Scientific Frontline: November 2025

Sunday, November 30, 2025

FastStone Capture

Image Credit: Scientific Frontline

In the modern digital ecosystem, precise visual communication is often more valuable than text. Whether for technical documentation, customer support, or creative design, the ability to instantly capture, annotate, and share what is on your screen is a daily necessity. However, users frequently face a frustrating dichotomy: built-in operating system tools are often too rudimentary, while full-featured suites can be bloated, expensive, and resource-heavy.

FastStone Capture positions itself as the optimal middle ground—a lightweight yet feature-rich utility designed to handle everything from simple screenshots to complex screen recordings. This review examines the technology, features, and overall value of FastStone Capture to determine if it truly delivers professional-grade functionality in such a compact package.

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Materials Science is the interdisciplinary field dedicated to understanding and manipulating the relationship between the atomic or molecular structure of a material, its macroscopic properties, and how it is processed.

At its core, this discipline seeks to uncover why materials behave the way they do and how to engineer new materials with specific, tailored characteristics to solve complex technological challenges. It bridges the gap between the fundamental theory of physics and chemistry and the practical applications of engineering.

The Holocoenotic Nature of the Biosphere
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The Genesis of a Paradigm

The concept of the ecosystem represents one of the most significant intellectual leaps in the history of biological science. It is not merely a label for a collection of living things, but a sophisticated framework that integrates the chaotic multiplicity of the natural world into a coherent, functional unit. To understand the ecosystem is to understand the fundamental architecture of life on Earth. This report provides an exhaustive analysis of the ecosystem concept, tracing its historical lineage, dissecting its thermodynamic and biogeochemical engines, exploring its diverse manifestations across the globe, and evaluating its resilience in the face of unprecedented anthropogenic pressure.

When Quantum Gases Refuse to Follow the Rules

The team Frederik Møller, Philipp Schüttelkopf and Jörg Schmiedmayer
Photo Credit: © Technische Universität Wien

At TU Wien, researchers have created a one-dimensional “quantum wire” made from a gas of ultracold atoms, where mass and energy flow without friction or loss.

In physical systems, transport takes many forms, such as electric current through a wire, heat through metal, or even water through a pipe. Each of these flows can be described by how easily the underlying quantity—charge, energy, or mass—moves through a material. Normally, collisions and friction lead to resistance causing these flows to slow down or fade away. But in a new experiment at TU Wien, scientists have observed a system where that doesn’t happen at all.

By confining thousands of rubidium atoms to move along a single line using magnetic and optical fields, they created an ultracold quantum gas in which energy and mass move with perfect efficiency. The results, now published in the journal Science, show that even after countless collisions, the flow remains stable and undiminished, thus revealing a kind of transport that defies the rules of ordinary matter.

Cat in the old town of Şanlıurfa (southeastern Anatolia, Turkey).
Photo Credit: © Nadja Pöllath, SNSB

Cats are among the most successful domestic mammals; they are widespread throughout the world, even in the most remote areas around the globe. Their estimated number is around one billion. Earlier studies have shown that the domestic cat Felis catus descended from the North African wildcat Felis lybica lybica.

Archaeological remains also prove that cats joined humans almost 10,000 years ago, but the complex evolution of their domestication, particularly the geographical region, the timing and the circumstances of their spread, remain largely unclear to this day. This is partly due to the scarcity of feline remains in archaeological contexts and the difficulty of attributing skeletal fragments to wild or domesticated forms.

Image Credit: NASA

New observations made with the ERIS instrument at the Very Large Telescope facility disprove from the assumption that the supermassive black hole at the center of the Milky Way devours nearby dust objects.

An international research team led by PD Dr Florian Peißker at the University of Cologne has used the new observation instrument ERIS (Enhanced Resolution Imager and Spectrograph) at the Very Large Telescope (VLT) facility in Chile to show that several so-called ‘dusty objects’ follow stable orbits around the supermassive black hole Sagittarius A* at the center of our galaxy. Earlier studies had surmised that some of these objects could be swallowed up by the black hole. New data refutes this assumption. The findings have been published under the title ‘ABCD’ in the journal Astronomy & Astrophysics.

The study focused on four of these unusual celestial bodies, which have been the subject of much discussion in recent years. In particular, G2 was long regarded as a pure dust and gas cloud. It was thought to have been initially elongated by the gravitational pull of Sagittarius A*, a process known as 'spaghettification', before being destroyed. However, the specific observations made with ERIS, which captures radiation in the near-infrared range, show that G2 follows a stable orbit. This is an indication that there is a star inside the dust cloud. These results confirm that the center of the Milky Way is not only destructive but can also be surprisingly stable.

Albert Lu (left) and Carles Enrich (right).
Photo Credit: Courtesy of University of Barcelona

A new study describes a key molecular mechanism that explains how cells exchange information through extracellular vesicles (EVs), small particles with great therapeutic potential. The results, published in the Journal of Extracellular Vesicles, reveal that the Commander protein complex, previously known for its role in membrane recycling, also coordinates the entry and internal destination of vesicles within the cell. This finding sheds light on the process of intercellular communication, which is fundamental to the development of new therapies and diagnostic tools.

