Lavender oil for longer-lasting sodium-sulfur batteries

In the future, linalool, a main component of lavender, could help to make sodium-sulfur batteries more durable and efficient.
Photo Credit: Dan Meyers

Lavender oil could help solve a problem in the energy transition. A team from the Max Planck Institute of Colloids and Interfaces has created a material from linalool, the main component of lavender oil, and sulfur that could make sodium-sulfur batteries more durable and powerful. Such batteries could store electricity from renewable sources.

It is a crucial question in the energy transition: how can electricity from wind power and photovoltaics be stored when it is not needed? Large batteries are one option. And sulfur batteries, in particular sodium-sulfur batteries offer several advantages over lithium batteries as stationary storage units. The materials from which they are made are much more readily available than lithium and cobalt, two essential components of lithium-ion batteries. The mining of these two metals also often damages the environment and locally causes social and political upheaval. However, sodium-sulfur batteries can store less energy in relation to their weight than lithium batteries and are also not as durable. Lavender oil with its main component linalool could now help to extend the service life of sodium-sulfur-batteries, as a team from the Max Planck Institute of Colloids and Interfaces reports in the journal Small.  "It's fascinating to design future batteries with something that grows in our gardens," says Paolo Giusto, group leader at the Max Planck Institute of Colloids and Interfaces.

Drawing a Line from the Gut Microbiome to Inflammation and Depression

Morganella morganii bacteria on a plate.
Photo Credit: Ajay Kumar Chaurasiya
(CC BY-SA 4.0)

It’s become increasingly clear that the gut microbiome can affect human health, including mental health. Which bacterial species influence the development of disease and how they do so, however, is only just starting to be unraveled.

For instance, some studies have found compelling links between one species of gut bacteria, Morganella morganii, and major depressive disorder. But until now no one could tell whether this bacterium somehow helps drive the disorder, the disorder alters the microbiome, or something else is at play.

Harvard Medical School researchers have now pinpointed a biologic mechanism that strengthens the evidence that M. morganii influences brain health and provides a plausible explanation for how it does so.

The findings, published in the Journal of the American Chemical Society, implicate an inflammation-stimulating molecule and offer a new target that could be useful for diagnosing or treating certain cases of the disorder. They also provide a roadmap for probing how other members of the gut microbiome influence human health and behavior.

“There is a story out there linking the gut microbiome with depression, and this study takes it one step further, toward a real understanding of the molecular mechanisms behind the link,” said senior author Jon Clardy, the Christopher T. Walsh, PhD Professor of Biological Chemistry and Molecular Pharmacology in the Blavatnik Institute at HMS.

Powerful anticancer compound might also be the key to eradicating HIV

Study co-authors Jennifer Hamad and Owen McAteer prepare for a cellular assay, a lab technique used to study living cells. The assay will yield information about the location of EBC-46 compounds that have been introduced into cells in the lab.
Photo Credit: Paul Wender

A compound with the unpresuming designation of EBC-46 has made a splash in recent years for its cancer-fighting prowess. Now a new study led by Stanford researchers has revealed that EBC-46 also shows immense potential for eradicating human immunodeficiency virus (HIV) infections. 

Compared to similar-acting agents, EBC-46 excels at activating dormant cells where HIV is hiding, the study found. These “kicked” cells can then be targeted (“killed”) by immunotherapies to fully clear the insidious virus from the body. By pursuing this “kick and kill” strategy with EBC-46, researchers think achieving permanent elimination of HIV in patients—in other words, a cure—is possible.

"We’re pleased to report that EBC-46 performed extremely well in preclinical experiments as part of a ‘kick and kill’ therapeutic," said study senior author Paul Wender, the Bergstrom Professor of Chemistry at Stanford’s School of Humanities and Sciences. "While we still have a lot of work to do before treatments based on EBC-46 might reach the clinic, this study marks unprecedented progress toward the as-yet-unrealized goal of eradicating HIV.” 

