Comment

Comment by Dr. Krishna Kumari Challa on April 16, 2025 at 8:43am

Heart valve abnormality is associated with malignant arrhythmias, study reveals

People with a certain heart valve abnormality are at increased risk of severe heart rhythm disorders, even after successful valve surgery. This is according to a new study, "Mitral annular disjunction and mitral valve prolapse: long-term risk of ventricular arrhythmias after surgery" , published in the European Heart Journal.

The condition is more common in women and younger patients with valve disorder and can, in the worst case, lead to sudden cardiac arrest.

Mitral annular disjunction, MAD, is a heart abnormality in which the mitral valve attachment "slides." In recent years, the condition has been linked to an increased risk of severe cardiac arrhythmias. Until now, it has not been known whether the risk of arrhythmias disappears if MAD is surgically corrected.

MAD is often associated with a heart disease called mitral valve prolapse, which affects 2.5% of the population and causes one of the heart's valves to leak. This can lead to blood being pumped backward in the heart, causing heart failure and arrhythmias. The disease can cause symptoms such as shortness of breath and palpitations.

In the current study, researchers  investigated the risk of cardiac arrhythmias in 599 patients with mitral valve prolapse who underwent heart surgery at Karolinska University Hospital between 2010 and 2022. Some 16% of the patients also had the cardiac abnormality MAD.

The researchers have been able to show that people with MAD have a significantly higher risk of suffering from ventricular arrhythmias, a dangerous type of heart rhythm disorder that, in the worst case, can lead to cardiac arrest in a subset of patients.

People with MAD were more likely to be female and were on average eight years younger than those without MAD. They also had more extensive mitral valve disease. Although the surgery was successful in correcting MAD, these patients had more than three times the risk of ventricular arrhythmias during five years of follow-up compared to patients without preoperative MAD.

These results show that it is important to closely monitor patients with this condition, even after a successful operation, say the researchers.

The study has led to new hypotheses that the researchers are now investigating further. One hypothesis is that MAD causes permanent changes in the heart muscle over time. Another is that MAD is a sign of an underlying heart muscle disease.

The researchers are now continuing to study scarring in the heart using MRI (magnetic resonance imaging) and analyze tissue samples from the heart muscle.

Bahira Shahim et al, Mitral annular disjunction and mitral valve prolapse: long-term risk of ventricular arrhythmias after surgery, (2025). DOI: 10.1093/eurheartj/ehaf195

Comment by Dr. Krishna Kumari Challa on April 16, 2025 at 8:14am

Abscisic acid was applied to maize roots to chemically induce stomatal closure. Plants exposed to dust laden with PET MPs under these conditions showed significantly lower absorption in leaf tissue, confirming that open stomata are crucial for foliar uptake of airborne MPs.

Plastic particles absorbed through leaves accumulated in measurable quantities across multiple species and sites. Airborne PET and PS entered leaves through stomata and moved along internal pathways to vascular tissues and trichomes.

Concentrations increased with exposure time, environmental levels, and leaf age. Field measurements showed that plastic accumulation in aboveground plant parts exceeds what is typically absorbed through roots.

Widespread detection of plastic polymers and fragments in edible plant parts confirms atmospheric exposure as a significant route of entry into vegetation. As leaves function as a primary source in terrestrial food chains, the presence of accumulated MPs suggests the potential for exposure to multiple layers of the ecosystem.

With plastics around, even vegetarians are not safe!

 Ye Li et al, Leaf absorption contributes to accumulation of microplastics in plants, Nature (2025). DOI: 10.1038/s41586-025-08831-4

Willie Peijnenburg, Airborne microplastics enter plant leaves and end up in our food, Nature (2025). DOI: 10.1038/d41586-025-00909-3

Part 2

Comment by Dr. Krishna Kumari Challa on April 16, 2025 at 8:13am

Airborne microplastics infiltrate plant leaves, raising environmental concerns

Researchers have found that plant leaves can directly absorb microplastics (MPs) from the atmosphere, leading to a widespread presence of plastic polymers in vegetation. Concentrations of polyethylene terephthalate (PET) and polystyrene (PS) were detected in leaves collected from multiple environments, including urban areas and agricultural sites. The study is published in the journal Nature.