The study was led by Professor Albert Lu, from the Faculty of Medicine and Health Sciences of the UB and the CELLEX Biomedical Research Centre (IDIBAPS-UB), and María Yáñez-Mó, from the Severo Ochoa Centre for Molecular Biology (CSIC-UAM). Carles Enrich, professor at the same faculty (IDIBAPS-UB), also participated.

According to Albert Lu, “understanding how receptor cells capture and process extracellular vesicles is essential to understanding how our body communicates at the molecular level.” “Furthermore — he continues — this knowledge is key to harnessing the therapeutic and diagnostic potential of these vesicles, since their effectiveness depends on being able to direct them and have them captured by the appropriate target cells.”

Marine Biology: In-Depth Description

Photo Credit: Neeraj Pramanik

Marine Biology is the scientific study of organisms in the ocean and other brackish bodies of water. This discipline encompasses a vast spectrum of life forms, ranging from microscopic picoplankton to the blue whale, the largest animal on Earth. It is an integrative field that combines elements of geology, chemistry, physical oceanography, and biology to understand the physiology, behavior, and ecological roles of marine organisms, as well as their complex interactions with the high-salinity environment.

The difference between a wild and a domesticated variety within a species is often greater than the difference between different species.
Photo Credit: Charlotte Perhammar

LiU researchers are mapping the genetic differences between the domestic chicken and its wild relative the junglefowl. They will now try to find out whether it is possible to use genetic engineering to “undomesticated” domesticated chickens. This could be a tool for conserving endangered species – and perhaps recreating extinct animals.

Imagine a world without a dog – often called a man’s best friend. A world also without cows, pigs or sheep. If our ancestors had not domesticated many animals and plants a few thousand years ago, there would be no fields of grain, rapeseed or cotton. All animals would be wild. Humans would hunt, fish, and gather plants in nature to put food on the table. In short, virtually every aspect of our lives would be radically affected if the phenomenon of domestication were to be deleted from the history of the Earth.

A male Coho salmon, featuring the characteristic hooked nose, returns to spawn from the Oregon Coast.
Photo Credit: NOAA Fisheries

During the annual salmon run last fall, University of Washington researchers pulled salmon DNA out of thin air and used it to estimate the number of fish that passed through the adjacent river. Aden Yincheong Ip, a UW research scientist of marine and environmental affairs, began formulating the driving hypothesis for the study while hiking on the Olympic Peninsula.

“I saw the fish jumping and the water splashing and I started thinking — could we recover their genetic material from the air?,” he said.

The researchers placed air filters at several sites on Issaquah Creek, near the Issaquah Salmon Hatchery in Washington. To their amazement, the filters captured Coho salmon DNA, even 10 to 12 feet from the river. Scientists collect environmental DNA, or eDNA, to identify species living in or passing through an area, but few have attempted to track aquatic species by sampling air.

Intestines one week after abdominal irradiation, showing proliferating epithelial cells (in brown).
Image Credit: Julius Fischer / TUM

Patients receiving intensive cancer treatments often suffer from severe damage to the intestinal lining. Researchers from the Technical University of Munich (TUM) and the Leibniz Institute for Immunotherapy (LIT) have discovered that certain immune cells can trigger healing processes. They use inflammatory signals to do so - which is surprising, as inflammation in the intestine was previously thought to be primarily harmful. This finding could open new possibilities for therapies.

Regulatory T cells (Tregs), a specialized type of immune cells, are usually seen as “peacekeepers” that prevent excessive immune attacks. In a study published in Signal Transduction and Targeted Therapy, researchers from the Department of Radiation Oncology at the TUM University Hospital and the LIT Cooperation Group “Innate Immune Sensing in Cancer and Transplantation” uncovered how the body's own immune system can be harnessed to repair the intestinal lining and improve survival.

Photo Credit: Adél Grőber

People who regularly consume polyphenol-rich foods and drinks, such as tea, coffee, berries, cocoa, nuts, whole grains and olive oil, may have better long-term heart health.

The research, led by King’s College London, found that those with higher adherence to polyphenol-rich dietary patterns had lower predicted cardiovascular disease (CVD) risk.

Polyphenols are natural compounds found in plants that are linked to various health benefits, including improved heart, brain, and gut health.

The study, published today in BMC Medicine, followed more than 3,100 adults from the TwinsUK cohort for over a decade, found that diets rich in specific groups of polyphenols were linked to healthier blood pressure and cholesterol profiles, contributing to lower CVD risk scores.

Ayush Agarwal worked on the analysis of biogas during his doctoral studies at the PSI Center for Energy and Environmental Sciences at PSI.
Photo Credit: © Paul Scherrer Institute PSI/Markus Fischer

Researchers at the Paul Scherrer Institute PSI have developed a new analytical method that can detect even tiny amounts of critical impurities in biogas. This procedure can be used even by small biogas plants without the need for major investment – thus facilitating the energy transition.

