Olympus BioScapes Competition 2011 Winners: Incredible Microscopic Images Of The Natural World
|6:38:39 PM, Sunday, November 20, 2011|
"The Olympus BioScapes competition has produced some of the world's most stunning microscopic digital images and videos of life science.
Now in its eighth year running, the winning entry is a photograph by Charles Krebs of Issaquah, Washington showing an underwater Rotifer Floscularia that relies on rapidly beating cilia to bring food-laden water in so it can feed.
From live green brain coral captured underwater to stink bug eggs snapped in Greece, you'll see some breathtaking photos of nature at its most beautiful.
Other images not to be missed include the reproductive system of a fruit fly and the golden chloroplasts in a living diatom..."
Scientists Create Light from Vacuum
|5:38:31 PM, Sunday, November 20, 2011|
"Scientists at Chalmers University of Technology have succeeded in creating light from vacuum - observing an effect first predicted over 40 years ago. The results will be published tomorrow (Wednesday) in the journal Nature. In an innovative experiment, the scientists have managed to capture some of the photons that are constantly appearing and disappearing in the vacuum.
The experiment is based on one of the most counterintuitive, yet, one of the most important principles in quantum mechanics: that vacuum is by no means empty nothingness. In fact, the vacuum is full of various particles that are continuously fluctuating in and out of existence. They appear, exist for a brief moment and then disappear again. Since their existence is so fleeting, they are usually referred to as virtual particles.
Chalmers scientist, Christopher Wilson and his co-workers have succeeded in getting photons to leave their virtual state and become real photons, i.e. measurable light. The physicist Moore predicted way back in 1970 that this should happen if the virtual photons are allowed to bounce off a mirror that is moving at a speed that is almost as high as the speed of light. The phenomenon, known as the dynamical Casimir effect, has now been observed for the first time in a brilliant experiment conducted by the Chalmers scientists.
"Since it's not possible to get a mirror to move fast enough, we've developed another method for achieving the same effect," explains Per Delsing, Professor of Experimental Physics at Chalmers. "Instead of varying the physical distance to a mirror, we've varied the electrical distance to an electrical short circuit that acts as a mirror for microwaves.
The "mirror" consists of a quantum electronic component referred to as a SQUID (Superconducting quantum interference device), which is extremely sensitive to magnetic fields. By changing the direction of the magnetic field several billions of times a second the scientists were able to make the "mirror" vibrate at a speed of up to 25 percent of the speed of light.
"The result was that photons appeared in pairs from the vacuum, which we were able to measure in the form of microwave radiation," says Per Delsing. "We were also able to establish that the radiation had precisely the same properties that quantum theory says it should have when photons appear in pairs in this way."
What happens during the experiment is that the "mirror" transfers some of its kinetic energy to virtual photons, which helps them to materialise. According to quantum mechanics, there are many different types of virtual particles in vacuum, as mentioned earlier. Goran Johansson, Associate Professor of Theoretical Physics, explains that the reason why photons appear in the experiment is that they lack mass.
"Relatively little energy is therefore required in order to excite them out of their virtual state. In principle, one could also create other particles from vacuum, such as electrons or protons, but that would require a lot more energy."
The scientists find the photons that appear in pairs in the experiment interesting to study in closer detail. They can perhaps be of use in the research field of quantum information, which includes the development of quantum computers.
However, the main value of the experiment is that it increases our understanding of basic physical concepts, such as vacuum fluctuations - the constant appearance and disappearance of virtual particles in vacuum. It is believed that vacuum fluctuations may have a connection with "dark energy" which drives the accelerated expansion of the universe. The discovery of this acceleration was recognized this year with the awarding of the Nobel Prize in Physics."
