Good news on blocking a virus considered a global threat

Illustration of the Hendra virus

Scientists have reported good news on the pandemic preparedness front: A cocktail of four manufactured antibodies is effective at neutralizing a virus from the Henipavirus family, a group of pathogens considered to be a global biosecurity threat.

The study focused on protection against a recently identified variant of the Hendra virus, which, along with Nipah virus, has been responsible for deadly animal and human infection outbreaks in the Eastern Hemisphere. The 2011 movie Contagion depicts a fictional viral outbreak traced to an infected pig that is modeled on the Nipah virus.

The Hendra variant, identified in two fatally diseased horses and sick bats in Australia, featured dramatic genetic changes from the original virus – which created a sense of urgency among scientists to learn how existing countermeasures stack up against the restructured pathogen.

Researchers screened and determined in cell studies that several previously developed monoclonal antibodies designed to neutralize the original virus are also effective against the variant. The team also designed an additional antibody that could join three others in a powerful cocktail that would leave the virus with minimal ability to further mutate its way out of antibody recognition.

Lockheed Martin, KAI Sign Teaming Agreement for Future T-50 Opportunities

Aimee Burnett, Greg Ulmer and OJ Sanchez join Mr. Hyun-Ho Ahn, president & CEO, Korea Aerospace Industries, for the T-50 Teaming Agreement signing ceremony.
Credit: Lockheed Martin Corporation

Lockheed Martin and Korea Aerospace Industries (KAI) have signed a teaming agreement for future T-50 opportunities, the newest partnership in the decades-long relationship between the companies.

“Lockheed Martin is an air power solutions leader, delivering capabilities across the entire spectrum of training and combat aircraft,” says Aimee Burnett, vice president, Integrated Fighter Group Business Development at Lockheed Martin. “We are proud to continue to partner with KAI on the T-50 to leverage our collective experiences to train the next generation of pilots to fly, fight and win."

She says the T-50 is a proven aircraft program that reduces the learning curve for new pilots and gets them flying operational sorties faster – even in fifth-generation aircraft like the F-35. That’s important as air forces around the world need to get their pilots up to speed faster than ever before, whether that’s to fill a gap in personnel or due to increased frequency of combat missions.

“That’s where the benefits of the proven T-50 program really come into play,” she says. “The seamless training experience with the T-50 gives student pilots an additional edge and fully prepares them – in less time than in the past – to fly any combat mission.”

Researchers solve mystery surrounding dielectric properties of unique metal oxide

University of Minnesota Associate Professor Bharat Jalan and his students discovered that the true dielectric constant of their strontium titanate films exceeds 25,000—the highest ever measured for this material.
Credit: Jalan Group, University of Minnesota

A University of Minnesota Twin Cities-led research team has solved a longstanding mystery surrounding strontium titanate, an unusual metal oxide that can be an insulator, a semiconductor, or a metal. The research provides insight for future applications of this material to electronic devices and data storage.

The paper is published in the prestigious Proceedings of the National Academy of Sciences of the United States of America (PNAS), a peer-reviewed, multidisciplinary, scientific journal.

When an insulator like strontium titanateis placed between oppositely charged metal plates, the electric field between the plates causes the negatively charged electrons and the positive nuclei to line up in the direction of the field. This orderly lining up of electrons and nuclei is resisted by thermal vibrations, and the degree of order is measured by a fundamental quantity called the dielectric constant. At low temperature, where the thermal vibrations are weak, the dielectric constant is larger.

In semiconductors, the dielectric constant plays an important role by providing effective “screening,” or protection, of the conducting electrons from other charged defects in the material. For applications in electronic devices, it is critical to have a large dielectric constant.

A Fresh Take on Fat: Nanoparticle Technology Provides Healthy Trans, Saturated Fat Alternative

Yangchao Luo, an associate professor in the College of Agriculture, Health and Natural Resources.
 Credit: Jason Shelton/UConn Photo

The old adage that oil and water don’t mix isn’t entirely accurate. While it’s true that the two compounds don’t naturally combine, turning them into one final product can be done. You just need an emulsifier, an ingredient commonly used in the food industry.

