Mirror Image: FSU study lays out chirality flipping theory

Ken Hanson, left, and Eugene DePrince, right, are faculty members in the Department of Chemistry and Biochemistry.
Photo Credit: Florida State University

Chemists can make a career out of controlling whether certain molecules are generated as a lefty or a righty.

Molecules don’t literally have hands, but scientists often refer to them in this way when looking at molecules that are mirror images of each other and therefore are not superimposable. And whether a molecule is a lefty or a righty directly affects how they behave and their use in everything from drug design to flavoring foods.

A Florida State University research team led by Associate Professor of Chemistry Ken Hanson previously found a way to turn “left-handed” molecules into “right-handed” ones by using light to induce a proton transfer and the transformation into a different isomer. Now, Hanson and his fellow FSU Professor of Chemistry Eugene DePrince are harnessing the power of math and computers to predict what would happen if you performed that same process in a gap between closely spaced mirrors.

Parasite common in cats causes abortion in bighorn sheep

Bighorn sheep
Photo Credit: David Mark

A parasite believed to be present in more than 40 million people in the United States and often spread by domestic and wild cats could hamper ongoing conservation efforts in bighorn sheep.

A recent study led by Washington State University researchers at the Washington Animal Disease Diagnostic Laboratory found that Toxoplasma gondii, a parasite that infects most species of warm-blooded animals and causes the disease toxoplasmosis, is a cause of abortions, or pregnancy loss, as well as neonatal deaths in the sheep. Researchers documented five cases in bighorn sheep in a study published in the Journal of Wildlife Diseases, but additional studies are needed to determine the full scope of its impact, the authors said.

“We have seen Toxoplasma as a cause of fetal and neonate loss pretty commonly in domestic sheep, but we hadn’t seen pregnancy loss due to toxoplasmosis yet in bighorn sheep,” said Elis Fisk, the lead author of the study. “Unfortunately, it does appear to be causing abortions and some level of death in young bighorn lambs.”

Stress may trigger male defense against predators

Photo Credit: Jörgen Wiklund

Only males among the fish species crucian carp have developed a strategy to protect themselves from hungry predators, according to a new study from Lund University in Sweden. The explanation could lie in that the surrounding environment affects the stress system in males and females differently.

Some animals have evolved the ability to swiftly change appearance to defend themselves against predators when necessary - while avoiding the unnecessary costs of that appearance when it is not needed. This is an advantage for animals that live in environments where the risk of being eaten by predators varies. However, there is a difference in the ability of females and males to escape the enemy in this way. Researchers at Lund University have investigated the crucian carp fish species.

“When the smell of predatory fish spreads in the water, the male crucian carp begins to change its appearance, much like a character from Transformers. From having grown in length, the presence of the predatory fish causes the male carp to instead grow in height. The new body shape makes it much more difficult for gape-size limited predators to swallow them. The shape also provides better acceleration, which is an advantage when the fish has to escape from an attacking pike”, explains Jerker Vinterstare, biologist at Lund University.

Where you live and what cardiometabolic conditions you have affects risk of developing dementia

Image Credit: Gerd Altmann

People in the United States and England who have multiple cardiometabolic conditions such as diabetes and high systolic blood pressure are more likely to develop dementia than their peers who are relatively healthy, according to new research from the University of Surrey.

The study also found that people living in China have an increased risk of developing dementia if they have obesity and hypertension when compared to those in their country who are relatively healthy.

Panagiota Kontari, a post-graduate researcher in the School of Psychology at the University of Surrey, said:

“Dementia affects 55 million people worldwide and there is currently no cure, so prevention is key. Cardiometabolic conditions have been shown to increase likelihood of developing the syndrome due to their link with vascular, biological and neurodegenerative diseases, which might accelerate brain ageing and cognitive decline.

“Understanding how cardiometabolic conditions are clustered and which particular combination of them leads to a greater risk of dementia across the world is important as such knowledge could help design tailored prevention strategies that target varying risk factors in different countries.”

Propionic acid protects nerve cells and supports their regeneration

Thomas Grüter and Kalliopi Pitarokoili (right) from the study team in St. Josef Hospital.
Photo Credit: RUB, Marquard

Some autoimmune diseases attack the nerves in the arms and legs. Researchers from Bochum are taking a new approach to counteract this damage.

In laboratory tests, researchers from St. Josef Hospital Bochum showed that propionate, the salt of a short-chain fatty acid, can protect nerves and help with their regeneration. The findings could be useful for the treatment of autoimmune diseases that damage nerve cells, such as chronic inflammatory demyelinating polyneuropathy (CIDP). Propionate naturally arises in the intestine when fiber is broken down. In previous studies, a team from the same department from St. Josef Hospital Bochum, clinic of the Ruhr University Bochum, has already proven that people with multiple sclerosis (MS) have a lack of propionate and can benefit from additional propionate intake. Accordingly, the substance could also be useful for patients with CIDP.

A group led by Dr. Thomas Grüter and private lecturer Dr. Kalliopi Pitarokoili from the Neurological University Clinic on St. Josef Hospital (Head of Prof. Dr. Ralf Gold), in the journal Proceedings of the National Academy of Sciences.

Genes Common to Different Species Found to Be Connected to the Development of Depression

Affective disorders, also known as mood disorders, are a group of mental illnesses that involve changes in emotional states.
Photo Credit:: Christopher Lemercier

Russian scientists performed a cross-species analysis of brain gene expression in danio fish, rats and humans to identify new common molecular targets for the therapy of affective disorders of the central nervous system induced by chronic stress. The study was able to identify several key brain proteins that may play important roles in the pathogenesis of affective disorders.