OHSU researchers use AI machine learning to map hidden molecular interactions in bacteria

Andrew Emili, Ph.D., professor of systems biology and oncological sciences, works in his lab at OHSU. Emili is part of a multi-disciplinary research team that uncovered how small molecules within bacteria interact with proteins, revealing a network of molecular connections that could improve drug discovery and cancer research.
Photo Credit: OHSU/Christine Torres Hicks

A new study from Oregon Health & Science University has uncovered how small molecules within bacteria interact with proteins, revealing a network of molecular connections that could improve drug discovery and cancer research.

The work also highlights how methods and principles learned from bacterial model systems can be applied to human cells, providing insights into how diseases like cancer emerge and how they might be treated. The results are published today in the journal Cell.

The multi-disciplinary research team, led by Andrew Emili, Ph.D., professor of systems biology and oncological sciences in the OHSU School of Medicine and OHSU Knight Cancer Institute, alongside Dima Kozakov, Ph.D., professor at Stony Brook University, studied Escherichia coli, or E. coli, a simple model organism, to map how metabolites — small molecules essential for life — interact with key proteins such as enzymes and transcription factors. These interactions control important processes such as cell growth, division and gene expression, but how exactly they influence protein function is not always clear.

A new experimental system to bring quantum technologies closer to students

The expert Raúl Lahoz and a group of students with the new equipment for studying quantum physics.
 Photo Credit: Fundació Catalunya La Pedrera

The world of quantum physics is experiencing a second revolution, which will drive an exponential leap in the progress of computing, the internet, telecommunications, cybersecurity and biomedicine. Quantum technologies are attracting more and more students who want to learn about concepts from the subatomic world — such as quantum entanglement or quantum superposition — to explore the innovative potential of quantum science. In fact, understanding the non-intuitive nature of quantum technology concepts and recognizing their relevance to technological progress is one of the challenges of 2025, declared the International Year of Quantum Science and Technology by UNESCO.

Now, a team from the Faculty of Physics of the University of Barcelona has designed new experimental equipment that makes it possible for students to familiarize themselves with the more complex concepts of quantum physics. The configuration they present —versatile, cost-effective and with multiple ways of application in the classroom — is already operational in the Advanced Quantum Laboratory of the UB’s Faculty of Physics and could also be accessible in less specialized centers.

This innovation is presented in an article in the journal EPJ Quantum Technology, which results from a collaboration between professors Bruno Juliá, from the Department of Quantum Physics and Astrophysics and the UB Institute of Cosmos Sciences (ICCUB); Martí Duocastella, from the Department of Applied Physics and the UB Institute of Nanoscience and Nanotechnology (IN2UB), and José M. Gómez, from the Department of Electronic and Biomedical Engineering. It is based on the result of Raúl Lahoz’s master’s final project, with the participation of experts Lidia Lozano and Adrià Brú.

Child mortality has risen since pandemic, new study shows

Photo Credit: Josue Michel

While child deaths in England fell temporarily during the COVID-19 pandemic, they have now risen to new heights, a new study from researchers at the University of Bristol and based on unique National Child Mortality Database (NCMD) data has found.

The study, published in PLOS Medicine, has shown that children were less likely to die during the pandemic lockdown (April 2020–March 2021) than at any time before or since, with 377 fewer deaths than expected from the previous year.  

The number of deaths in the following year (2021-2022) was similar to before the pandemic, but in 2022−2023, there were 258 more deaths than expected from the pre-pandemic period. 

The aim of the research was to quantify the relative rate, and causes, of childhood deaths in England, before, during, and after national lockdowns for COVID-19 and its social changes.

The researchers identified all those children in England who died between April 2019 and March 2023 and calculated what the rate of death was for each year, for each group of children (e.g., infants or older children) and cause of death.

Eight Psychiatric Disorders Share the Same Genetic Causes

Image Credit: Won Lab

Building off previous groundbreaking research, a new study identifies specific genetic variants that have significant impacts on brain development and are shared across eight different psychiatric disorders. Targeting these variants could pave the way for treatments that address multiple conditions at once.

