SFL Educational News Service
Source/Credit: French National Center for Scientific Research
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| Human activities and infrastructure, such as cities and roads, may reduce future options for species as they need to move to keep pace with climate change. Shown is a willow ptarmigan above a port city. Photo Credit: Chris Sergeant. |
Scientific Frontline: "At a Glance" Summary: Proactive Approaches Needed.
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| Photo by Allan Mas |
They think this ‘explorative bias’ has an evolutionary basis and plays a crucial role in our survival.
Based on these findings − which were apparent across multiple domains from visual processing to memory and at all levels of analysis − the researchers argue that we need to change our perspective of dyslexia as a neurological disorder.
The findings, reported today in the journal Frontiers in Psychology, have implications both at the individual and societal level, says lead author Dr Helen Taylor, an affiliated Scholar at the McDonald Institute for Archaeological Research at the University of Cambridge and a Research Associate at the University of Strathclyde.
“The deficit-centered view of dyslexia isn’t telling the whole story,” said Taylor. “This research proposes a new framework to help us better understand the cognitive strengths of people with dyslexia.”
She added: “We believe that the areas of difficulty experienced by people with dyslexia result from a cognitive trade-off between exploration of new information and exploitation of existing knowledge, with the upside being an explorative bias that could explain enhanced abilities observed in certain realms like discovery, invention and creativity.”
This is the first-time a cross-disciplinary approach using an evolutionary perspective has been applied in the analysis of studies on dyslexia.
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| At the beginning of the last ice, local mountain glaciers grew and formed large ice sheets, like the one seen here in Greenland, that covered much of today's Canada, Siberia, and Northern Europe. Credit: Annie Spratt/Unsplash |
Understanding what drives Earth’s glacial–interglacial cycles – the periodic advance and retreat of ice sheets in the Northern Hemisphere – is no easy feat, and researchers have devoted substantial effort to explaining the expansion and shrinking of large ice masses over thousands of years. The new study, published in the journal Nature Geoscience, proposes an explanation for the rapid expansion of the ice sheets that covered much of the Northern Hemisphere during the most recent ice age, and the findings could also apply to other glacial periods throughout Earth's history.
About 100,000 years ago, when mammoths roamed the Earth, the Northern Hemisphere climate plummeted into a deep freeze that allowed massive ice sheets to form. Over a period of about 10,000 years, local mountain glaciers grew and formed large ice sheets covering much of today's Canada, Siberia and northern Europe.
While it has been widely accepted that periodic "wobbling" in the Earth's orbit around the sun triggered cooling in the Northern Hemisphere summer that caused the onset of widespread glaciation, scientists have struggled to explain the extensive ice sheets covering much of Scandinavia and northern Europe, where temperatures are much milder.
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| A tangle of unprocessed boron nitride nanotubes seen through a scanning electron microscope. Rice University scientists introduced a method to combine them into fibers using the custom wet-spinning process they developed to make carbon nanotube fibers. Credit: Pasquali Research Group/Rice University |
A Rice team led by professors Matteo Pasquali and Angel Martà has simplified handling of the highly valuable nanotubes to make them more suitable for large-scale applications, including aerospace, electronics and energy-efficient materials.
The researchers reported in Nature Communications that boron nitride nanotubes, aka BNNTs, assemble themselves into liquid crystals under the right conditions, primarily concentrations above 170 parts per million by weight in chlorosulfonic acid.
These liquid crystals consist of aligned BNNTs that are far easier to process than the tangled nanotubes that usually form in solution. The lab proceeded to form fibers and films from the liquid crystalline solutions.
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| MIT-WHOI Joint Program student Henry Holm pumping seawater for lipid samples from beneath sea ice on the Western Antarctic Peninsula, 2018. This is for a WHOI-led study that conducted a global survey of lipids in the ocean in order to analyze omega-3 fatty acids. Image credit: Benjamin Van Mooy / © Woods Hole Oceanographic Institution |
Now, the first-ever survey of planktonic lipids in the global ocean predicts a temperature-linked decrease in the production of essential omega-3 fatty acids, an important subset of lipid molecules.