NASA Probe Data Show Evidence of Liquid Water on Icy Europa
|5:32:59 PM, Wednesday, November 16, 2011|
“Data from a NASA planetary mission have provided scientists evidence of what appears to be a body of liquid water, equal in volume to the North American Great Lakes, beneath the icy surface of Jupiter's moon, Europa. The data suggest there is significant exchange between Europa's icy shell and the ocean beneath. This information could bolster arguments that Europa's global subsurface ocean represents a potential habitat for life elsewhere in our solar system. The findings are published in the scientific journal Nature. "The data opens up some compelling possibilities," said Mary Voytek, director of NASA's Astrobiology Program at agency headquarters in Washington. "However, scientists worldwide will want to take a close look at this analysis and review the data before we can fully appreciate the implication of these results." NASA's Galileo spacecraft, launched by the space shuttle Atlantis in 1989 to Jupiter, produced numerous discoveries and provided scientists decades of data to analyze. Galileo studied Jupiter, which is the most massive planet in the solar system, and some of its many moons. One of the most significant discoveries was the inference of a global salt water ocean below the surface of Europa. This ocean is deep enough to cover the whole surface of Europa and contains more liquid water than all of Earth's oceans combined. However, being far from the sun, the ocean surface is completely frozen. Most scientists think this ice crust is tens of miles thick. "One opinion in the scientific community has been if the ice shell is thick, that's bad for biology. That might mean the surface isn't communicating with the underlying ocean," said Britney Schmidt, lead author of the paper and postdoctoral fellow at the Institute for Geophysics, University of Texas at Austin. "Now, we see evidence that it's a thick ice shell that can mix vigorously and new evidence for giant shallow lakes. That could make Europa and its ocean more habitable." Schmidt and her team focused on Galileo images of two roughly circular, bumpy features on Europa's surface called chaos terrains. Based on similar processes seen on Earth -- on ice shelves and under glaciers overlaying volcanoes -- they developed a four-step model to explain how the features form. The model resolves several conflicting observations. Some seemed to suggest the ice shell is thick. Others suggest it is thin. This recent analysis shows the chaos features on Europa's surface may be formed by mechanisms that involve significant exchange between the icy shell and the underlying lake. This provides a mechanism or model for transferring nutrients and energy between the surface and the vast global ocean already inferred to exist below the thick ice shell. This is thought to increase the potential for life there. The study authors have good reason to believe their model is correct, based on observations of Europa from Galileo and of Earth. Still, because the inferred lakes are several miles below the surface, the only true confirmation of their presence would come from a future spacecraft mission designed to probe the ice shell. Such a mission was rated as the second highest priority flagship mission by the National Research Council's recent Planetary Science Decadal Survey and is being studied by NASA. "This new understanding of processes on Europa would not have been possible without the foundation of the last 20 years of observations over Earth's ice sheets and floating ice shelves," said Don Blankenship, a co-author and senior research scientist at the Institute for Geophysics, where he leads airborne radar studies of the planet's ice sheets. Galileo was the first spacecraft to directly measure Jupiter's atmosphere with a probe and conduct long-term observations of the Jovian system. The probe was the first to fly by an asteroid and discover the moon of an asteroid. NASA extended the mission three times to take advantage of Galileo's unique science capabilities, and it was put on a collision course into Jupiter's atmosphere in September 2003 to eliminate any chance of impacting Europa. The Galileo mission was managed by NASA's Jet Propulsion Laboratory in Pasadena, Calif., for the agency's Science Mission Directorate.”
Transporter 5: Solving an Ancient Mystery of the Cell
|9:04:27 PM, Tuesday, November 15, 2011|
“The discovery by scientists in Cambridge and Alberta of a fifth adaptor protein – a tiny and vital component of many cells –will lay the foundations for a greater understanding of genetic disorders.
The people who work there call it the Titanic. The Cambridge Institute for Medical Research, a shiny building with funnel-like air vents on the Addenbrooke’s complex, is the workplace of around 250 scientists, many of them internationally acclaimed in their fields. Its 40 research groups are dedicated to advancing the basic and clinical science that is needed to understand the molecular mechanisms of disease. It is in these laboratories that some of the foundational research takes place that will pave the way for the development of drugs and therapies that will save lives in the future.
Earlier this year one of these groups – a team of seven scientists led by eminent cell biologist Professor Margaret Robinson – made a discovery that will lead to some of the key information contained in cell biology textbooks being revised. Working with colleagues at the University of Alberta in Canada, the team showed that the cells of all eukaryotes (a term used to describe the cell structure of animals, plants and fungi) contain five adaptor protein complexes (APs). This finding confounds existing assumptions that only four APs are present in cells – and will help scientists learn more about, and ultimately treat, certain genetic disorders.
Scientists have known about the existence of APs – which are vital to the functions of cells – ever since the late 1970s. Four APs were identified by researchers in the space of some 20 years. “As recently as 2004 I was quoted in the scientific literature stating categorically that there were no more than four APs,” says Professor Robinson. “It just goes to show that you can’t be too certain that you’ve found everything there is to find. And even more importantly it illustrates just how vital it is to carry out fundamental research, to provide the knowledge needed to feed into the translational research that could ultimately lead to cures for diseases.”
Cells are often described as the building blocks of life. As every school child is taught, cells have a nucleus, a surrounding membrane and cytoplasm. The intricate workings of the cell, however, are much more complex and represent a fascinating puzzle for biologists. Cells are full of compartments, visible only through the most powerful microscopes. These compartments do not exist in isolation but communicate with each other – for example, to send newly-made molecules from the place where they are manufactured to the place where they need to be in order to function.
Tiny spherical vesicles transport proteins and other molecules around the cell in a process that scientists call trafficking. But in order for the different compartments not to get mixed up, the cell needs to put some molecules into vesicles as cargo to be delivered to a new compartment, while leaving others behind. The machinery that selects which molecules will go into the vesicles includes the adaptor proteins. The word adaptor is used to describe their ability to connect two different types of molecules together: the cargo and the structural proteins that physically form the vesicle.
The way in which adaptor proteins pick up molecules from compartments can be likened to diners in a sushi bar, picking up dishes of food from a passing conveyor belt avoiding items they dislike and opting for those they desire. “APs have different ways of recognising molecules. It’s a process that we are only just beginning to understand, but this fundamental research could impact on the study of diseases where certain molecules fail to get trafficked correctly,” says Dr. Jennifer Hirst, who is a senior researcher in the Robinson lab and has discovered and characterised a number of new adaptors…”
Mimicking the Brain -- In Silicon: New Computer Chip Models How Neurons Communicate With Each Other at Synapses
|8:58:20 PM, Tuesday, November 15, 2011|
“For decades, scientists have dreamed of building computer systems that could replicate the human brain's talent for learning new tasks.
