New advances to boost regeneration and plasticity of brain neurons

The study is led by Professor Daniel Tornero and researcher Alba Ortega , from the Faculty of Medicine and Health Sciences and the Institute of Neurosciences of the University of Barcelona
Photo Credit: Courtesy of University of Barcelona

The brain’s mechanisms for repairing injuries caused by trauma or degenerative diseases are not yet known in detail. Now, a study by the University of Barcelona describes a new strategy based on stem cell therapy that could enhance neuronal regeneration and neuroplasticity when this vital organ is damaged. The results reveal that the use of brain-derived neurotrophic factor (BDNF), combined with stem cell-based cell therapies, could help in the treatment of neurodegenerative diseases or brain injuries.

Combining cell therapy with BDNF production

BDNF is a protein that is synthesized mainly in the brain and plays a key role in neuronal development and synaptic plasticity. Several studies have described its potential to promote neuronal survival and growth, findings that are now extended by the new study.

“The findings indicate that BDNF can promote the maturation and increase the activity of neurons generated in the laboratory from donor skin cells. The skin cells must first be reprogrammed to become induced pluripotent stem cells (iPSCs), and then differentiated to obtain neuronal cultures,” says Daniel Tornero, from the UB’s Department of Biomedicine and the CIBER Area for the Neurodegenerative Diseases (CIBERNED).

In this way, the study combines cell therapy with the production of BDNF in the same cells. This study confirms the beneficial effects of this growth factor in neuronal cultures derived from human stem cells, the same cells that are used in cell therapy to treat, for example, stroke in animal models.

Study links wind-blown dust from receding Salton Sea to reduced lung function in area children

Researchers with the UC Irvine-led study sample dust at the southern edge of the Salton Sea. Joe C. Wen School of Population & Public Health
Photo Credit: Courtesy of University of California, Irvine

Children living near the Salton Sea, in Southern California’s desert region of Imperial County, are experiencing poorer lung function than children exposed to less wind-blown dust, according to a new study led by researchers at the University of California, Irvine’s Joe C. Wen School of Population & Public Health.

They found that higher dust exposure – measured in hours per year – was linked to lower lung function, with the negative effects most pronounced among children living closest to the lake. The work, published in the American Journal of Respiratory and Critical Care Medicine, marks one of the first investigations to directly link dust events from a drying saline lake to measurable declines in children’s respiratory health.

A federal grant from the National Institute of Environmental Health Sciences and the Southern California Environmental Health Sciences Center funded the research in partnership with the Imperial Valley community-based organization Comite Civico del Valle.

The tides are changing for white dwarfs

Impression of the 6.9 minute double white dwarf binary J1539+5027, composed of a tidally heated white dwarf (yellow) and its more compact companion (blue). It is about to start mass transferring.
 Image Credit: KyotoU / Lucy McNeill

White dwarfs are the compact remnants of stars that have stopped nuclear burning, a fate that will eventually befall our sun. These extremely dense objects are degenerate stars because their structure is counterintuitive: the heavier they are, the smaller they are.

White dwarfs often form binary systems, in which two stars orbit one another. The majority of these are ancient even by galactic standards, and have cooled to surface temperatures of about 4,000 degrees Kelvin. However, recent studies have revealed a class of short period binary systems in which the stars orbit each other faster than once per hour. Contrary to theoretical models, these stars are inflated to twice the size as expected due to surface temperatures of 10 to 30 thousand degrees Kelvin.

Binding power of trapped water demonstrated for the first time

Water molecules are a driving force in the formation of molecular bonds, such as in proteins.
Image Credit: INT, KIT

Water is everywhere – it covers most of the earth, circulates in the human body and can be found in even the smallest molecular niches. But what happens if water does not flow freely but is trapped in such structures? Researchers at the Karlsruhe Institute of Technology (KIT) and Constructor University in Bremen have proven for the first time that "locked" water can influence its environment and strengthen the bond between molecules. This finding could open new avenues for the development of drugs and materials.

Some of the water on Earth is found in tiny nooks and crannies – enclosed in molecular pockets, such as protein binding sites or synthetic receptors. Whether this water behaves neutrally in the presence of other molecules or influences their binding has so far been controversial. "Water molecules usually interact most strongly with each other. However, experimental data showed that water behaves unusually in such narrow pockets", says Dr. Frank Biedermann from KIT's Institute of Nanotechnology. "We have now been able to provide the theoretical basis for these observations and prove that the water in the molecular pockets is energetically tense."

Russian Physicists Found a Way to Speed Up the Process of Developing Solar Panels

According to Ivan Zhidkov, this method allows for the quick selection of only promising materials.
 Photo Credit: Rodion Narudinov

Physicists at Ural Federal University and their colleagues from the Institute of Problems of Chemical Physics of the Russian Academy of Science (IPCP RAS) have found a way to significantly reduce the thousands of hours required for developing perovskite solar panel technology. Scientists have proposed a method that allows us  to determine in a few hours whether solar panels will fail quickly or if the development is promising with a potentially long service life. The test results were published in the journal Physica B: Condensed Matter.

Perovskite films are promising energy converters for various photoelectronic devices, such as solar cells, LEDs, and photodetectors. They have excellent optoelectronic properties and can be grown relatively easily at a low production cost.