The market for biogas is growing. According to the Swiss Federal Office of Energy, Switzerland fed 471 gigawatt hours of this fuel into the natural gas grid last year – roughly twice the amount fed in ten years ago. This comes with an increase in the need to measure impurities in the biogas quickly and reliably, because strict quality criteria apply to this green gas.

Researchers at PSI’s Center for Energy and Environmental Sciences have now come up with a solution to this problem. The analytical method they have developed can simultaneously detect the two most critical impurities in biogas: sulfur compounds and siloxanes. They have now presented their method in the journal Progress in Energy.

Professor Lluís Gibert, from the University of Barcelona, is the only expert from a European institution participating in an international study based on the analysis of the bones of a fossilized foot and teeth that has revealed how Australopithecus deyiremeda, a human ancestor that coexisted more than three million years ago with Australopithecus afarensis — the famous Lucy — on the plains of East Africa, moved and fed.
Photo Credit: Courtesy of University of Barcelona

In 2009, scientists found eight bones from the foot of a human ancestor in layers of ancient sediment at the Woranso-Mille site in the central Afar region of Ethiopia. The fossil remains, known as the Burtele Foot, were discovered by a team led by paleoanthropologist Yohannes Haile-Selassie, from Arizona State University (United States), but were not assigned to any fossil species of a human ancestor from the African continent.

A study now published in the journal Nature and led by Haile-Selassie solves the mystery and reveals that Burtele Foot belongs to the species Australopithecus deyiremeda, a new hominid fossil discovered years ago by the researcher’s team at the Woranso-Mille site (Nature, 2015). Thus, the study of this fossil foot — dated to about 3.4 million years ago — reveals that A. deyiremeda was an Australopithecus that walked on two limbs (bipedalism) and also lived in trees, as indicated by the presence of a prehensile big toe like that of chimpanzees.

The international team of experts includes Professor Lluís Gibert, from the Faculty of Earth Sciences of the University of Barcelona, who is the only researcher from a European institution to sign the study. Geological analyses were decisive for dating and linking this foot to the remains of A. deyiremeda.

Longitudinal sections of two injured nerves with regenerating nerve fibers. Both specimens are from diabetic animals; in the lower image, the animal was treated with a peptide. Regeneration can be seen in the green-stained nerve fibers.
Image Credit: Dietmar Fischer / University of Cologne

Researchers have decoded the signaling pathway that inhibits nerve regeneration in diabetes and have developed a therapeutic peptide that could transform the treatment—and possibly even the prevention—of diabetic nerve damage.

Nerve damage is one of the most common and burdensome complications of diabetes. Millions of patients worldwide suffer from pain, numbness, and restricted movement, largely because damaged nerve fibers do not regenerate sufficiently. The reasons for this are unclear. A research team led by Professor Dr Dietmar Fischer, Professor of Pharmacology at the University of Cologne’s Faculty of Medicine, and Director of the Center for Pharmacology at University Hospital Cologne, has now identified a central mechanism that explains limited regeneration in diabetes. Building on this, the researchers have developed a promising therapeutic approach that can be used to increase regeneration. Their findings were published in the ‘Science Translational Medicine’ journal under the title ‘Failure of nerve regeneration in mouse models of diabetes is caused by p35-mediated CDK5 hyperactivity’.

“Our climate scenarios show that we can prevent much of this by limiting climate change.," says lead author of the study, Tiem van der Deure.
Illustration Credit: University of Copenhagen

An insistent buzzing at sunset followed by itchy, spotted legs. Here in Denmark, mosquitoes are mostly an annoying – but generally harmless – nuisance. That is far from the case in many parts of the world.

Every year, around 600,000 people die from malaria, a mosquito-borne disease – most of them in sub-Saharan Africa, and children are the most vulnerable. This makes malaria one of the deadliest infectious diseases globally.

A new study from the University of Copenhagen, published in Global Change Biology, shows that future climate change could create more favorable conditions for malaria mosquitoes, exposing millions of people across large parts of Africa to more dangerous mosquito bites.

Coffee linked to slower biological ageing among those with severe mental illness – up to a limit

Photo Credit: Julia Florczak

New research from King’s College London finds that coffee consumption within the NHS recommended limit is linked to longer telomere lengths – a marker of biological ageing – among people with bipolar disorder and schizophrenia. The effect is comparable to roughly five years younger biological age.

Telomeres are structures that protect DNA. As people get older, their telomeres shorten as part of the natural human ageing process. This process has been shown to be accelerated among people with severe mental illness, such as bipolar disorder and schizophrenia, who have an average life expectancy 15 years shorter than the general population.

Previous research shows that coffee has health benefits. It may reduce oxidative stress in the general population, helping slow biological ageing processes like telomere shortening. The new study, published in BMJ Mental Health, explores whether coffee consumption could slow this ageing process among those with severe mental illness.