A significant implication of the survey is that as global warming proceeds, there will be fewer and fewer omega-3 fatty acids produced by plankton at the base of the food web, which will mean less omega-3 fatty acids available for fish and for people. Omega-3 fatty acid is an essential fat that the human body cannot produce on its own, and is widely regarded as a “good” fat that links seafood consumption to heart health.
The survey analyzed 930 lipid samples across the global ocean using a uniform high-resolution accurate mass spectrometry analytical workflow, “revealing heretofore unknown characteristics of ocean planktonic lipidomes,” which is the entirety of hundreds to thousands of lipid species in a sample, according to a new paper led by authors from the Woods Hole Oceanographic Institution (WHOI).
“Focusing on ten molecularly diverse glycerolipid classes we identified 1,151 distinct lipid species, finding that fatty acid unsaturation (i.e., number of carbon-to-carbon double bonds) is fundamentally constrained by temperature. We predict significant declines in the essential fatty acid eicosapentaenoic acid [EPA] over the next century, which are likely to have serious deleterious effects on economically critical fisheries,” states the paper, “Global ocean lipidomes show a universal relationship between temperature and lipid unsaturation,” published in the journal Science.
While manipulating play dough is fun and easy for 2-year-olds, the shapeless sludge is hard for robots to handle. Machines have become increasingly reliable with rigid objects, but manipulating soft, deformable objects comes with a laundry list of technical challenges, and most importantly, as with most flexible structures, if you move one part, you’re likely affecting everything else.
Scientists from MIT’s Computer Science and Artificial Intelligence Laboratory (CSAIL) and Stanford University recently let robots take their hand at playing with the modeling compound, but not for nostalgia’s sake. Their new system learns directly from visual inputs to let a robot with a two-fingered gripper see, simulate, and shape doughy objects. “RoboCraft” could reliably plan a robot’s behavior to pinch and release play dough to make various letters, including ones it had never seen. With just 10 minutes of data, the two-finger gripper rivaled human counterparts that teleoperated the machine — performing on-par, and at times even better, on the tested tasks.
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| Artistic rendering of Ca. Thiomargarita magnifica with dime. Credit: Mangrove photo by Pierre Yves Pascal; Illustration by Susan Brand/Berkeley Lab |
The Core Concept: Candidatus Thiomargarita magnifica is a giant, single-celled bacterium found in Caribbean mangrove ecosystems that can reach nearly a centimeter in length. It is roughly 5,000 times larger than typical bacteria and is distinctly visible to the naked eye.
Key Distinction/Mechanism: Unlike traditional bacteria that possess free-floating DNA, this species compartmentalizes its genetic material into novel, membrane-bound organelles named "pepins." It generates energy through chemosynthesis, thriving on top of sulfur-rich sediments.
Major Frameworks/Components:
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| Plants are growing in complete darkness in an acetate medium that replaces biological photosynthesis. Credit: Marcus Harland-Dunaway/UCR Full Size Image |
The research, published in Nature Food, uses a two-step electrocatalytic process to convert carbon dioxide, electricity, and water into acetate, the form of the main component of vinegar. Food-producing organisms then consume acetate in the dark to grow. Combined with solar panels to generate the electricity to power the electrocatalysis, this hybrid organic-inorganic system could increase the conversion efficiency of sunlight into food, up to 18 times more efficient for some foods.
“With our approach we sought to identify a new way of producing food that could break through the limits normally imposed by biological photosynthesis,” said corresponding author Robert Jinkerson, a UC Riverside assistant professor of chemical and environmental engineering.
In order to integrate all the components of the system together, the output of the electrolyzer was optimized to support the growth of food-producing organisms. Electrolyzers are devices that use electricity to convert raw materials like carbon dioxide into useful molecules and products. The amount of acetate produced increased while the amount of salt used decreased, resulting in the highest levels of acetate ever produced in an electrolyzer to date.