MIT researchers have now taken a major step toward that goal by designing a computer chip that mimics how the brain's neurons adapt in response to new information. This phenomenon, known as plasticity, is believed to underlie many brain functions, including learning and memory.
With about 400 transistors, the silicon chip can simulate the activity of a single brain synapse -- a connection between two neurons that allows information to flow from one to the other. The researchers anticipate this chip will help neuroscientists learn much more about how the brain works, and could also be used in neural prosthetic devices such as artificial retinas, says Chi-Sang Poon, a principal research scientist in the Harvard-MIT Division of Health Sciences and Technology.
Poon is the senior author of a paper describing the chip in the Proceedings of the National Academy of Sciences the week of Nov. 14. Guy Rachmuth, a former postdoc in Poon's lab, is lead author of the paper. Other authors are Mark Bear, the Picower Professor of Neuroscience at MIT, and Harel Shouval of the University of Texas Medical School.
There are about 100 billion neurons in the brain, each of which forms synapses with many other neurons. A synapse is the gap between two neurons (known as the presynaptic and postsynaptic neurons). The presynaptic neuron releases neurotransmitters, such as glutamate and GABA, which bind to receptors on the postsynaptic cell membrane, activating ion channels. Opening and closing those channels changes the cell's electrical potential. If the potential changes dramatically enough, the cell fires an electrical impulse called an action potential.
All of this synaptic activity depends on the ion channels, which control the flow of charged atoms such as sodium, potassium and calcium. Those channels are also key to two processes known as long-term potentiation (LTP) and long-term depression (LTD), which strengthen and weaken synapses, respectively.
The MIT researchers designed their computer chip so that the transistors could mimic the activity of different ion channels. While most chips operate in a binary, on/off mode, current flows through the transistors on the new brain chip in analog, not digital, fashion. A gradient of electrical potential drives current to flow through the transistors just as ions flow through ion channels in a cell.
"We can tweak the parameters of the circuit to match specific ion channels," Poon says. "We now have a way to capture each and every ionic process that's going on in a neuron."
Previously, researchers had built circuits that could simulate the firing of an action potential, but not all of the circumstances that produce the potentials. "If you really want to mimic brain function realistically, you have to do more than just spiking. You have to capture the intracellular processes that are ion channel-based," Poon says.
The new chip represents a "significant advance in the efforts to incorporate what we know about the biology of neurons and synaptic plasticity onto CMOS [complementary metal-oxide-semiconductor] chips," says Dean Buonomano, a professor of neurobiology at the University of California at Los Angeles, adding that "the level of biological realism is impressive.
The MIT researchers plan to use their chip to build systems to model specific neural functions, such as the visual processing system. Such systems could be much faster than digital computers. Even on high-capacity computer systems, it takes hours or days to simulate a simple brain circuit. With the analog chip system, the simulation is even faster than the biological system itself.
Another potential application is building chips that can interface with biological systems. This could be useful in enabling communication between neural prosthetic devices such as artificial retinas and the brain. Further down the road, these chips could also become building blocks for artificial intelligence devices, Poon says….”
Dewayne Dedmon's Leap Of Faith: Discouraged for Religious Reasons from Playing Basketball
|1:59:36 AM, Friday, November 11, 2011|
"Thou wilt show me the path of life.
Dieter Horton first caught sight of the skinny kid with the long arms one afternoon in April 2008. The boy was sitting in the first row of the bleachers in the small gym at Antelope Valley College, waiting silently, his knees together. Only when he stood up, 30 minutes later, did Horton realize just how tall he was. At least 6'8", Horton thought. Then he looked closer: Who the hell is this kid?
After all, AVC is located in Lancaster, Calif., in the heart of the Antelope Valley, only an hour's drive north of Los Angeles over the San Gabriel Mountains but in a world of its own. If there was a teenager within a nose of 6'6" in the valley, Horton could tell you his home address, his girlfriend's name and what he liked on his pizza. In 11 years as a junior college basketball coach in California, Horton had won a state title, sent nearly 20 kids to Division I schools and set a state juco record by finishing 37--0 at Fullerton College in 2005--06. Young, ambitious and handsome in a clean-cut way, Horton scouted so relentlessly that his phys-ed students had grown accustomed to his teaching with a cellphone pressed to his ear. Yet here was a towering kid unfamiliar to the coach from local high schools or the AAU circuit or even city rec leagues.
When Horton finished talking with one of his players, the boy walked over. He wore an enormous pair of beat-up hightops, ratty shorts and a white T-shirt so large it looked like a muumuu. He hunched over, as if trying to shrink to standard proportions. "Coach," he said, "my name is Dewayne Dedmon. I want to play basketball."