Yangchao Luo, an associate professor in the College of Agriculture, Health and Natural Resources, is using an innovative emulsification process for the development of a healthier shelf-stable fat for food manufacturing.

Luo is working with something known as high internal phase Pickering emulsions (HIPEs). High internal phase means the mixture is at least 75% oil. Pickering emulsions are those that are stabilized by solid particles.

Previous research in Pickering emulsions has focused on non-edible particles, but Luo is interested in bringing HIPEs to the food industry as an alternative to trans and saturated fats.

This new approach could have a major impact on how food is produced and could make it easier for food manufacturers to include healthier fats.

Many processed foods are loaded with saturated and trans fats for flavor and to extend a product’s shelf life. Consuming these fats can increase the risk of cardiovascular disease, type 2 diabetes, and LDL cholesterol.

AI platform enables doctors to optimize personalized chemotherapy dose

Research team behind the PRECISE.CURATE trial (from left) Prof Dean Ho, Dr Agata Blasiak, Dr Raghav Sundar, Ms Anh Truong
Credit/Source: National University of Singapore

Based on a pilot clinical trial, close to 97% of dose recommendations by CURATE.AI were accepted by clinicians; some patients were prescribed optimal doses that were around 20% lower on average

A team of researchers from National University of Singapore (NUS), in collaboration with clinicians from the National University Cancer Institute, Singapore (NCIS) which is part of the National University Health System (NUHS), has reported promising results in using CURATE.AI, an artificial intelligence (AI) tool that identifies and better allows clinicians to make optimal and personalized doses of chemotherapy for patients.

Based on a pilot clinical trial – called PRECISE.CURATE - involving 10 patients in Singapore who were diagnosed with advanced solid tumors and predominantly metastatic colorectal cancers, clinicians accepted close to 97% of doses recommended by CURATE.AI, with some patients receiving optimal doses that were approximately 20% lower on average. These early outcomes are a promising step forward for the potential of truly personalizing oncology, where drug doses can be adjusted dynamically during treatment.

Developed by Professor Dean Ho and his team, CURATE.AI is an optimization platform that harnesses a patient’s clinical data, which includes drug type, drug dose and cancer biomarkers, to generate an individualized digital profile which is used to customize the optimal dose during the course of chemotherapy treatment.

Brain hereditary disease factor suspected

Jonasz Jeremiasz Weber, Rana Dilara Incebacak Eltemur, Priscila Pereira Sena, Huu Phuc Nguyen (from left) worked out the study together.
Credit: © Pengfei Qi

Similar to Alzheimer's, the hereditary disease Spinocerebellar Ataxia Type 17 (SCA17) leads to the demise of brain nerve cells and the premature death of those affected. The exact mechanisms of the disease are unknown, so there are no treatment approaches to date. Researchers of human genetics at the Ruhr University Bochum (RUB) around Dr. Jonasz Weber now suspects a class of protein-splitting enzymes, so-called calpaines, to contribute to the disease. In the model, the Calpaine was switched off to stop the course. The researchers report in the journal Cellular and Molecular Life Sciences.

Changed blueprint of a protein

Spinocerebellar ataxia type 17 (SCA17) is a rare, hereditary disease of the human brain. Due to the pathological change in a gene that contains the blueprint for a protein called TATA box-binding protein (TBP), the protein is formed in cells in a defective form. This also affects its function. "One consequence of this is that the protein forms detectable protein deposits in the brain and damages the nerve cells via molecular mechanisms that have not yet been fully elucidated," explains Jonasz Weber.

As a consequence, those affected by the disease develop symptoms such as movement disorders, seizures, impairment of mental performance as well as changes in nature and behavior, which are associated with the breakdown of tissues such as the cerebellum and brain stem.