“Using a state-of-the-art two-step tandem CO2 electrolysis setup developed in our laboratory, we were able to achieve a high selectivity towards acetate that cannot be accessed through conventional CO2 electrolysis routes,” said corresponding author Feng Jiao at University of Delaware.
In about a fifth of the cases of Parkinson’s disease, look to a small, malfunctioning protein in the lysosome as a risk factor, say University of Michigan researchers.
Lysosomes are the garbage collectors of cells. These organelles are responsible for breaking down the “trash” in the cell—misfolded proteins, worn out organelles—that cells collect in a process called autophagy. Autophagy depends closely on lysosome function, and when lysosomes malfunction and this process is disrupted, causing cellular debris to build up, various disorders can occur. Many of these are degenerative disorders such as Alzheimer’s disease, Duchenne muscular dystrophy and Tay-Sachs disease.
Now, U-M researchers have discovered how a mutated protein called TMEM175 acts as a risk factor in about 20% of cases of Parkinson’s disease. In Parkinson’s, nerve cells in the area of the brain that controls movement begin to fail and die. According to the National Institute on Aging, researchers think Parkinson’s is a result of a combination of genetic and environmental factors.
The U-M researchers found that if mutated, TMEM 175 does not properly regulate the acidity of the environment within the lysosome. If the acidity in that environment is not correct, enzymes within lysosomes stop working effectively, and the organelles cannot perform their roles correctly. Their study results are published in the journal Cell.
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| LGBTQ people may face unique barriers to health care, according to a new study by Zachary Ramsey, doctoral candidate in the WVU School of Public Health. By interviewing researchers and physicians, Ramsey identified four pressing health issues that sexual and gender minorities face: discrimination, heteronormativity, health care system barriers and the interconnectedness of physical, mental and social health. His findings appear in the Journal of Gay and Lesbian Social Services. Credit: West Virginia University |
A new qualitative study by Zachary Ramsey—a doctoral candidate in the West Virginia University School of Public Health—suggests sexual and gender minorities may face unique barriers to health care, most particularly in rural areas.
His findings appear in the Journal of Gay and Lesbian Social Services.
“Research into sexual and gender minorities is growing quickly, but mainly in large urban centers,” he said. “There are a lot of differences between urban and rural populations for a general population, so it stands to reason that there would be a lot of differences between urban and rural LGBTQ individuals. Without more studies of LGBTQ rural individuals specifically, these differences will not be known, and policies and rural LGBTQ Center programming can only use an urban population for guidance.”
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| Dr. Roman Gernhäuser from the TUM Physics Department is part of the international research team that detected the tetra-neutron. Image Credit: Uli Benz / TUM |
The building blocks of atomic nuclei are the nucleons, which come in two types, the neutral neutrons and the positively charged protons – the two so-called isospin states of the nucleon. Bound nuclei composed exclusively of neutrons have never been clearly identified. The only known bound systems that consist almost exclusively of neutrons are the neutron stars. These are the final stages of stellar evolution with a typical diameter of about ten kilometers. These stars are stable (bound) by gravity, which leads to a very high neutron density inside the stellar corpses. Atomic nuclei, in turn, are bound by the strong interaction, with preference to bind a comparable number of neutrons and protons – this is known from the stable nuclei found on Earth.
However, the study of pure neutron systems is of great importance, since this is the only way to gain experimental knowledge about the interaction of several neutrons with each other and thus about the nuclear interaction. Moreover, the study of the hitherto hypothetical particles could help to better understand the properties of neutron stars. Finding out whether such neutron systems exist as resonance states or even bound nuclei is therefore a long-standing endeavor in nuclear physics. The international team of scientists has now made a new attempt to do this, using a new experimental method that differs from all previous experiments.