Instantly Horton recognized the name. For years stories had floated around the valley about a tall kid who wasn't allowed to play basketball, but the coach had never believed them. He heard lots of stories. Most came from the kids themselves. Every year dozens of cocky teenagers approached Horton and assured him they'd score 20 a game if only he'd give them a uniform and the rock. To weed out the dreamers and boasters, he told them, "Come back next week." Only one in 10 ever did.
"O.K., Dewayne Dedmon, how about we see what you got," Horton said. "Show up next Tuesday at 3 p.m., and we'll work you out."
Dedmon nodded. "Yes, sir," he said. "I'll see you then."
Within a few days, Horton had forgotten all about him.
Gail Lewis was so proud she felt like crying. She stared at the letters on the notepaper stuck to the wall and read along. She knew the line, from Proverbs. Then she looked down at her nine-year-old son, sitting on his bed in their sparsely furnished three-bedroom apartment in Lancaster. Here he was, only halfway grown up and already disciplining himself..."
How the Potato Changed the World
|1:46:32 AM, Friday, November 11, 2011|
"When potato plants bloom, they send up five-lobed flowers that spangle fields like fat purple stars. By some accounts, Marie Antoinette liked the blossoms so much that she put them in her hair. Her husband, Louis XVI, put one in his buttonhole, inspiring a brief vogue in which the French aristocracy swanned around with potato plants on their clothes. The flowers were part of an attempt to persuade French farmers to plant and French diners to eat this strange new species.
Today the potato is the fifth most important crop worldwide, after wheat, corn, rice and sugar cane. But in the 18th century the tuber was a startling novelty, frightening to some, bewildering to others—part of a global ecological convulsion set off by Christopher Columbus.
About 250 million years ago, the world consisted of a single giant landmass now known as Pangaea. Geological forces broke Pangaea apart, creating the continents and hemispheres familiar today. Over the eons, the separate corners of the earth developed wildly different suites of plants and animals. Columbus’ voyages reknit the seams of Pangaea, to borrow a phrase from Alfred W. Crosby, the historian who first described this process. In what Crosby called the Columbian Exchange, the world’s long-separate ecosystems abruptly collided and mixed in a biological bedlam that underlies much of the history we learn in school. The potato flower in Louis XVI’s buttonhole, a species that had crossed the Atlantic from Peru, was both an emblem of the Columbian Exchange and one of its most important aspects.
Compared with grains, tubers are inherently more productive. If the head of a wheat or rice plant grows too big, the plant will fall over, with fatal results. Growing underground, tubers are not limited by the rest of the plant. In 2008 a Lebanese farmer dug up a potato that weighed nearly 25 pounds. It was bigger than his head.
Many researchers believe that the potato’s arrival in northern Europe spelled an end to famine there. (Corn, another American crop, played a similar but smaller role in southern Europe.) More than that, as the historian William H. McNeill has argued, the potato led to empire: “By feeding rapidly growing populations, [it] permitted a handful of European nations to assert dominion over most of the world between 1750 and 1950.” The potato, in other words, fueled the rise of the West.
Equally important, the European and North American adoption of the potato set the template for modern agriculture—the so-called agro-industrial complex. Not only did the Columbian Exchange carry the potato across the Atlantic, it also brought the world’s first intensive fertilizer: Peruvian guano. And when potatoes fell to the attack of another import, the Colorado potato beetle, panicked farmers turned to the first artificial pesticide: a form of arsenic. Competition to produce ever-more-potent arsenic blends launched the modern pesticide industry. In the 1940s and 1950s, improved crops, high-intensity fertilizers and chemical pesticides created the Green Revolution, the explosion of agricultural productivity that transformed farms from Illinois to Indonesia—and set off a political argument about the food supply that grows more intense by the day..."
Poland's Mysterious Crooked Forest
|1:31:06 AM, Friday, November 11, 2011|
"In a tiny corner of western Poland a forest of about 400 pine trees grow with a 90 degree bend at the base of their trunks - all bent northward. Surrounded by a larger forest of straight growing pine trees this collection of curved trees, or "Crooked Forest," is a mystery.
Planted around 1930, the trees managed to grow for seven to 10 years before getting held down, in what is understood to have been human mechanical intervention. Though why exactly the original tree farmers wanted so many crooked trees is unknown."
Russia Races to Rescue Mars Probe From Earth Orbit
|1:19:59 AM, Friday, November 11, 2011|
"MOSCOW (AP) — A Russian spacecraft on its way to Mars with 12 tons of toxic fuel is stuck circling the wrong planet: ours. And it could come crashing back to Earth in a couple of weeks if engineers can't coax it back on track.
Space experts were hopeful Wednesday that the space probe's silent engines can be fired to send it off to Mars. If not, it will plummet to Earth. But most U.S. space debris experts think the fuel on board would explode harmlessly in the upper atmosphere and never reach the ground.
The launch mishap was the latest in a series of recent Russian failures that have raised concerns about the condition of the country's space industries.
The unmanned $170 million Phobos-Ground craft successfully got into orbit, propelled off the ground by a Zenit-2 booster rocket just after midnight Moscow time Wednesday (2016 GMT Tuesday) from the Baikonur cosmodrome in Kazakhstan. After separating from its booster, 11 minutes later, it was supposed to fire its engines twice and head to Mars.