Psychiatric disorders often overlap and can make diagnosis difficult. Depression and anxiety, for example, can coexist and share symptoms. Schizophrenia and anorexia nervosa. Autism and attention deficit/hyperactivity disorder, too. But, why?

Life experiences, environment, and genetics can all influence psychiatric disorders, but much of it comes down to variations in our genetics. Over the past few years, scientists in the field of psychiatric genetics have found that there are common genetic threads that may be linking and causing coexisting psychiatric disorders.

In 2019, researchers at the Psychiatric Genomics Consortium, Harvard University, and the UNC School of Medicine identified 136 “hot spots” within the genome that are associated with eight psychiatric disorders. Among them, 109 hot spots were shared among multiple disorders, or “pleiotropic”. However, it was not clear at the time how genetic variations within these hot spots differed from those that only have roles in only one disorder.

Better prediction of epidemics

The curve calculated using a “reproduction matrix” (turquoise) reflects the actual infection rate (black) much more accurately than previous models (yellow and blue).
Graphic Credit: Empa

The reproduction number R is often used as an indicator to predict how quickly an infectious disease will spread. Empa researchers have developed a mathematical model that is just as easy to use but enables more accurate predictions than R. Their model is based on a reproduction matrix that takes into account the heterogeneity of society.

"Your friends have more friends than you do", wrote the US sociologist Scott Feld in 1991. Feld's so-called friendship paradox states that the friends of any given person have more friends on average than the person themselves. This is based on a simple probability calculation: Well-connected people are more likely to appear in other people's social circles. "If you look at any person's circle of friends, it is very likely that this circle contains very well-connected people with an above-average number of friends," explains Empa researcher Ivan Lunati, head of the Computational Engineering laboratory. A similar principle served Lunati and his team as the basis for a new mathematical model that can be used to more accurately predict the development of case numbers during an epidemic.

T cells rise up to fight infections in the gut

An image produced through Xenium analysis of mouse small intestines. Protruding “villi” stick up from the lining of the small intestine. Valley-like “crypts” fill in the gaps.
Image Credit: Reina Lab, La Jolla Institute for Immunology

Your gut is a battleground. The cells that line your small intestine have to balance two seemingly contradictory jobs: absorbing nutrients from food, while keeping a wary eye out for pathogens trying to invade your body.

“This is a surface where pathogens can sneak in,” says La Jolla Institute for Immunology (LJI) Assistant Professor Miguel Reina-Campos, Ph.D. “That’s a massive challenge for the immune system.”

So how do immune cells keep the gut safe? New research led by scientists at LJI, UC San Diego, and the Allen Institute for Immunology shows that pathogen-fighting immune cells called tissue-resident memory CD8 T cells (TRM cells) go through a surprising transformation—and relocation—as they fight infections in the small intestine.

In fact, these cells literally rise up higher in the tissue to fight infections before pathogens can spread to deeper, more vulnerable areas.

Peeing with your peers

 

Male chimps socializing
Photo Credit: Kyoto University, Kumamoto Sanctuary

In Italy, it has been said, there is a proverb for everything.

Chi non piscia in compagnia o è un ladro o è una spia -- "Whoever doesn't pee in the company of others is either a thief or a spy" -- goes one such saying, describing a communal act that in Japanese is known as tsuré-shon.

Social urination can be found represented in artwork across the centuries and around the world, and even today continues to be represented in cultural tropes. Now, researchers in Japan -- observing chimpanzees -- are suggesting that this phenomenon has evolutionary roots even deeper than previously expected.

Despite decades of research into other contagious behaviors such as yawning, contagious urination has never been studied scientifically in any species. To tackle this, a team at Kyoto University conducted 604 hours of direct observation at the University's Kumamoto Sanctuary, documenting 1,328 urination events. The researchers analyzed whether these were aligned in time, triggered by nearby individuals, or influenced by social relationships.