Geologists discover the first evidence of 4.5-billion-year-old “proto-Earth”

“This is maybe the first direct evidence that we’ve preserved the proto Earth materials,” says Nicole Nie. An artist’s illustration shows a rocky proto Earth bubbling with lava.
Image Credit: MIT News; iStock
(CC BY-NC-ND 4.0)

Scientists at MIT and elsewhere have discovered extremely rare remnants of “proto-Earth,” which formed about 4.5 billion years ago, before a colossal collision irreversibly altered the primitive planet’s composition and produced the Earth as we know today. Their findings, reported today in the journal Nature Geosciences, will help scientists piece together the primordial starting ingredients that forged the early Earth and the rest of the solar system.

Billions of years ago, the early solar system was a swirling disk of gas and dust that eventually clumped and accumulated to form the earliest meteorites, which in turn merged to form the proto-Earth and its neighboring planets.

In this earliest phase, Earth was likely rocky and bubbling with lava. Then, less than 100 million years later, a Mars-sized meteorite slammed into the infant planet in a singular “giant impact” event that completely scrambled and melted the planet’s interior, effectively resetting its chemistry. Whatever original material the proto-Earth was made from was thought to have been altogether transformed.

“Cocktails” of common pharmaceuticals in our waterways may promote antibiotic resistance

Photo Credit: Nana K.

New research has shown, for the first time, how mixtures of commonly used medications which end up in our waterways and natural environments might increase the development of antibiotic-resistant bacteria.

When humans or animals take medications, as much as 90 percent can pass through the body and into natural environments, via waste-water, or run-off from fields, ending up in the ocean. 

In the environment, this build-up of antibiotic medicines can accumulate to a strength sufficient to kill the bacteria that live there; this can result in bacteria evolving defenses that help them to survive these concentrations, which can mean they are also resistant to antibiotics used to treat them if they later infect humans. However, less is known about how build-up of other medicines also affects bacteria, and until now, scientists have largely investigated the effect of these medications on triggering this antibiotic resistance one-at-a-time. 

Extra Silver Atom Sparks Breakthrough in Photoluminescence of Silver Nanoclusters

Structural architectures of anion-templated (a) Ag78 and (b) Ag79 NCs. Hydrogen atoms are omitted for clarity.
Image Credit: ©Yuichi Negishi et al.

A team of researchers from Tohoku University, Tokyo University of Science, and the Institute for Molecular Science have uncovered how the precise addition of a single silver (Ag) atom can dramatically transform the light-emitting properties of high-nuclear Ag nanoclusters (NCs). The study reports a remarkable 77-fold increase in photoluminescence (PL) quantum yield (QY) at room temperature - a milestone that paves the way for practical applications in optoelectronics and sensing technologies. The findings were published in the Journal of the American Chemical Society.

Photoluminescence quantum yield is an important metric used to evaluate the efficiency of photoluminescence, which is how well a material can absorb energy and convert it into light. Improving PLQY positively impacts technology such as OLEDs in TV screens.

Earth’s continents stabilized due to furnace-like heat

A new study of the chemical components of rocks led by researchers at Penn State and Columbia University provides the clearest evidence yet for how Earth's continents became and remained so stable — and the key ingredient is heat. 
Photo Credit: Jaydyn Isiminger / Penn State
(CC BY-NC-ND 4.0)

The new discovery has implications beyond geologic history, such as the search for critical minerals and habitable planets beyond Earth

For billions of years, Earth’s continents have remained remarkably stable, forming the foundation for mountains, ecosystems and civilizations. But the secret to their stability has mystified scientists for more than a century. Now, a new study by researchers at Penn State and Columbia University provides the clearest evidence yet for how the landforms became and remained so stable — and the key ingredient is heat. 

In a paper published today (Oct. 13) in the journal Nature Geoscience, the researchers demonstrated that the formation of stable continental crust — the kind that lasts billions of years — required temperatures exceeding 900 degrees Celsius in the planet’s lower continental crust. Such high temperatures, they said, were essential for redistributing radioactive elements like uranium and thorium. The elements generate heat as they decay, so as they moved from the bottom to the top of the crust, they carried heat out with them and allowed the deep crust to cool and strengthen.

Scientists uncover a new way to forecast eruptions at mid-ocean ridges through hydrothermal vent temperatures

Data loggers deployed at hydrothermal vents on the East Pacific Rise record temperature of vent fluids every ten minutes for up to a year.
Photo Credit: Photo courtesy of Jill McDermott, Lehigh Univ.; WHOI, NDSF, Alvin Team; Funder: National Science Foundation. © Woods Hole Oceanographic Institution

A new study provides scientists with a powerful new tool for monitoring and predicting tectonic activity deep beneath the seafloor at mid-ocean ridges—vast underwater mountain chains that form where Earth’s tectonic plates diverge.

The study, titled “Hydrothermal vent temperatures track magmatic inflation and forecast eruptions at the East Pacific Rise, 9°50'N,” reveals that fluctuations in the temperature of fluids flowing from hydrothermal vents occurring over minutes to years indicate the effects of magmatic and tectonic processes that occur miles beneath the seafloor. The research offers the first evidence that these subtle but detectable temperature changes could offer the means to predict seafloor volcanic eruptions.

Led by Thibaut Barreyre of the French National Centre for Scientific Research (CNRS) and University of Brest, with collaborators from Woods Hole Oceanographic Institution (WHOI), Lehigh University, and Scripps Institution of Oceanography, the study presents a 35-year time-series of temperature measurements from five hydrothermal vents along the East Pacific Rise, one of the most active segments and well-studied of the global mid-ocean ridge system.