Researchers performed field investigations and laboratory simulation experiments to quantify plastic accumulation in plant leaves. Leaf absorption was confirmed as a significant pathway for plastic accumulation in plants, with evidence of translocation into vascular tissue and retention in specialized structures like trichomes.

MPs have been detected throughout terrestrial environments, including soil, water, and air. Laboratory studies have shown that plant roots can absorb MPs, with submicrometer and nanometer-sized particles of PS and polymethylmethacrylate transported upward from the roots of Triticum aestivum, Lactuca sativa, and Arabidopsis thaliana. Root uptake through the apoplastic pathway has been observed, yet translocation to shoots occurs slowly.

Airborne MPs have been measured at concentrations between 0.4 and 2,502 items per cubic meter in urban settings such as Paris, Shanghai, Southern California, and London. Laboratory experiments demonstrated the foliar absorption of nanoparticles including Ag, CuO, TiO₂, and CeO₂.

Plastic particles have been shown to deposit on plant surfaces, and some studies reported internal accumulation following exposure to high levels of commercial PS models.

At the most polluted sites, concentrations of PET reached tens of thousands of nanograms per gram of dry leaf weight. PS levels followed a similar pattern, with the highest values detected in leaves from the landfill site.

PET and PS were also found in nine leafy vegetables, with open-air crops exhibiting higher levels than greenhouse-grown counterparts. Nano-sized PET and PS were visually confirmed in plant tissue.

Older leaves and outer leaves of vegetables accumulated more plastic than newly grown or inner leaves, suggesting an accumulation over time.

Laboratory exposure of maize to plastic-laden dust resulted in measurable PET absorption in leaf tissue after just one day. PET was not detected in roots or stems under similar root-exposure conditions. Fluorescent and europium-labeled particles enabled visualization of stomatal entry and subsequent migration through the apoplastic pathway.

Part 1

Comment by Dr. Krishna Kumari Challa on April 15, 2025 at 11:05am

Repeated treatment with malaria medication can decrease its effect

In a recently published article in the journal Nature Communications, researchers present results indicating that repeated treatment with piperaquine, an antimalarial drug, can lead to the parasites developing decreased sensitivity to this drug. These findings may impact the use of piperaquine in the future.

Piperaquine is an important antimalarial drug characterized by a long half-life, meaning it remains in the body for several weeks and protects against new infections. This is a key asset of this drug. However, the researchers behind the study have discovered that this advantage can disappear with repeated treatment in areas with high malaria transmission.

The study shows that repeated treatment with dihydroartemisinin-piperaquine can lead to parasites developing drug tolerance by duplicating the plasmepsin 3 (pm3) gene. This allows them to reinfect patients earlier than expected during the expected protective period, reducing piperaquine's effectiveness as a prophylactic medicine.

 Leyre Pernaute-Lau et al, Decreased dihydroartemisinin-piperaquine protection against recurrent malaria associated with Plasmodium falciparum plasmepsin 3 copy number variation in Africa, Nature Communications (2025). DOI: 10.1038/s41467-025-57726-5

Comment by Dr. Krishna Kumari Challa on April 15, 2025 at 11:03am

Modified antibody fragment blocks fertilization, paving way for nonhormonal contraceptive

Current methods of contraception rely on hormones, which can cause side effects such as mood changes, headaches or increased risk of blood clots. Blocking fertilization on the surface of the egg has been proposed as an alternative, but antibodies were deemed unsuitable due to possible immune responses triggered by their Fc region.

A new study  shows how a small antibody fragment can block fertilization by targeting a key protein on the surface of the egg. This discovery brings a nonhormonal contraceptive one step closer to reality. The study has been published in the Proceedings of the National Academy of Sciences.

In the study, the researchers describe how a modified antibody fragment can block fertilization by targeting the protein ZP2 on the surface of the egg. 

This small antibody fragment can block fertilization by targeting ZP2, a key protein in the outer layer of the egg that is involved in both sperm binding and blocking polyspermy.

The researchers have used X-ray crystallography to map the interaction between the antibody IE-3, which is known to prevent fertilization in mice, and ZP2 at the atomic level. A modified, smaller version of the antibody (scFV) was found to be equally effective, blocking fertilization in 100% of IVF tests with mouse eggs. Because it lacks the immune-triggering Fc region of the full antibody, scFV minimizes potential side effects.