Neither engine fired. So the spacecraft couldn't leave Earth's orbit, flying between 129 and 212 miles above Earth. And that orbit is already deteriorating, according to American satellite tracking.
The Federal Space Agency said the probe's orbit and its power sources could allow it to circle the Earth for about two weeks. That jibes with calculations made by NASA.
"From the orbits we're seeing from the U.S. Space Surveillance Network, it's going to be a couple weeks before it comes in," NASA chief debris scientist Nicholas Johnson said Wednesday afternoon. "It's not going to be that immediate."
The craft was aiming to get ground samples from Phobos, one of Mars' two moons, and return them in a daring expedition hailed by eager scientists, who said it may include bits of Mars that may have been trapped on its moon.
Federal Space Agency chief Vladimir Popovkin said the system that keeps the spacecraft pointed in the right direction may have failed. The Russian rescue effort was being hampered by a limited earth-to-space communications network. Even before the problem, flight controllers were forced to ask people in South America to scan the sky to see if the engines on the spacecraft fired.
Amateur astronomers were the first to spot the trouble when they detected the craft was stuck in an Earth orbit.
As time went on Wednesday, experts in the United States became more confident that the Russians could still get the probe going, just a day or two later than planned. There were no sightings of an explosion or partial rocket firings, which are good signs, said James Oberg, a NASA veteran who has written books on the Russian space program and who now works as a space consultant.
"I am growing more confident as we realize that the vehicle is healthy; it didn't blow up," Oberg said late Wednesday afternoon. "They have a chance of doing a Hubble repair, an Apollo 13, snatching victory out of jaws of defeat kind of thing."
The hope is that this is just a software problem that can be fixed and uploaded to the probe, said Bruce Betts, program director of the Planetary Society in the United States, a group that has a $500,000 experiment on board.
"There's a major problem, but it might be recoverable," Betts said. "The game's not over yet."
The spacecraft is 13.2 metric tons (14.6 tons). Russian data shows that most of that weight — about 11 metric tons (12 tons) — is fuel, NASA's Johnson said..."
Why Are There So Many Colors of Poisonous Frogs?
|1:04:59 AM, Friday, November 11, 2011|
"Hopping around in the Peruvian jungle, near the border with Brazil, is a menagerie of tiny poison dart frogs. Their wealth of colors and patterns—some have golden heads atop white-swirled bodies, others wear full-torso tattoos of black and neon-yellow stripes—act as the world's worst advertisement to predators: Don't eat me, I'm toxic. But why have so many designs evolved when a single one might do?
Evolutionary biologist Mathieu Chouteau of the University of Montreal in Canada ventured into the rainforest to find out. He was on the trail of Ranitomeya imitator, a single species of poison dart frog that comes in about 10 different patterns. That variability should be confusing for predators, he says, because the warnings are supposed to be a message to them, and it would make more sense to give them only one design to keep track of.
To figure out what was going on, Chouteau enlisted his girlfriend's help to make 3600 models of frogs, each 18 millimeters long. "It was, like, at least a month of working full-time," he says. They pressed black clay into frog-shaped molds and painted each one in one of two patterns: yellow striped or reticulated, like a giraffe, with green lines. They also made brown frogs as a nontoxic-looking control. Then Chouteau packed the frogs in his carryon baggage and flew to Peru.
The models represent the frogs that live in two different sites: one in the Amazonian lowland and one in a valley at about 500 meters above sea level. The two sites are separated by a high ridge. In one very long day at each site, Chouteau set out 900 of the frogs on leaves along narrow trails used by locals to hunt in the forest. For the next 3 days, he went back and checked them to see whether the soft clay recorded evidence of attacks by birds.
Birds mostly avoided the model that looked like the local frog, but they attacked the model that looked like the frog from the other site, Chouteau reports in the December issue of The American Naturalist. In the high valley, the land of the reticulated frogs, only 7.2% of the model frogs with the reticulated pattern were attacked, whereas 14.2% of the brown models and 26.6% of the yellow-striped models were attacked. The pattern was roughly reversed at the other site.
And that helps explain the diversity of frogs in the rainforest, Chouteau says. Different frog patterns rule at different sites, and birds keep these designs going by weeding out any frogs that deviate from the norm.
"This study shows quite nicely how, once you've got the diversity, it's stabilized," says Chris Jiggins, an evolutionary biologist at the University of Cambridge in the United Kingdom. But where the diversity comes from, he says, is "a bit of an outstanding question." It's possible that frogs with a particular pattern are somehow better suited to the environment where they live, but he thinks the differences more likely arise because of drift. Random changes in pattern get established and then keep evolving, making the frogs distinctive. "What's actually kind of surprising is the birds are really going for these frogs," he says. "You'd think, these frogs are so nasty, you wouldn't go anywhere near a poison dart frog." Maybe the rainforest is so diverse that it's always worth trying something, even something brightly colored."