The Atlantic grey seal nurses its young for only 17 days. This means that the milk must be packed with good stuff to quickly prepare the seal pup for a tough life at sea. Researchers have analysed seal milk and discovered many new types of milk sugar.
Photo Credit: Patrick Pomeroy / contributing author

Researchers have discovered that milk from grey seals in the Atlantic Ocean may be more potent than breast milk. An analysis of seal milk found approximately 33 per cent more sugar molecules than in breast milk. Many of these sugars are unique and may pave the way for even better infant formulas for babies.

During the 17 days that grey seal pups suckle, they need to get their digestive systems up and running and build up an immune system to protect them against diseases and other dangers they may encounter in the North Atlantic. It is reasonable to suspect that their mother's milk is extremely refined to accomplish this task. An international study with researchers from the University of Gothenburg and Chalmers University of Technology in Nature Communications shows that this is indeed the case.

“Our analysis shows that grey seal milk is extraordinary. We identified 332 different sugar molecules, or sugars, compared to about 250 in breast milk. Two-thirds were completely unknown previously. Some of these molecules had a previously unseen size of 28 sugar units, which exceeds the largest known sugar units in breast milk, which are 18 units in size,” says Daniel Bojar, senior lecturer in bioinformatics at the University of Gothenburg.

Hurricane Florence moved toward the U.S. East Coast as it intensified to a Category 4 storm, with one-minute sustained winds of 130 mph Monday September 10, 2018. This image, captured by the GOES East satellite at 10:00 am ET, showed Florence in the western Atlantic, about 600 miles southeast of Bermuda, at Category 3 intensity. The storm had developed a small but well-defined eye and a symmetrical appearance typical of major hurricanes that are rapidly intensifying.
Image Credit: NOAA

For centuries, coastlines have attracted dense human settlement and economic activity. Today, more than 40 percent of the global population lives within 100 kilometers of the coast, facing accelerating sea-level rise, coastal erosion, flooding, and tropical cyclones.

Although moving away from the coast - known as “retreat” - is often viewed as an adaptive strategy, its global extent and drivers have remained unclear. A new study published in Nature Climate Change fills this gap by providing the first global evidence that coastal retreat is driven more by social and infrastructural vulnerability than by historical exposure to hazards.

The study was conducted by an international team led by researchers from Sichuan University and included remote sensing experts from the University of Copenhagen (Alexander Prishchepov and Shengping Ding, IGN). It maps settlement movements across 1,071 coastal regions in 155 countries. By integrating nighttime light observations with global socioeconomic datasets, the researchers found that 56% of coastal regions have retreated from the coast from 1992 to 2019, and 16% of regions, including the Copenhagen area in Denmark, have moved closer to the coast, while 28% have remained stable.

Photo Credit: Cottonbro Studio

Australian researchers have found compelling evidence that insomnia may be linked to disruptions in the brain’s natural 24-hour rhythm of mental activity, shedding light on why some people struggle to ‘switch off’ at night.

Published in Sleep Medicine, the study led by the University of South Australia (UniSA) is the first to map how cognitive activity fluctuates across the day in individuals with chronic insomnia, compared to healthy sleepers.

Insomnia affects about 10% of the population, and up to 33% of older adults, with many reporting an overactive or ‘racing’ mind at night.

While this has long been linked to cognitive hyperarousal, it has remained unclear where these thought patterns stem from.

Gamma-ray image of the Milky Way halo (with details).
Gamma-ray intensity map excluding components other than the halo, spanning approximately 100 degrees in the direction of the Galactic center. The horizontal gray bar in the central region corresponds to the Galactic plane area, which was excluded from the analysis to avoid strong astrophysical radiation.
Image Credit: ©2025 Tomonori Totani, The University of Tokyo

In the early 1930s, Swiss astronomer Fritz Zwicky observed galaxies in space moving faster than their mass should allow, prompting him to infer the presence of some invisible scaffolding — dark matter — holding the galaxies together. Nearly 100 years later, NASA’s Fermi Gamma-ray Space Telescope may have provided direct evidence of dark matter, allowing the invisible matter to be “seen” for the very first time.

Dark matter has remained largely a mystery since it was proposed so many years ago. Up to this point, scientists have only been able to indirectly observe dark matter through its effects on observable matter, such as its ability to generate enough gravitational force to hold galaxies together. The reason dark matter can’t be observed directly is because the particles that make up dark matter don’t interact with electromagnetic force — meaning dark matter doesn’t absorb, reflect or emit light.

Immunology: In-Depth Description

Image Credit: Scientific Frontline / AI generated

Immunology is the branch of biomedical science concerned with the structure, function, and disorders of the immune system—the complex network of cells, tissues, and organs that protect an organism from foreign invaders. Its primary goal is to understand how biological systems identify and eliminate pathogens (such as bacteria, viruses, fungi, and parasites) while maintaining tolerance for the body's own healthy tissue (distinguishing "self" from "non-self").