IA leads the charge against multiple sclerosis

MRI image in false colors of a brain hemisphere from an MS patient (affected areas are shown in red).
 Credit: Govind Bhagavatheeshwaran, Daniel Reich / NINDS / NIH

Artificial intelligence may enable earlier diagnosis of Multiple Sclerosis, an incurable disease that attacks the central nervous system. This could improve the efficacy of treatments designed to slow its progression.

An autoimmune disease, multiple sclerosis (MS) is characterized by a breakdown of myelin, the membrane that protects the axons of neurons. Communication within the nervous system is gradually disrupted, causing increasingly severe motor and neurological damage. Although multiple sclerosis is currently incurable, treatments are available to relieve certain symptoms, particularly if the disease is discovered early; unfortunately, however, it tends to be diagnosed at a later stage.

San Diego Zoo and Its Partners Spearhead Conservation of Critically Endangered Chinese Giant Salamander

Chinese giant salamander
Credit: San Diego Zoo Wildlife Alliance

Chinese giant salamanders are well camouflaged in the rushing waters of China’s mountain river system. Spotting this critically endangered species in its native habitat is exceedingly rare, but guests at the San Diego Zoo now have a unique opportunity to take a close look at this sleek and mysterious creature—at the newly opened Denny Sanford Wildlife Explorers Basecamp. San Diego Zoo Wildlife Alliance and conservation partners, including Ocean Park Hong Kong, are working toward the goal of creating a breeding group of Chinese giant salamanders. The goal is to eventually re-establish depleted populations in the Chinese giant salamander’s native range, while at the same time educating the public about conservation of its habitat in China.

The Chinese giant salamander is the largest living amphibian on the planet, with some measuring nearly 6 feet in length. However, their elusive nature has made it difficult for biologists to study their reproductive habits. Veterinary and wildlife care specialist teams at the San Diego Zoo conducted ultrasounds on three Chinese giant salamanders, in an effort to determine their sex and better understand their overall health. Determining the sex of these individuals is critical to the creation of a conservation breeding plan to help bring this species of “living fossils” back from the brink of extinction. The technique of using ultrasound to determine sex was discovered and recommended by specialists in China and colleagues in the zoo community.

Ningaloo corals are ill-equipped to handle future climate change

Source: Curtin University

The relatively pristine coral populations of WA’s inshore Kimberley region are better equipped to survive ocean warming than the World Heritage-listed Ningaloo Marine Park, according to a new Curtin University study.

Despite previous research predicting coral species would move south to cooler waters to protect themselves, the new study – published in Molecular Ecology – has found this may not hold true on the West Coast of Australia.

The new study, which investigated coral population connectivity and adaptive capacity, has found corals growing in different reef systems in north-western Australia are genetically isolated from each other.

The findings were based on the genetic data of a reef-building coral, Acropora digitifera, sampled from five well-known reef systems. The study sought to find out how connected these reef systems are, and how resilient this coral is to different future climate scenarios in different regions.

Lead researcher PhD student Arne Adam, from the Curtin School of Molecular and Life Sciences, said climate change had caused widespread loss of species biodiversity and ecosystem productivity across the globe, particularly on tropical coral reefs. He said the results suggest corals from northern reefs in WA are isolated from each other, meaning that corals may not be able to move to more southern reef regions.

Scientists Have Found Neurons that Control Some Symptoms of Sickness

During an infection, inflammatory signals activate immune-sensitive neurons (genetically labeled in red) in the ventral medial preoptic area (VMPO) leading to the induction of fever and other sickness behaviors. All cells are labeled with a nuclear stain (blue).
Credit: Courtesy of Dulac Lab/HHMI at Harvard University

Feeling ill is about both the body and the brain. Now scientists have identified a group of neurons in mice that has ultimate control over symptoms such as fever and behaviors like seeking out warmth.

Fevers, chills, an appetite that vanishes – we can tell when we’re getting sick. Many people chalk these symptoms of illness up to the immune system fighting off infection. But there’s another player involved when we feel woefully under the weather.