Russian 'Grave Robber Made Dolls From Girls' Corpses'
|12:50:55 AM, Friday, November 11, 2011|
"A suspected grave robber in the central Russian city of Nizhny Novgorod is said by police to have made 29 life-size dolls from mummified female corpses.
Local historian and cemetery explorer Anatoly Moskvin, 45, was arrested last week by police investigating a spate of grave desecrations in the area.
The brightly dressed dolls, their faces and limbs covered in cloth, were found in his flat and garage, police said.
It was not clear whether each doll contained a set of human remains.
Police are now trying to establish the identity of the mummified remains.
They said they had been investigating "numerous" grave desecrations in cemeteries in and around Nizhny Novgorod since last year.
Video released by police on their website shows the dolls seated on shelves or sofas, in small rooms stacked with books and papers.
No actual bones are apparent in the footage and some of the faces are covered by masks.
Officials said the remains belonged mainly to girls or young women, and they had been dressed in clothes taken from corpses.
Also found in Mr Moskvin's flat were photographs and nameplates taken from headstones as well as instructions for making dolls and maps of cemeteries in the region, a police statement said.
Shoes found in the flat matched footprints found in cemeteries, it added.
Some Russian media are reporting that Muslim graves were singled out in the robberies.
According to the police statement, Mr Moskvin is "well-known in academic circles" having studied Celtic culture at a leading Russian university, and is the author of many books and academic works.
He is described in Russian media reports as a "necropolist", or cemetery expert.
Police did not say how he had been arrested and Russian newspapers report variously that he was caught with a bag of bones or that detectives grew suspicious when they consulted him, as a cemetery expert, about the desecrations.
Alexei Yesin, editor of a local newspaper to which Mr Moskvin contributed, told the Associated Press news agency he was a loner who had "certain quirks" but said he had given no indication that he was up to anything so strange.
"I saw no signs of that while working with him," Mr Yesin said.
In a 2007 interview with the newspaper Nizhegorodsky Rabochy, Mr Moskvin said he had begun wandering through cemeteries when still a schoolboy..."
Tardigrades: Water Bears in Space
|12:05:34 AM, Wednesday, November 09, 2011|
"In 2007, a little known creature called a tardigrade became the first animal to survive exposure to space.
It prevailed over sub-zero temperatures, unrelenting solar winds and an oxygen-deprived space vacuum.
On Monday, this microscopic cosmonaut has once again hitched a ride into space on the Nasa shuttle Endeavour.
Its mission: to help scientists understand more about how this so-called "hardiest animal on Earth" can survive for short periods off it.
Tardigrades join other microscopic organisms selected to be part of a project into extreme survival.
Project Biokis is sponsored by the Italian Space Agency and will investigate the impact of short-duration spaceflight on a number of microscopic organisms.
The project will use seven experiments to investigate how spaceflight affects organisms on a molecular level.
The team will be using molecular biology to evaluate any changes in the organisms' genetic information, as well as investigating how cells physically adapt to cope with extreme dehydration, caused by the space vacuum, and damage caused by cosmic radiation.
One of these experiments, the Tardkiss experiment, will expose colonies of tardigrade to different levels of ionising radiation, determined using an instrument called a dosimeter, at different points during the spaceflight mission.
The results from Tardkiss will enable researchers to determine how radiation dosage effects the way cells work.
Tardigrades are of particular interest following the 2007 European Space Agency (Esa) Foton-M3 mission, during which their ability to survive space conditions was discovered.
Tardigrades are microscopic animals more commonly known by their non-scientific name, the water bear.
Their stocky bodies and gait have all the hallmarks of a bear. But this isn't a typical bear encounter.
These bears are less than 1mm long and are found in the sea, in fresh water and on land.
Genetic studies have shown that they originally lived in freshwater environments before adapting to colonise the land, seeking out moist habitats such as soil, mosses, leaf litter and lichen.
Tardigrades earned the "hardiest animal on earth" tag having evolved elaborate dormancy strategies that allow them to shut down all but the essential biological processes when conditions are not conducive to supporting life.
Professor Roberto Guidetti from the University of Modena and Reggio Emilia believes their ability to suspend life and withstand freezing and desiccation may explain why they can survive in space.
"Tardigrades can be found all over the world from the Arctic to the Antarctic, from high mountains to deserts, in urban areas and backyard gardens," he explained.
"In terrestrial environments, they always require at least a film of water surrounding their bodies to perform activities necessary for life."
But if these conditions change, tardigrades are capable of entering an extreme form of resting called cryptobiosis.
In this state, they are capable of withstanding freezing, a process called cryobiosis, and desiccation, a process called anhydrobiosis..."
-- Not exactly news, but unless you keep up with stuff like this, you likely have not heard of it.
Cloud-Powered Facial Recognition Is Terrifying
|5:43:16 PM, Friday, November 04, 2011|
""I never forget a face," goes the Marx Brothers one-liner, "but in your case, I'll be glad to make an exception."
