‘Worms in space’ experiment aims to investigate the biological effects of spaceflight

Petri Pod
Photo Credit: University of Exeter

A crew of tiny worms will be heading on a mission to the International Space Station in 2026 that will help scientists understand how humans can travel through space safely, using a Leicester-built space pod. The experiment is based upon a concept and early development by the University of Exeter over more than 8 years 

A team of scientists and engineers at Space Park Leicester, the University of Leicester’s pioneering £100 million science and innovation park, have designed and built a miniature space laboratory called a Petri Pod, based around the principle of the biological culture petri dish invented in 1887 and based upon earlier development work by the University of Exeter and Leicester, that will allow scientists on Earth to study biological organisms in space. 

There is a burgeoning global drive for humans to colonize space, the Moon, and other planets of our Solar System, but one of the challenges is the harmful effects of extended exposure to the effects of the space environment on human physiology. This includes microgravity which can lead to bone and muscle loss, fluid shift, and vision problems in humans as well as radiation-induced effects of genetic damage, increased cancer risk, etc. 

Rocks on Faults Can Heal Following Seismic Movement

At the Cascadia subduction zone in the Pacific Northwest, one tectonic plate is moving underneath another. New experimental work at UC Davis shows how rocks on faults deep in the Earth can cement themselves back together after a seismic movement, adding to our knowledge of how these faults behave.
Photo Credit: of Otter Rock, Oregon by USGS

Earthquake faults deep in the Earth can glue themselves back together following a seismic event, according to a new study led by researchers at the University of California, Davis. The work, published in Science Advances and supported by grants from the National Science Foundation, adds a new factor to our understanding of the behavior of faults that can give rise to major earthquakes. 

“We discovered that deep faults can heal themselves within hours,” said Amanda Thomas, professor of earth and planetary sciences at UC Davis and corresponding author on the paper. “This prompts us to reevaluate fault rheological behavior, and if we have been neglecting something very important.” 

How plants search for nutrients

In the case of nutrient deficiency, efficient plants are able to grow long, lateral roots to broaden the radius from which they can take nutrients.
Photo Credit: Andreas Heddergott / Technische Universität München

What makes plants tolerant to nutrient fluctuations? An international research team led by the Technical University of Munich (TUM) and involving the Leibniz Institute of Plant Genetics and Crop Plant Research (IPK) has investigated this question on the micronutrient boron. The researchers analyzed 185 gene data sets from the model plant Arabidopsis. Their goal is to then be able to transfer the findings to the important crop plant rapeseed. 

Boron is one of the key micronutrients for the growth and fertility of many plants. However, extreme weather events reduce the availability of this nutrient: drought reduces boron uptake, while flooding washes the nutrient out of the soil – less boron reaches the plants. In the context of climate change, this deficiency represents an additional stressor for plants. Their tolerance to these fluctuations is a decisive factor in determining their yields. 

Study shows waste cardboard is effective for power generation

Photo Credit: Jon Moore

A new study has shown for the first time that waste cardboard can be used as an effective source of biomass fuel for large scale power generation. 

Engineers from the University of Nottingham have provided the first comprehensive characterization of cardboard as a potential fuel source and created a new method to assess the composition of the material providing a practical tool for fuel assessment for cardboards. The study has been published in the journal Biomass and Bioenergy. 

Human biology is ill-adapted to modern cities

A new study has found that modern cities are having a huge impact on our health and wellbeing.
Photo Credit: Patrick Robert Doyle

Researchers from Loughborough University and the University of Zurich found that rapid industrialization has reshaped human habitats so dramatically that our biology may no longer be able to keep up. 

The paper, published in Biological Reviews, highlights that densely populated, polluted, and industrialized environments are impairing core biological functions essential for survival and reproduction (i.e., the ‘evolutionary fitness’ of our species). 

Scientists observe metabolic activity of individual lipid droplets in real time

LipiPB Red shows longer fluorescence lifetimes in stable lipid droplets (red) and shorter lifetimes as they undergo degradation (blue). This probe revealed that lipid droplets sequentially degrade, where lipolysis precedes lipophagy.
Image Credit: Issey Takahashi, Nagoya University

A research team has developed a fluorescent probe that allows scientists to visualize how individual lipid droplets break down inside living cells in real time. The probe changes its fluorescence properties depending on the chemical composition of each droplet, which allows researchers to observe not only their location within cells, but also their metabolic activity during lipid breakdown. The findings, published in the Journal of the American Chemical Society, may contribute to the development of new strategies to treat metabolic diseases such as obesity and diabetes, as well as cancers associated with abnormal lipid metabolism. 

