in the journal Nature Photonics. (ANI)

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Boffins identify tiny brain area key to fear of rivals and predators

March 10, 2009 By Leave a Comment

Washington, Mar 10 (ANI): Researchers from University of Southern California have identified an area of hypothalamus in the brain, which is key to animals’ fear of territorial rivals and predators.

The team of neurologists led by Larry Swanson found that mice lose their fear of territorial rivals when a tiny piece of their brain is neutralized.

Brain’s amygdala region has long been studied by researchers as the region of fear. However, the new study has shown that primal fear responses do not depend on the amygdala, but on an obscure corner of the primeval brain.

During the study, the researchers examined the brain activity of rats and mice exposed to cats, or to rival rodents defending their territory.

They found that both experiences activated neurons in the dorsal premammillary nucleus, part of an ancient brain region called the hypothalamus.

For further analysis, the research team then made tiny lesions in the same area. Those rodents behaved far differently.

“These animals are not afraid of a predator,” Swanson said.

“It’s almost like they go up and shake hands with a predator.

“It’s amazing that these lesions appear to abolish innate fear responses.

“The same basic circuitry is found in primates and people that we find in rats and mice,” he added.

The study appears in Proceedings of the National Academy of Sciences. (ANI)

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