Unlike Groucho Marx, unfortunately, the cloud never forgets. That's the logic behind a new application developed by Carnegie Mellon University's Heinz College that's designed to take a photograph of a total stranger and, using the facial recognition software PittPatt, track down their real identity in a matter of minutes. Facial recognition isn't that new -- the rudimentary technology has been around since the late 1960s -- but this system is faster, more efficient, and more thorough than any other system ever used. Why? Because it's powered by the cloud.
The logic of the new application is based on a series of studies designed to test the integration between facial recognition technology and the wealth of data accessible in the cloud (by which we basically mean the Internet). Facial recognition's law enforcement uses -- to identify criminals out of a surveillance video tape, say -- have always been limited by the criminal databases available for reference. When Florida deployed Viisage facial recognition software in January 2001 to search for potential troublemakers and terrorists in attendance at Super Bowl XXXV, police in Tampa Bay were only able to extract useful information on 19 people with minor criminal records who already existed in any database they had access to. But the Internet was a much smaller place in 2001; Google was in its infancy, and the sheer volume of data available in a simple search simply didn't exist.
Often, the problems with facial recognition are rooted in the need for greater processing power, human and machine. After revelers rioted in the streets of Vancouver following the Canucks' defeat in the Stanley Cup, Vancouver police received nearly 1,600 hours of footage from bystanders furious with their fellow citizens; the department was woefully inequipped to handle the sudden influx of data, anticipating that it would take nearly two years to analyze all the information. Vancouver's Digital Multimedia Evidence Processing Lab was able to cut the processing time to a mere three weeks with a relatively small 20-workstation lab.
With Carnegie Mellon's cloud-centric new mobile app, the process of matching a casual snapshot with a person's online identity takes less than a minute. Tools like PittPatt and other cloud-based facial recognition services rely on finding publicly available pictures of you online, whether it's a profile image for social networks like Facebook and Google Plus or from something more official from a company website or a college athletic portrait. In their most recent round of facial recognition studies, researchers at Carnegie Mellon were able to not only match unidentified profile photos from a dating website (where the vast majority of users operate pseudonymously) with positively identified Facebook photos, but also match pedestrians on a North American college campus with their online identities.
The repercussions of these studies go far beyond putting a name with a face; researchers Alessandro Acquisti, Ralph Gross, and Fred Stutzman anticipate that such technology represents a leap forward in the convergence of offline and online data and an advancement of the "augmented reality" of complementary lives. With the use of publicly available Web 2.0 data, the researchers can potentially go from a snapshot to a Social Security number in a matter of minutes:
We use the term augmented reality in a slightly extended sense, to refer to the merging of online and offline data that new technologies make possible. If an individual's face in the street can be identified using a face recognizer and identified images from social network sites such as Facebook or LinkedIn, then it becomes possible not just to identify that individual, but also to infer additional, and more sensitive, information about her, once her name has been (probabilistically) inferred.
In our third experiment, as a proof-of-concept, we predicted the interests and Social Security numbers of some of the participants in the second experiment. We did so by combining face recognition with the algorithms we developed in 2009 to predict SSNs from public data. SSNs were nothing more than one example of what is possible to predict about a person: conceptually, the goal of Experiment 3 was to show that it is possible to start from an anonymous face in the street, and end up with very sensitive information about that person, in a process of data "accretion." In the context of our experiment, it is this blending of online and offline data - made possible by the convergence of face recognition, social networks, data mining, and cloud computing - that we refer to as augmented reality.
Naturally, the development of such software inspires understandably Orwellian concerns. Jason Mick at DailyTech notes that PittPatt started as a Carnegie Mellon University research project, which spun off into a company post 9/11. "At the time, U.S. intelligence was obsessed with using advanced facial recognition to identify terrorists," writes Mick. "So the Defense Advanced Research Projects Agency (DARPA) poured millions into PittPatt." While Google purchased the company in July, the potential for such intrusive technology to be used against law-abiding citizens is cause for concern..."
The Navy Deploys An Underwater Roomba To Keep Its Fleet Shipshape
|5:05:22 PM, Friday, November 04, 2011|
"The Hull Bug, inspired by hermit crabs, will swim alongside warships and keep their hulls sparkling clean.
Barnacles. They may look innocuous when you see them on the undersides of breaching whales, but they increase drag on the underside of a ship significantly, reducing its speed by up to 10 percent and increasing fuel consumption by up to 40 percent.
For the Navy, which spends a lot of time and fuel sailing ships, this is a problem. In fact, the Navy is forced to spend $1 billion a year on extra fuel and the cleaning of its ships.
So it's developing an autonomous robot inspired by the grooming behavior of sea creatures (PDF), and it's currently undergoing tests by the Office of Naval Research for deployment in 2015 across the U.S. Navy's fleet. The robot, which is something like an underwater Roomba, is described as a "robotic hull biomimetic underwater grooming," or Hull Bug.
In general, "fouling" of ships affects the world's entire fleet of ships, and is a major drag-- literally!--on the fuel efficiency of vessels of every size. Traditional approaches to keeping barnacles and other "biofilms," or collections of living gunk, off ships and submarines involve toxic paints laced with large amounts of copper. Not only do these paints pollute the harbors where ships spend most of their time, they're a headache to dispose of when dry-docked vessels are sandblasted every decade.