“All of this is orchestrated by the brain,” says neurobiologist Catherine Dulac, who is a Howard Hughes Medical Institute Investigator at Harvard University. Now research from Dulac’s team, published in Nature, pins this broad response on a previously uncharacterized population of neurons in the brain.

How exactly the brain serves as an infection ringleader has been unclear. Earlier research had identified receptors in the brain that were required for animals to develop a fever. But fever is only part of the story. One of the bigger mysteries is: Where does ultimate control for the symptoms and behaviors associated with sickness lie?

Dulac, her postdoctoral fellow, Jessica A. Osterhout, and colleagues injected mice with molecules that mimic bacterial or viral infections to investigate that question. As the mice’s immune systems reacted to these inflammatory molecules, the researchers homed in on which neurons jumped into action. The team watched neurons’ gene expression through single-cell RNA sequencing and mapped the whereabouts of those neurons using a visualization technique called MERFISH, which was developed in the lab of HHMI Investigator Xiaowei Zhuang at Harvard, a collaborator in this work.

Carbon Dioxide Glaciers Are Moving at Mars’ South Pole

Perspective view of the South Polar Cap of Mars using Viking imagery draped over topography from the Mars Orbiter Laser Altimeter. White ice is a residual carbon dioxide cap that resides on top of and protects the much thicker CO2 glaciers. The surrounding terrain is composed of red dust that overlies the mountains in the background and the 4-kilometer-thick H2O ice cap that supports the CO2 glaciers.
  Credit: NASA data visualized using JMARS.

Glaciers of carbon dioxide are moving, creating deposits kilometers thick today across the south polar region of Mars, something that could have been going on more than 600,000 years, a paper by Planetary Science Institute Research Scientist Isaac Smith says.

“The CO2 deposits that were first identified in 2011 turn out to be flowing today, just like glaciers on Earth,” said Smith, lead author of “Carbon Dioxide Ice Glaciers at the South Pole of Mars” that appears in the Journal for Geophysical Research - Planets.

“Approximately 600,000 years ago CO2 ice started forming at the Martian south pole. Due to climate cycles, the ice has increased in volume and mass several times, interrupted by periods of mass loss through sublimation,” Smith said. “If the ice had never flowed, then it would mostly be where it was originally deposited, and the thickest ice would only be about 45 meters thick. Instead, because it flowed downhill into basins and spiral troughs – curvilinear basins – where it ponded, it was able to form deposits reaching one kilometer thick.

The Earth moves far under our feet: New study shows Earth’s inner core oscillates

The Earth’s inner core — a hot, dense ball of solid iron the size of Pluto — has been shown to move and/or change over decades.
Credit: USC Graphic/Edward Sotelo

USC scientists have found evidence that the Earth’s inner core oscillates, contradicting previously accepted models that suggested it consistently rotates at a faster rate than the planet’s surface.

Their study, published in Science Advances, shows that the inner core changed direction in the six-year period from 1969-74, according to the analysis of seismic data. The scientists say their model of inner core movement also explains the variation in the length of day, which has been shown to oscillate persistently for the past several decades.

“From our findings, we can see the Earth’s surface shifts compared to its inner core, as people have asserted for 20 years,” said John Vidale, co-author of the study and Dean’s Professor of Earth Sciences at USC Dornsife College of Letters, Arts and Sciences. “However, our latest observations show that the inner core spun slightly slower from 1969-71 and then moved in the other direction from 1971-74. We also note that the length of the day grew and shrank as would be predicted.

“The coincidence of those two observations makes oscillation the likely interpretation.”

One in 500 men carry extra sex chromosome, putting them at higher risk of several common diseases

In a study published in Genetics in Medicine, researchers analyzed genetic data collected on over 200,000 UK men aged 40-70 from UK Biobank, a biomedical database and research resource containing anonymized genetic, lifestyle and health information from half a million UK participants. They found 356 men who carried either an extra X chromosome or an extra Y chromosome.