Mungbean flowers at UQ Gatton.
Photo Credit: Megan Pope

New breeding opportunities for an important cash crop have been unlocked by University of Queensland and Grains Research and Development Corporation (GRDC)-supported research.

Queensland Alliance of Agriculture and Food Innovation PhD candidate Caitlin Dudley, supported by a GRDC Research Scholarship, has revealed key insights about mungbean flowering through extensive field trials.

“Our research found that when mungbean flowers, and how long they flowers, are independent traits with distinct genetic controls,” Ms Dudley said.

“That’s important to know because it opens opportunities for breeders to optimize flowering time to improve yield for specific growing environments.

Pediatric surgery ward at Nagoya University Hospital, where laparoscopic surgery for biliary atresia is performed.
Photo Credit: Merle Naidoo, Nagoya University

Biliary atresia affects newborns when bile ducts become blocked, leading to liver damage that often requires transplants—a new study evaluates an alternative to traditional open surgery.

Nagoya University researchers and their collaborators have found that minimally invasive laparoscopic surgery significantly reduces blood loss and improves jaundice recovery compared to traditional open surgery for treating biliary atresia—a serious liver condition in newborns. The study, published in Hepatobiliary Surgery and Nutrition, also found that high-dose steroid therapy after surgery does not necessarily improve outcomes for treating this condition.

Biliary atresia affects 1 in 15,000 newborns and is the leading cause of liver transplants in children. It occurs when bile ducts become blocked or do not develop properly, which prevents effective liver function and leads to progressive damage. What causes this blockage is unknown, and surgery is usually performed within the first two to three months of birth when the condition is diagnosed.

An artist's concept of NASA’s Mars Reconnaissance Orbiter, which has been orbiting the Red Planet since 2006. The antenna is part of SHARAD, a radar that peers below the Martian surface.
Image Credit: NASA/JPL-Caltech

A new study published in Geophysical Research Letters casts doubt on a 2018 discovery of a briny lake potentially lurking beneath Mars’ south polar cap.

SHARAD, the Shallow Radar sounder on NASA’s Mars Reconnaissance Orbiter (MRO), performed a maneuver that allowed it to peer deeper beneath the polar ice than ever before. It recorded only a faint signal where MARSIS (Mars Advanced Radar for Subsurface and Ionosphere Sounding), the low-frequency radar on the European Space Agency’s Mars Express spacecraft, found a highly radar-reflective surface under the ice in 2018, which that team interpreted to be due to the presence of liquid water.

“The existence of liquid water under the south pole is really compelling and exciting, but if it is there, SHARAD should also see a very bright reflectance spot, and we don’t,” said study lead author Gareth Morgan, a SHARAD co-investigator and Planetary Science Institute senior scientist.

Silky lupine plants at Lassen National Park in California
Photo Credit: Duncan Menge

High levels of atmospheric carbon dioxide intensify climate change, but high carbon dioxide levels can also stimulate plant growth. Plant growth removes carbon dioxide from the atmosphere, partially mitigating the effects of climate change. However, plants only grow faster in the presence of high levels of carbon dioxide if they can also acquire enough nitrogen from the atmosphere to do so. The actual amount of nitrogen acquired from the atmosphere was reassessed in a study co-led by Columbia faculty that was released this summer; it was shown to be significantly lower than previously estimated.

Zacharie Potvin-Jutras, with Claudine Gauthier:
“Our goal is to examine conditions at the onset of a heart disease, before there has been any significant impact on the brain”
Photo Credit: Courtesy of Concordia University

Individuals with coronary artery disease (CAD) — a constricting or blocking of blood vessels feeding the heart — face increased risks of strokes, cognitive impairment and dementia. However, the link between CAD and cognitive function is not fully understood.

A new study led by Concordia researchers looks at how the disease affects the brain’s white matter, the network of nerve fibers that connects different regions of the brains and is critical to transmitting information efficiently.

The study, published in the Journal of Neuroscience, applied a novel multivariate approach using 12 separate metrics. The researchers compared test results and MRI scans of 43 patients with CAD to those of 36 healthy individuals. All participants were over the age of 50.

Bio-beads collected near Truro.
Photo Credit Beach Guardian

A new study shows that microplastics in the natural environment are colonized by pathogenic and antimicrobial resistant bacteria. The study team calls for urgent action for waste management and strongly recommends wearing gloves when taking part in beach cleans.

Microplastics are plastic particles less than 5mm in size and are extremely widespread pollutants. It is estimated that over 125 trillion particles have accumulated in the ocean (surface to seabed) and they have also been detected in soils, rivers, lakes, animals and the human body.

An emerging concern associated with microplastics is the microbial communities that rapidly make their home on the particle surface, forming complex biofilms known as the “Plastisphere”. These communities may often include pathogenic (disease-causing) or antimicrobial resistant (AMR) bacteria.