Hull Bug represents a completely different approach to keeping ships free of crud: It's not terribly powerful, but the idea is that it would be so easy to use, it could be deployed almost continuously, to gently sweep biofilms and baby barnacles off the underside of a ship. (The alternative are less-frequent cleanings carried out by divers equipped with spinning brushes, an expensive and difficult proposition.)
Hull Bug is inspired by the "grooming" behavior common to just about every crustacean on the planet. Hermit crabs even have a special pair of legs devoted to just this purpose.
The Hull Bug is relatively small: it's less than three feet long, weighs 50 pounds, and uses a simple bulldozer attachment to keep a hull clear of material. But its most clever features are how it navigates and adheres to the ship..."
Ant Jaws Break Speed Record, Propel Insects Into Air, Biologists Find
|5:02:18 PM, Friday, November 04, 2011|
"21 August 2006
BERKELEY – A species of ant native to Central and South America is entering the annals of extreme animal movement, boasting jaws arguably more impressive than such noteworthy contenders as the great white shark and the spotted hyena.
Biologists clocked the speed at which the trap-jaw ant, Odontomachus bauri, closes its mandibles at 35 to 64 meters per second, or 78 to 145 miles per hour - an action they say is the fastest self-powered predatory strike in the animal kingdom. The average duration of a strike was a mere 0.13 milliseconds, or 2,300 times faster than the blink of an eye.
A research team led by Sheila Patek, assistant professor of integrative biology at the University of California, Berkeley, calculated the kinematics of the trap-jaw ant's mandible strikes with the help of advances in high-speed videography. The researchers published their results in the Aug. 21 issue of the Proceedings of the National Academy of Sciences.
They found that the jaws, used to capture prey and to defend the ant from harm, accelerate at 100,000 times the force of gravity, with each jaw generating forces exceeding 300 times the insect's body weight. The ants in this study had body masses ranging from 12.1 to 14.9 milligrams.
"You'd think the relevant number is the mandible closing speed, but it's actually the acceleration that is most impressive," said Patek. "The acceleration is huge relative to the tiny mass of the mandibles. The mandibles are operating in the outer known limits in biology in terms of speed and acceleration."
Patek acknowledged that falcons can dive as fast as 300 miles per hour, but that the raptors must start from very high altitudes and get a boost from the force of gravity to reach those speeds. In comparison, animals such as trap-jaw ants and mantis shrimp (which formerly held the record for swiftest strike in the animal world) utilize energy stored within their own bodies. The mandibles of the trap-jaw ant, for instance, are held cocked by a pair of huge, contracting muscles in the head. The muscles are sprung when their corresponding latches, each on a shield-like plate called the clypeus, are triggered.
"Having a latch system is critical in obtaining the explosive speeds," said Patek. "In general, muscles aren't good at generating fast movements. If a person were to throw an arrow, it wouldn't get very far. But by using a crossbow, elastic energy is stored in the bow, and a latch releases the stored energy almost instantaneously. As a result, the arrow shoots out very fast and goes much farther. That's exactly what really fast organisms are doing."
It's no wonder, then, that O. bauri ants can launch themselves into the air with a mere snap of their jaws, achieving heights up to 8.3 centimeters and horizontal distances up to 39.6 centimeters. That roughly translates, for a 5-foot-6-inch tall human, into a height of 44 feet and a horizontal distance of 132 feet, an aerial trajectory likely to be the envy of circus acrobats and Olympic athletes.
The jump's trajectory depends on the purpose of the mandible's strike. When the ant, either alone or in a group, approaches and strikes a large intruder with its jaws, it is simultaneously catapulted away from the trespasser, perhaps leaving behind a crippled victim in the process. In these so-called "bouncer defense" maneuvers, the trap-jaw ants clear, on average, 22.3 centimeters horizontally, but only 0.8 to 5.7 centimeters vertically.
In comparison, when the ant needs to escape quickly from an intruder, it strikes its jaws against the ground to fling itself into the air. In these "escape jumps," the ant is jettisoned to heights of 6.1 to 8.3 centimeters, but just 3.1 centimeters horizontally.
Escape jumps also yield a faster initial spin rate, 63 revolutions per second, compared to the relatively slow spin rate of 36 revolutions per second for bouncer defense jumps.
Study co-author Andrew Suarez, assistant professor of entomology at the University of Illinois at Urbana-Champaign, noted that when the ants jump to escape from harm, they are airborne from 0.22 to 0.27 seconds, often long enough to keep them away from a lizard's tongue, which takes 0.11 to 0.28 seconds to strike.
The researchers suggest that the "popcorn effect" of multiple ants jumping at once may also serve to help them escape by confusing potential predators. Suarez, along with study co-author Brian Fisher, associate curator and chair of entomology at the California Academy of Sciences, witnessed this jumping frenzy first-hand when they were in Costa Rica collecting the worker ants for this study.
The researchers said the difference in aerial trajectories may be more a function of the angle at which an ant's mandibles hit their target rather than an intentional maneuver, although that is something they intend to investigate further..."
-- Old, but an interesting read nonetheless.
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