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| Alan Kwan, MD, examines imaging studies to find out how heart disease differs between women and men. Photo by Cedars-Sinai. |
The gender disparity likely stems from cellular-level differences in the heart muscle and surrounding tissue, said Alan Kwan, MD, the
“We have known for some time that with aging, women’s hearts tend to have a thicker wall, shrink more in size, and pump faster and harder than a man’s,” said Kwan. “While these structural differences can be seen with the naked eye, it requires more sensitive and detailed imaging to understand how these changes lead to, or result in, heart failure.”
Using their novel cardiac imaging technique, the research team found microstructural changes in the cardiac muscle tissue that predicted heart failure, particularly in women. These microstructural changes likely are the result of greater amounts of fibrosis—or scarring—accumulating in the hearts of females when compared to males.
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| Many of Asia's rivers flow from the Tibetan Plateau, providing reserves of water to nearly 2 billion people. Credit: Esther Lee Creative Commons Attribution 2.0 Generic license. |
Nicknamed “The Third Pole,” the Tibetan Plateau and neighboring Himalayas is home to the largest global store of frozen water outside of the North and South Polar Regions. This region, also known as the Asian water tower (AWT), functions as a complex water distribution system which delivers life-giving liquid to multiple countries, including parts of China, India, Nepal, Pakistan, Afghanistan, Tajikistan and Kyrgyzstan.
Yet due to the rapid melting of snow and upstream glaciers, the area can’t sustainably support the continued growth of the developing nations that rely on it.
“Populations are growing so rapidly, and so is the water demand,” said Lonnie Thompson, distinguished university professor of earth sciences at The Ohio State University and senior research scientist at the Byrd Polar Research Center. “These problems can lead to increased risks of international and even intranational disputes, and in the past, they have.”
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| Photo Credit: Aireon |
Aireon will provide historical aircraft data and near real-time aircraft event data via its AireonINSIGHTS product for select Boeing airplane programs.
As part of its implementation of an enterprise Safety Management System (SMS), Boeing will integrate the ADS-B data into its safety analytics tools. Recognized worldwide as an industry best practice, SMS is an integrating framework for managing safety risks. Through the use of data science and data analytics, the information will deliver insights to proactively identify hazards and monitor emerging safety trends.
“We are investing in a data stream that can be transformed into safety intelligence,” said Vishwa Uddanwadiker, Boeing vice president of Aerospace Safety Analytics. “We are adding this to our data analytics ecosystem to help predict and prevent safety risks, while identifying other opportunities to strengthen our Safety Management System.”
The global space-based ADS-B data from AireonINSIGHTS can help customers gain insights to key performance indicators on flight safety.
“The power of the Aireon data unlocks a cache of information for Boeing regarding the operations of its aircraft in the global airspace. With this integration, Boeing will have data to provide a full operational view of its fleet, and we are excited to partner with them,” said Don Thoma, Aireon CEO.
As a leading global aerospace company, Boeing develops, manufactures and services commercial airplanes, defense products and space systems for customers in more than 150 countries. As a top U.S. exporter, the company leverages the talents of a global supplier base to advance economic opportunity, sustainability and community impact. Boeing's diverse team is committed to innovating for the future, leading with sustainability, and cultivating a culture based on the company's core values of safety, quality and integrity.
Aireon has deployed a space-based air traffic surveillance system for ADS-B-equipped aircraft throughout the entire globe. Aireon is harnessing next-generation aviation surveillance technologies that were formerly ground-based and, for the first time ever, is extending their reach globally to significantly improve efficiency, enhance safety, reduce emissions, and provide cost savings benefits to all stakeholders. Space-based ADS-B surveillance covers oceanic, polar, and remote regions, and augments existing ground-based systems that are limited to terrestrial airspace. In partnership with leading ANSPs from around the world, like NAV CANADA, the Irish Aviation Authority, ENAV, NATS UK and NAVIAIR, as well as Iridium Communications, Aireon is providing a global, real-time, space-based air traffic surveillance system, available to all aviation stakeholders.
Source/Credit: Boeing
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Scientific Frontline: Extended "At a Glance" Summary : Quantum Biology The Core Concept : Quantum biology is the study of non-triv...
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