“Lipid droplets are cellular organelles that not only store excess lipids but also play critical roles in lipid metabolism. However, understanding how individual droplets function has been challenging,” Professor Shigehiro Yamaguchi, from the Institute of Transformative Bio-Molecules (ITbM) at Nagoya University, explained. 

Extending the Lifespan of Electrocatalysts

The image shows the nanosized atom probe tomography specimens on a silicon microtip coupon.
Photo Credit: © Tong Li

A research team has discovered how to keep a cobalt-based oxide electrocatalyst active and stable. The element chromium plays a crucial role in this process.  

Although chromium itself is not an active element, its continuous dissolution enables a reversible surface transformation that keeps the Co-Cr spinel oxide electrocatalyst active and stable. This could significantly improve the efficiency of hydrogen production. These findings stem from researchers at Ruhr University Bochum, Germany, the Max Planck Institutes for Sustainable Materials in Düsseldorf and for Coal Research in Mülheim, Forschungszentrum Jülich and the Helmholtz Institute for Renewable Energies in Erlangen-Nürnberg. They report their results in the journal Nature Communications. 

Seeing infrared with organic electrodes

Organic electrodes
Electrophysiological recording of retinal activity on a precision setup using controlled red-light conditions that do not alter the retina’s response. The experiment captures how the retina reacts to infrared photovoltaic stimulation
Photo Credit: Technische Universität Wien

In some people, the light receptors on the retina are damaged, but the underlying nerve structure is still intact. In this case, a visual implant could potentially help in the future: Biocompatible, thin photovoltaic films register radiation, convert it into electrical signals, and use these to stimulate living nerve tissue. This has now been achieved for the first time in laboratory tests at TU Wien. 

Microplastics hit male arteries hard

Changcheng Zhou Professor, Biomedical Sciences
Photo Credit: Courtesy of University of California, Riverside

A mouse study led by University of California, Riverside biomedical scientists suggests that everyday exposure to microplastics — tiny fragments shed from packaging, clothing, and countless plastic products — may accelerate the development of atherosclerosis, the artery-clogging process that leads to heart attacks and strokes. The harmful effects were seen only in male mice, offering new clues about how microplastics may affect cardiovascular health in humans.

“Our findings fit into a broader pattern seen in cardiovascular research, where males and females often respond differently,” said lead researcher Changcheng Zhou, a professor of biomedical sciences in the UCR School of Medicine. “Although the precise mechanism isn’t yet known, factors like sex chromosomes and hormones, particularly the protective effects of estrogen, may play a role.”

Researchers link Antarctic ice loss to ‘storms' at the ocean's subsurface

Mattia Poinelli, a UC Irvine postdoctoral scholar in Earth system science and NASA JPL research affiliate, outlines in a newly published study the impact of submesoscale events – small, subsurface ocean eddies and vortices – on Antarctica’s ice sheets. “Despite being largely overlooked in the context of ice-ocean interactions,” he says, “[they] are among the primary drivers of ice loss.”
Photo Credit: Steve Zylius / UC Irvine

Researchers at the University of California, Irvine and NASA’s Jet Propulsion Laboratory have identified stormlike circulation patterns beneath Antarctic ice shelves that are causing aggressive melting, with major implications for global sea level rise projections.

In a paper published recently in Nature Geoscience, the scientists say their study is the first to examine ocean-induced ice shelf melting events from a weather timescale of just days versus seasonal or annual timeframes. This enabled them to match “ocean storm” activity with intense ice melt at Thwaites Glacier and Pine Island Glacier in the climate change-threatened Amundsen Sea Embayment in West Antarctica.

The research team relied on climate simulation modeling and moored observation tools to gain 200-meter-resolution pictures of submesoscale ocean features between 1 and 10 kilometers across, tiny in the context of the vast ocean and huge slabs of floating ice in Antarctica.