The article was published in the journal Scientific Reports. Affective disorders, also known as mood disorders, are a group of mental illnesses that involve changes in emotional states. They include various forms of depression and mania, psychosis, and increased anxiety. They are widespread because they occur not only as independent mental pathologies, but also as complications of neurological and other somatic diseases.

This fact determines the difficulty of diagnosis: people classify low mood, anxiety and irritability as temporary, situational manifestations. According to statistics, emotional disorders of varying severity occur in 20% of people, but only a quarter of them receive qualified help.

A Quan­tum Video Reel

Using all of images from the video reel, the team could then estimate the quantum states of the atom.
Image Credit: University of Innsbruck

When it comes to creating ever more intriguing quantum systems, a constant need is finding new ways to observe them in a wide range of physical scenarios.  JILA Fellow Cindy Regal and JILA and NIST Fellow Ana Maria Rey have teamed up with Oriol Romero-Isart from the University of Innsbruck and IQOQI to show that a trapped particle in the form of an atom readily reveals its full quantum state with quite simple ingredients, opening up opportunities for studies of the quantum state of ever larger particles.

In the quantum realm an atom does not behave as point particle, instead it behaves more as a wave.  Its properties (e.g., its position and velocity) are described in terms of what is referred to as the wavefunction of the atom. One way to learn about the wavefunction of a particle is to let the atom fly and then capture its location with a camera. 

And with the right tricks, pictures can be taken of the particle’s quantum state from many vantage points, resulting in what is known as quantum tomography (‘tomo’ being Greek for slice or section, and ‘graphy’ meaning describing or recording).  In the work published in Nature Physics, the authors used a rubidium atom placed carefully in a specific state of its motion in a tightly focused laser beam, known as an optical tweezer.  And they were able to observe it from many vantage points by letting it evolve in the optical tweezer in time.  Like a ball rolling in a bowl, at different times the velocity and location of the particle interchange, and by snapping pictures at the right time during a video reel of the ball, many vantages of the particle’s state can be revealed.

Asteroid findings from specks of space dust could save the planet

Itokawa seen in close-up
Image Credit: JAXA

Curtin University-led research into the durability and age of an ancient asteroid made of rocky rubble and dust, revealed significant findings that could contribute to potentially saving the planet if one ever hurtled toward Earth.

The international team studied three tiny dust particles collected from the surface of ancient 500-metre-long rubble pile asteroid, Itokawa, returned to Earth by the Japanese Space Agency’s Hayabusa 1 probe.

The study’s results showed asteroid Itokawa, which is 2 million kilometers from Earth and around the size of Sydney Harbour Bridge, was hard to destroy and resistant to collision.

Lead author Professor Fred Jourdan, Director of the Western Australian Argon Isotope Facility, part of the John de Laeter Centre and the School of Earth and Planetary Sciences at Curtin, said the team also found Itokawa is almost as old as the solar system itself.

“Unlike monolithic asteroids, Itokawa is not a single lump of rock, but belongs to the rubble pile family which means it’s entirely made of loose boulders and rocks, with almost half of it being empty space,” Professor Jourdan said.

Scientists Unveil Least Costly Carbon Capture System to Date

Chemist Dave Heldebrant, a recently selected fellow of the American Chemical Society who holds a joint appointment with Washington State University, has helped design several solvents that can deftly capture carbon dioxide molecules before they reach Earth’s atmosphere. 
Photo Credit: Andrea Starr | Pacific Northwest National Laboratory

The need for technology that can capture, remove and repurpose carbon dioxide grows stronger with every CO2 molecule that reaches Earth’s atmosphere. To meet that need, scientists at the Department of Energy’s Pacific Northwest National Laboratory have cleared a new milestone in their efforts to make carbon capture more affordable and widespread. They have created a new system that efficiently captures CO2—the least costly to date—and converts it into one of the world’s most widely used chemicals: methanol.

Snaring CO2 before it floats into the atmosphere is a key component in slowing global warming. Creating incentives for the largest emitters to adopt carbon capture technology, however, is an important precursor. The high cost of commercial capture technology is a longstanding barrier to its widespread use.

PNNL scientists believe methanol can provide that incentive. It has many uses as a fuel, solvent, and an important ingredient in plastics, paint, construction materials and car parts. Converting CO2 into useful substances like methanol offers a path for industrial entities to capture and repurpose their carbon.

Soft robots harness viscous fluids for complex motions

Soft Robot
Video Credit: Courtesy of Collective Embodied Intelligence Lab | Cornell University 

One of the virtues of untethered soft robots is their ability to mechanically adapt to their surroundings and tasks, making them ideal for a range of roles, from tightening bolts in a factory to conducting deep-sea exploration. Now they are poised to become even more agile and controlled.

A team of researchers led by Kirstin Petersen, assistant professor of electrical and computer engineering in the College of Engineering, designed a new – and surprisingly simple – system of fluid-driven actuators that enable soft robots to achieve more complex motions. The researchers accomplished this by taking advantage of the very thing – viscosity – that had previously stymied the movement of such robots.

The team’s paper, “Harnessing Nonuniform Pressure Distributions in Soft Robotic Actuators,” published Jan. 20 in Advanced Intelligent Systems. The paper’s lead author is postdoctoral researcher Yoav Matia.