Elisa Dioguardi et al, Structural basis of ZP2-targeted female nonhormonal contraception, Proceedings of the National Academy of Sciences (2025). DOI: 10.1073/pnas.2426057122

Comment by Dr. Krishna Kumari Challa on April 15, 2025 at 9:58am

Radiation from CT scans could account for 5% of all cancer cases a year, study suggests

CT can save lives, but its potential harms are often overlooked. CTs expose patients to ionizing radiation—a carcinogen—and it's long been known that the technology carries a higher risk of cancer.

Radiation from CT scans may account for 5% of all cancers annually, according to a new study  that cautions against overusing and overdosing CTs.

The danger is greatest for infants, followed by children and adolescents. But adults are also at risk, since they are the most likely to get scans.

Nearly 103,000 cancers are predicted to result from the 93 million CTs that were performed in 2023 alone. This is three to four times more than previous assessments, the researchers say.

The researchers said some CT scans are unlikely to help patients and are overused, such as those for upper respiratory infections or for headaches without concerning signs or symptoms. They said patients could lower their risk by getting fewer of these scans, or by getting lower-dose scans.

There is currently unacceptable variation in the doses used for CT, with some patients receiving excessive doses. 

JAMA Internal Medicine (2025). jamanetwork.com/journals/jamai … ainternmed.2025.0505

Comment by Dr. Krishna Kumari Challa on April 15, 2025 at 9:51am

Drug pollution in water

The drugs we take, from anxiety medications to antibiotics, don't simply vanish after leaving our bodies. Many are not fully removed by wastewater treatment systems and end up in rivers, lakes, and streams, where they can linger and affect wildlife in unexpected ways.

The new  findings suggest that even tiny traces of drugs in the environment can alter animal behavior in ways that may shape their survival and success in the wild.

A recent global survey of the world's rivers found drugs were contaminating waterways on every continent—even Antarctica. These substances enter aquatic ecosystems not only through our everyday use, as active compounds pass through our bodies and into sewage systems, but also due to improper disposal and industrial effluents.

To date, almost 1,000 different active pharmaceutical substances have been detected in environments worldwide.

Particularly worrying is the fact that the biological targets of many of these drugs, such as receptors in the human brain, are also present in a wide variety of other species. That means animals in the wild can also be affected.

In fact, research over the last several decades has demonstrated that pharmaceutical pollutants can disrupt a wide range of traits in animals, including their physiology, development, and reproduction.

https://www.science.org/doi/10.1126/science.adp7174

Comment by Dr. Krishna Kumari Challa on April 15, 2025 at 9:44am

An alternative to artificial fertilizers: Small peptides enhance symbiosis between plants and fungi

Industrial farming practices often deplete the soil of important nutrients and minerals, leaving farmers to rely on artificial fertilizers to support plant growth. In fact, fertilizer use has more than quadrupled since the 1960s, but this comes with serious consequences. Fertilizer production consumes massive amounts of energy, and its use pollutes the water, air, and land.

Plant biologists  are now proposing a new solution to help kick this unsustainable fertilizer habit. 

In a new study, the researchers identified a key molecule produced by plant roots, a small peptide called CLE16, that encourages plants and beneficial soil fungi to interact with each other. They say boosting this symbiotic relationship, in which the fungi provide mineral nutrients to the plants through CLE16 supplementation, could be a more natural and sustainable way to encourage crop growth without the use of harmful artificial fertilizers.

The findings are published in the Proceedings of the National Academy of Sciences.

By restoring the natural symbiosis between plant roots and fungi, we could help crops get the nutrients they need without the use of harmful fertilizers.

In this mutually beneficial relationship, soil-borne arbuscular mycorrhizal fungi supply plants with water and phosphorus, which the plants accept in exchange for carbon molecules. These exchanges occur by specialized symbiotic fungal tendrils, called arbuscules, burying themselves into plant root cells.

Around 80% of plants can trade resources with fungi in this way. However, the traits that support this symbiosis have been weakened over centuries of agricultural plant breeding that prioritized creating crops with the biggest yields.

Scientists say new crop varieties could be bred to strengthen these traits again—an opportunity they intend to explore through the Institute's Harnessing Plants Initiative.