Image Credit: Projecte Luso/iMirabilis2/iAtlantic

An international team led by Covadonga Orejas, a researcher at the Gijón Oceanographic Centre of the Spanish Institute of Oceanography (IEO-CSIC); Veerle Huvenne, a researcher at the UK National Oceanography Centre (NOC); and Jacob González-Solís, professor at the Faculty of Biology and the Biodiversity Research Institute (IRBio) of the University of Barcelona, has published the first comprehensive study on the seamounts of the Cape Verde archipelago, their biodiversity, ecological functionality and socio-economic relevance in the journal Progress in Oceanography.

These volcanic formations — at least 14 large mountains and numerous smaller elevations — act as veritable oases of life in the deep ocean, concentrating nutrients and modifying the circulation of underwater currents. This supports exceptional biodiversity, ranging from microorganisms to communities of deep-sea corals and sponges, as well as sharks, turtles, seabirds and cetaceans. Their position between the temperate waters of the North Atlantic and the tropical waters of the South, further enhances their productivity and ecological connectivity.

A new study sheds light on why some species seem to thrive nearly everywhere, while others are rare and have very limited ranges. Pictured is the boojum tree (Fouquieria columnaris), native only to a few desert regions in Mexico's Gulf of California.
Photo Credit: Daniel Stolte

Few ideas in science have been tested and confirmed as thoroughly as evolution by natural selection. 160 years ago, Charles Darwin proposed the theory of evolution by natural selection after observing organisms that had developed highly specialized traits to better survive or reproduce in their environments. Whether the same process can explain global patterns of biodiversity, however – why most species are restricted to certain environments while a few outliers seem to be found everywhere – remains largely uncertain.

"We still are not exactly sure why most species are confined to narrow ranges, while only a few thrive nearly everywhere," said Brian Enquist, professor in the University of Arizona Department of Ecology and Evolutionary Biology and senior author of a new study providing the strongest global evidence yet that abundant plant species became so dispersed over time because of their ability to tolerate diverse climates.

An aerial view of the loop section of the West Gold Hill Dinosaur Tracksite in Colorado.
Photo Credit: Dr. Paul Murphey

An analysis of a unique looping trail of ancient footprints in the United States reveals the dinosaur which made it may have been limping.

The site near Ouray in Colorado is one of the most continuous and tightly turning sauropod trackways ever documented.

Dr. Anthony Romilio from The University of Queensland’s Dinosaur Lab analyzed more than 130 footprints along the 95.5-metre track made 150 million years ago.

“This was left in the Late Jurassic when long-necked dinosaurs such as Diplodocus and Camarasaurus roamed North America,” Dr Romilio said.

This tissue section, taken from the intestine of a mouse unable to produce the neuropeptide VIP, clearly shows the striking frequency with which certain cell types occur on the intestine's surface. These include villous cells (red), mucus-producing goblet cells (yellow), Paneth cells (pink) and stem cells (green).
Image Credit: © Charité | Luisa Barleben

The intestinal nervous system, often referred to as the "gut brain", is essential in controlling digestion and maintaining the intestinal barrier. This protective layer, made up of the intestinal mucosa, immune cells and the microbiome, shields the body from the contents of the gut. Its effectiveness depends on the delicate balance among these components. If this balance is disrupted, inflammation, allergies, or chronic intestinal diseases can arise. The intestinal mucosa serves as the body’s primary defense against pathogens. While previous studies have shown that the intestinal nervous system is involved in immune responses in addition to digestion, its role in the development of intestinal epithelial cells has remained largely unclear until now.

Ichthyology: In-Depth Description

Image Credit: Scientific Frontline / AI generated

Ichthyology is the specialized branch of zoology devoted to the scientific study of fish, encompassing all three major groups: jawless fish (Agnatha), cartilaginous fish (Chondrichthyes), and bony fish (Osteichthyes). This discipline investigates the biology, morphology, taxonomy, evolution, and behavioral patterns of the most diverse group of vertebrates on Earth, ranging from microscopic species to massive biological entities like whale sharks.

Image Credit: Scientific Frontline / stock image

Research on mice by scientists at The University of Manchester has shed new light on why the guts’ immune system changes after a stroke and how it might contribute to gastro-intestinal problems.

Published in Brain, Behavior and Immunity, the study adds to the emerging idea of the “gut-brain axis” – in which scientists suggest allows communication between the two organs in both health and disease.

The study casts more light on the biology of stroke, a life-threatening medical emergency that disrupts blood flow to parts of the brain often causing long-term effects to mobility and cognition.

Stroke patients are also at risk of secondary bacterial infections and often exhibit gastrointestinal symptoms including difficulty swallowing and constipation.

Image Credit: Scientific Frontline / stock image

Genetics is the branch of biology concerned with the study of genes, genetic variation, and heredity in organisms. It seeks to understand the molecular mechanisms by which traits are passed from parents to offspring, how the genetic code directs biological functions, and how variations in this code drive evolution and disease. At its core, genetics is the study of biological information: how it is stored, copied, translated, and mutated.