Sex chromosomes determine our biological sex. Men typically have one X and one Y chromosome, while women have two Xs. However, some men also have an extra X or Y chromosome – XXY or XYY.

Without a genetic test, it may not be immediately obvious. Men with extra X chromosomes are sometimes identified during investigations of delayed puberty and infertility; however, most are unaware that they have this condition. Men with an extra Y chromosome tend to be taller as boys and adults, but otherwise they have no distinctive physical features.

In today’s study, the researchers identified 213 men with an extra X chromosome and 143 men with an extra Y chromosome. As the participants in UK Biobank tend to be ‘healthier’ than the general population, this suggests that around one in 500 men may carry an extra X or Y chromosome.

Only a small minority of these men had a diagnosis of sex chromosome abnormality on their medical records or by self-report: fewer than one in four (23%) men with XXY and only one of the 143 XYY men (0.7%) had a known diagnosis.

By linking genetic data to routine health records, the team found that men with XXY have much higher chances of reproductive problems, including a three-fold higher risk of delayed puberty and a four-fold higher risk of being childless. These men also had significantly lower blood concentrations of testosterone, the natural male hormone. Men with XYY appeared to have a normal reproductive function.

Perpetual motion is possible

Researchers cooled a helium-3 superfluid down to one ten-thousandth of a degree from absolute zero and proceeded to create two time-crystals inside the liquid.
Credit: Mikko Raskinen / Aalto University.

Professor and Nobel laureate in Physics Frank Wilczek, who also recently visited Aalto University to speak at a colloquium of Finland’s foremost quantum community InstituteQ, theorised the existence of time-crystals in 2012. They were experimentally confirmed to exist in 2016.

Now researchers have succeeded in creating and observing the interaction of two time-crystals in an experiment at Aalto University’s Low Temperature Lab.

The study was recently published in Nature Communications.

In an ordinary crystal the atoms or molecules comprising it have organized themselves into a regular crystal structure. Conversely, a time-crystal is a grouping of particles that moves without external energy, always returning to the same state in certain intervals. That means its regularity is expressed in time rather than in space.

‘Everyone knows perpetual motion machines are impossible. However, in quantum physics perpetual motion itself is possible as long as it’s not observed. By weakly connecting the particles to their environment, we were able to create up to two time-crystals and make them interact,’ says Samuli Autti, researcher at Lancaster University who carried out the experiment at Aalto.

Seeking COVID’s Kryptonite

Photos of the setup. Left: A closeup of the interior of the box containing the laser-to-fiber-optic coupling system. Center: The laser system in the hallway outside the door to BSL-3. Right: A closeup of the experimental setup inside BSL-3, including the chamber the housed the samples of SARS-CoV-2.
 Credit: NIST

To disinfect a surface, you can illuminate it with a blast of ultraviolet (UV) light, which is bluer than the human eye can see. But to specifically inactivate SARS-CoV-2, the virus that causes COVID-19, which wavelengths are best? And how much radiation is enough?

Answering those questions requires scientists to overcome two main obstacles. First, they need to separate the virus completely from extraneous substances in the environment. Second, they need to illuminate the virus with a single wavelength of UV light at a time, with minimal changes to the experimental setup between tests.

A recent collaboration between the National Institute of Standards and Technology (NIST) and the National Biodefense Analysis and Countermeasures Center (NBACC), a U.S. Department of Homeland Security Science and Technology Directorate laboratory, overcame both these obstacles and completed what may be the most thorough test ever conducted of how several different UV and visible wavelengths affect SARS-CoV-2.

In a new paper published this week in Applied Optics, the collaborators describe their novel system for projecting a single wavelength of light at a time onto a sample of COVID-19 virus in a secure laboratory. Classified as Biosafety Level 3 (BSL-3), the lab is designed for studying microbes that are potentially lethal when inhaled. Their experiment tested more wavelengths of UV and visible light than any other study with the virus that causes COVID-19 to date.