 Müller, Lena Maria, A plant CLE peptide and its fungal mimic promote arbuscular mycorrhizal symbiosis via CRN-mediated ROS suppression, Proceedings of the National Academy of Sciences (2025). DOI: 10.1073/pnas.2422215122

Comment by Dr. Krishna Kumari Challa on April 15, 2025 at 9:06am

Half of the universe's hydrogen gas, long unaccounted for, has been found

Astronomers tallying up all the normal matter—stars, galaxies and gas—in the universe today have come up embarrassingly short of the total matter produced in the Big Bang 13.6 billion years ago. In fact, more than half of normal matter—half of the 15% of the universe's matter that is not dark matter—cannot be accounted for in the glowing stars and gas we see.

New measurements, however, seem to have found this missing matter in the form of very diffuse and invisible ionized hydrogen gas, which forms a halo around galaxies and is more puffed out and extensive than astronomers thought.

The findings not only relieve a conflict between astronomical observations and the best, proven model of the evolution of the universe since the Big Bang, they also suggest that the massive black holes at the centers of galaxies are more active than previously thought, fountaining gas much farther from the galactic center than expected—about five times farther, the team found.

The new  measurements are certainly consistent with finding all of the gas. 

The results of the study, co-authored by 75 scientists from institutions around the world, have been presented at recent scientific meetings, posted as a preprint on arXiv and are undergoing peer review at the journal Physical Review Letters.

While the still mysterious dark matter makes up the bulk—about 84%—of matter in the universe, the remainder is normal matter. Only about 7% of normal matter is in the form of stars, while the rest is in the form of invisible hydrogen gas—most of it ionized—in galaxies and the filaments that connect galaxies in a kind of cosmic network.

The ionized gas and associated electrons strung out in this filament network are referred to as the warm-hot intergalactic medium, which is too cold and too diffuse to be seen with the usual techniques at astronomers' disposal, and therefore has remained elusive until now.

In the new paper, the researchers estimated the distribution of ionized hydrogen around galaxies by stacking images of approximately 7 million galaxies—all within about 8 billion light-years of Earth—and measuring the slight dimming or brightening of the cosmic microwave background caused by a scattering of the radiation by electrons in the ionized gas, the so-called kinematic Sunyaev-Zel'dovich effect.

B. Hadzhiyska et al, Evidence for large baryonic feedback at low and intermediate redshifts from kinematic Sunyaev-Zel'dovich observations with ACT and DESI photometric galaxies, arXiv (2024). DOI: 10.48550/arxiv.2407.07152

Comment by Dr. Krishna Kumari Challa on April 15, 2025 at 8:58am

Scientists uncover why carbon-rich meteorites rarely reach Earth

An international team of researchers may have answered one of space science's long-running questions—and it could change our understanding of how life began. Carbon-rich asteroids are abundant in space yet make up less than 5% of meteorites found on Earth.

Published in Nature Astronomy, researchers analyzed close to 8,500 meteoroids and meteorite impacts, using data from 19 fireball observation networks across 39 countries—making it the most comprehensive study of its kind. The paper is titled "Perihelion history and atmospheric survival as primary drivers of Earth's meteorite record."

The team discovered Earth's atmosphere and the sun act like giant filters, destroying fragile, carbon-rich (carbonaceous) meteoroids before they reach the ground.

Scientists have long suspected that weak, carbonaceous material doesn't survive atmospheric entry. What this research shows is many of these meteoroids don't even make it that far: they break apart from being heated repeatedly as they pass close to the sun. The ones that do survive getting cooked in space are more likely to also make it through Earth's atmosphere.

The study also found meteoroids created by tidal disruptions—when asteroids break apart from close encounters with planets—are especially fragile and almost never survive atmospheric entry.

Carbonaceous meteorites are particularly important because they contain water and organic molecules—key ingredients linked to the origin of life on Earth. Carbon-rich meteorites are some of the most chemically primitive materials we can study—they contain water, organic molecules and even amino acids.

However, scientists have so few of them in their meteorite collections that they risk having an incomplete picture of what's actually out there in space and how the building blocks of life arrived on Earth.

Understanding what gets filtered out and why is key to reconstructing our solar system's history and the conditions that made life possible.

 Patrick M. Shober et al, Perihelion history and atmospheric survival as primary drivers of the Earth's meteorite record, Nature Astronomy (2025). DOI: 10.1038/s41550-025-02526-6

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