Maria Strømme, Professor of Materials Science.
Inset Photo Credit: Courtesy of Uppsala University

Consciousness is fundamental; only thereafter do time, space and matter arise. This is the starting point for a new theoretical model of the nature of reality, presented by Maria Strømme, Professor of Materials Science at Uppsala University, in the scientific journal AIP Advances. The article has been selected as the best paper of the issue and featured on the cover.

Strømme, who normally conducts research in nanotechnology, here takes a major leap from the smallest scales to the very largest – and proposes an entirely new theory of the origin of the universe. The article presents a framework in which consciousness is not viewed as a byproduct of brain activity, but as a fundamental field underlying everything we experience – matter, space, time, and life itself.

A new study involving millions of electronic health records reveals that untreated obstructive sleep apnea raises the risk of Parkinson’s disease.
Image Credit: Scientific Frontline / AI generated

New research reveals that people with untreated obstructive sleep apnea have a higher risk of developing Parkinson’s disease. However, they can significantly reduce the risk by improving the quality of their sleep by using continuous positive airway pressure, or CPAP.

The study, which published today in the journal JAMA Neurology, examined electronic health records covering more than 11 million U.S. military veterans who received care through the Department of Veterans Affairs between 1999 and 2022.

The research was led by Oregon Health & Science University and the Portland VA Health Care System.

Parkinson’s is a neurodegenerative condition that affects an estimated 1 million people nationwide, with the risk rising incrementally year by year for people over age 60.

When SDU whale researcher Olga Filatova set off on her first field trip in 2000, she spent five years looking for whales before she saw a humpback.

“It was incredibly rare to spot one back then. Today, we see them almost every day when we’re in the field,” she says. “We don’t know exactly how many humpbacks there are now, but definitely many more than when I started.”

A cautious estimate from the Endangered Species Coalition puts today’s population at around 80,000—up from just 10,000 at their lowest point. That makes humpbacks one of the great success stories of conservation.

Sika Zheng
Photo Credit: Courtesy of University of California, Riverside

A collaborative study by scientists at the University of California, Riverside, and University of Southern California reports on how a process known as alternative splicing, often described as “editing” the genetic recipe, may help explain why some mammals live far longer than others.

Published in Nature Communications, the study, which compared alternative RNA processing in 26 mammal species with maximum lifespans ranging from 2.2 to 37 years (>16-fold differences), found that changes in how genes are spliced, more than just how active they are, play a key role in determining maximum lifespan.

Photo Credit: Courtesy of University of York

Energy that would normally go to waste inside powerful particle accelerators could be used to create valuable medical isotopes, scientists have found.

The next step is to explore how the method could be scaled up to deliver clinically use

Researchers at the University of York have shown that intense radiation captured in particle accelerator “beam dumps” could be repurposed to produce materials used in cancer therapy.

Scientists have now found a way to make those leftover photons do a second job, without affecting the main physics experiments.

A beam of photons designed to investigate things like the matter that makes up our universe, could at the same time, be used to create useful medical isotopes in the diagnosis and treatment of cancer.

Photo Credit: Akram Huseyn

Elevated levels of five proteins in our blood can help predict risk of mortality, a new study from the University of Surrey finds. Scientists believe the proteins (PLAUR, SERPINA3, CRIM1, DDR1 and LTBP2), that play key roles in the development of diseases such as cancer and inflammation, may also contribute to the risk of dying. Findings could help clinicians identify individuals most at risk from mortality and lead to earlier medical interventions.

The study also discovered 392 proteins associated with an increased risk of death within a 5-year timeframe and a further 377 proteins associated with dying within 10 years, even when adjusting for health and lifestyle factors, such as smoking or pre-existing disease diagnoses. Proteins perform a wide range of essential functions in the body and are vital for growth, development, and the structure of every cell.

Glaciers transport sediments from Antarctica to the coast.
Photo Credit: Dr Kate Winter, Northumbria University

Research involving scientists from Newcastle University has revealed new hope in natural environmental systems found in Antarctica which could help mitigate the overall rise of carbon dioxide.

As Antarctica's ice sheets thin due to climate change, newly exposed mountain peaks could significantly increase the supply of vital nutrients to the Southern Ocean which surrounds the continent, potentially enhancing its ability to absorb atmospheric carbon dioxide over long timescales, according to the research published in Nature Communications.

Led by Northumbria University, a team of scientists looked at analysis of sediment samples from East Antarctica's Sør Rondane Mountains. They discovered that weathered rocks exposed above the ice surface contain iron concentrations up to ten times higher than previously reported from the Antarctic continent. This bioavailable iron is transported to the ocean by glaciers and icebergs, where it fuels the growth of phytoplankton – microscopic marine organisms that absorb CO₂ through photosynthesis.

A DNA strand with a highlighted area indicating a mutation
Image Credit: Scientific Frontline

Every human has tens of thousands of tiny genetic alterations in their DNA, also known as variants, that affect how cells build proteins.

Yet in a given human genome, only a few of these changes are likely to modify proteins in ways that cause disease, which raises a key question: How can scientists find the disease-causing needles in the vast haystack of genetic variants?

For years, scientists have been working on genome-wide association studies and artificial intelligence tools to tackle this question. Now, a new AI model developed by Harvard Medical School researchers and colleagues has pushed forward these efforts. The model, called popEVE, produces a score for each variant in a patient’s genome indicating its likelihood of causing disease and places variants on a continuous spectrum.

What is the evolutionary advantage of our consciousness? And what can we learn about this from observing birds? Researchers at Ruhr University Bochum published two articles on this topic.

Although scientific research about consciousness has enjoyed a boom in the past two decades, one central question remains unanswered: What is the function of consciousness? Why did it evolve at all? The answers to these questions are crucial to understanding why some species (such as our own) became conscious while others (such as oak trees) did not. Furthermore, observing the brains of birds shows that evolution can achieve similar functional solutions to realize consciousness despite different structures. The working groups led by Professors Albert Newen and Onur Güntürkün at Ruhr University Bochum, Germany, report their findings in a current special issue of the journal Philosophical Transactions of the Royal Society B.

Kleopatra

Image Credit: Scientific Frontline

In the modern digital ecosystem, the email inbox and local file storage remain vulnerable entry points for surveillance, data theft, and unauthorized access. While transport layer security (TLS) protects data in transit, it often leaves the data itself exposed at rest or at the endpoints. For professionals in journalism, law, science, and academia, relying solely on provider-managed security is increasingly insufficient.

The challenge lies in complexity: robust encryption standards like OpenPGP are historically difficult for non-technical users to implement, often requiring cumbersome command-line interactions.

Researchers at WashU Medicine have developed a noninvasive medicine delivered through the nose that successfully eliminated deadly brain tumors in mice. The medicine is based on a spherical nucleic acid, a nanomaterial (labeled red) that travels along a nerve (green) from the nose to the brain, where it triggers an immune response to eliminate the tumor.
Image Credit: Courtesy of Alexander Stegh

Researchers at Washington University School of Medicine in St. Louis, along with collaborators at Northwestern University, have developed a noninvasive approach to treat one of the most aggressive and deadly brain cancers. Their technology uses precisely engineered structures assembled from nano-size materials to deliver potent tumor-fighting medicine to the brain through nasal drops. The novel delivery method is less invasive than similar treatments in development and was shown in mice to effectively treat glioblastoma by boosting the brain’s immune response.

Glioblastoma tumors form from brain cells called astrocytes and are the most common kind of brain cancer, affecting roughly three in 100,000 people in the U.S. Glioblastoma generally progresses very quickly and is almost always fatal. There are no curative treatments for the disease, in part because delivering medicines to the brain remains extremely challenging.

The new study was led by Pandurangan Vijayanand, M.D., Ph.D., William K. Bowes Distinguished Professor at La Jolla Institute for Immunology
Photo Credit: Courtesy of La Jolla Institute for Immunology

We owe a lot to tissue resident memory T cells (TRM). These specialized immune cells are among the body’s first responders to disease.

Rather than coursing through the bloodstream—as many T cells do—our TRM cells specialize in defending specific organs. They battle viruses, breast cancer, liver cancer, melanomas, and many other health threats.

Pandurangan Vijayanand, M.D., Ph.D., William K. Bowes Distinguished Professor at La Jolla Institute for Immunology (LJI), has even shown that a greater density of TRM cells is linked to better survival outcomes in lung cancer patients.

What Is: Mitochondrion

Evolutionary Singularities and the Eukaryotic Dawn

The mitochondrion represents a biological singularity, a discrete evolutionary event that fundamentally partitioned life on Earth into two distinct energetic stratums: the prokaryotic and the eukaryotic. While colloquially reduced to the moniker of "cellular powerhouse," the mitochondrion is, in functional reality, a highly integrated endosymbiont that serves as the master regulator of eukaryotic physiology. It is the nexus of cellular respiration, the arbiter of programmed cell death, a buffer for intracellular calcium, and a hub for biosynthetic pathways ranging from heme synthesis to steroidogenesis. To comprehend the complexity of multicellular life, one must first dissect the intricate molecular sociology of this organelle.

The origin of the mitochondrion is the subject of intense phylogenomic reconstruction. The prevailing consensus, the endosymbiotic theory, posits that the mitochondrion descends from a free-living bacterial ancestor—specifically a lineage within the Alphaproteobacteria—that entered into a symbiotic relationship with a host archaeal cell approximately 1.5 to 2 billion years ago. This was not a trivial acquisition but a transformative merger. The energetic capacity afforded by the internalization of a bioenergetic specialist allowed the host cell to escape the surface-area-to-volume constraints that limit prokaryotic genome size, facilitating the expansion of the nuclear genome and the development of complex intracellular compartmentalization.

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