One of the problems of conventional filters used in homes, businesses and public spaces is their poor performance. They rely on weak van der Waals forces to capture particles like dust and pollen, meaning they let a lot of stuff slip through. Nature, however, does the job a whole lot better.
Drawing inspiration from the human body, chemical engineers at Chung-Ang University in South Korea designed an air filtration system that mimics the mucus layer coating nasal hairs.
A team of chemists, microbiologists and ecologists has designed a molecular probe (a molecule designed to detect proteins or DNA inside an organism, for example) that lights up when a sugar is consumed.
In the Journal of the American Chemical Society, they now describe how the probe helps researchers study the microscopic tug-of-war between algae and microbial degraders in the ocean.
“Sugars are ubiquitous in marine ecosystems, yet it’s still unclear whether or how microbes can degrade them all,” says Jan-Hendrik Hehemann from the Max Planck Institute for Marine Microbiology and the MARUM—Center for Marine Environmental Sciences, both located in Bremen.
When people take antibiotics, some of the dose is excreted with urine and feces and ends up in our wastewater. The presence of this low dose of antibiotic creates an opportunity for resistant bacteria to evolve.
Scientists studying antibiotic-resistant bacteria in wastewater at a treatment plant discovered multi-drug-resistant strains of bacterial species which are usually not dangerous to healthy people, but which could transmit genes for antibiotic resistance to much more dangerous bacteria like E. coli.
The scientists then challenged the bacteria with natural compounds which could potentially be included in wastewater treatment to kill off bacteria and fight antibiotic resistance. The most effective were curcumin, which comes from turmeric, and emodin, from rhubarb.
Every living cell must interpret its genetic code—a sequence of chemical letters that governs countless cellular functions. A new study by researchers from the Center for Theoretical Biological Physics at Rice University has uncovered the mechanism by which the identity of the letters following a given nucleotide in DNA affects the likelihood of mistakes during transcription, the process by which DNA is copied into RNA. The discovery offers new insight into hidden factors that influence transcription accuracy.
The work is published in the journal Proceedings of the National Academy of Sciences.
The study was authored by Tripti Midha, Anatoly Kolomeisky and Oleg Igoshin. It shows why genetic sequences are not equally prone to errors. Instead, the identity of the two nucleotides immediately downstream of a site significantly alters the error rate during transcription. This discovery builds on prior insights by the same authors on enzymatic proofreading mechanisms, factoring in the effects of distinct kinetics for different nucleotide additions.
Researchers from DZNE, Ludwig-Maximilians-Universität München (LMU), and Technical University of Munich (TUM) have found that the enzyme “gamma-secretase”—implicated in Alzheimer’s disease and cancer—selects its reaction partners according to a complex scheme of molecular features.
Their study, published in Nature Communications, introduces a methodology that decodes the enzyme’s recognition logic by bridging biochemistry with explainable artificial intelligence (AI). This novel approach could help to better understand the role of gamma-secretase in diseases and aid drug development.
Gamma-secretase is an enzyme belonging to the category of “proteases” that plays a key role in Alzheimer’s disease and cancer. It occurs in the membrane of numerous cells, including neurons, where—acting like a pair of scissors—it cleaves other membrane-bound proteins.
A breakthrough in the understanding of how mammals create red blood cells by Dr Julia Gutjahr, who began her research into the mechanisms of blood production in the lab of Professor Antal Rot in the Faculty of Medicine and Dentistry, could lead to opportunities for articifical blood to be created at scale for the first time.
Dr Gutjahr is now a biologist at the Institute of Cellular Biology and Immunology Thurgau at the University of Konstanz in Germany. She identified the molecular signal, chemokine CXCL12, that triggers the expulsion of the nucleus by the red blood cell precursors, a key step in the development of red blood cells.
Studies undertaken by researchers at Queen Mary and University of Konstanz have identified a critical chemical signal in the development of red blood cells. The discovery will help make the manufacture of artificial blood more efficient.
In what experts are calling a “dream come true,” scientists used a recent biochemical discovery to help an 8-year-old boy with a rare genetic condition regain mobility.
Researchers from NYU Langone demonstrated, in a study published in Nature on Wednesday, how a chemical precursor to a commonly available enzyme, CoQ10, can help brain cells overcome a rare genetic condition that severely hobbles cells’ energy production process. Without treatment, the boy’s condition is known to deteriorate rapidly and could be fatal.
NYU Langone researchers have helped an 8-year-old boy regain mobility using an experimental treatment.
When the Empire State Building was constructed, its 102 stories rose above midtown one piece at a time, with each individual element combining to become, for 40 years, the world’s tallest building. Uptown at Columbia, Oleg Gang and his chemical engineering lab aren’t building Art Deco architecture; their landmarks are incredibly small devices built from nanoscopic building blocks that arrange themselves.
“We can now build the complexly prescribed 3D organizations from self-assembled nanocomponents, a kind of nanoscale version of the Empire State Building,” said Gang, professor of chemical engineering and of applied physics and materials science at Columbia Engineering and leader of the Center for Functional Nanomaterials’ Soft and Bio Nanomaterials Group at Brookhaven National Laboratory.
“The capabilities to manufacture 3D nanoscale materials by design are critical for many emerging applications, ranging from light manipulation to neuromorphic computing, and from catalytic materials to biomolecular scaffolds and reactors,” said Gang.
Serendipitous discovery of djerfisherite in Ryugu grain challenges current paradigm of the nature of primitive asteroids. A surprising discovery from a tiny grain of asteroid Ryugu has rocked scientists’ understanding of how our Solar System evolved. Researchers found djerfisherite—a mineral typically born in scorching, chemically reduced conditions and never before seen in Ryugu-like meteorites—inside a sample returned by Japan’s Hayabusa2 mission. Its presence suggests either Ryugu once experienced unexpectedly high temperatures or that exotic materials from other parts of the solar system somehow made their way into its formation. Like discovering a palm tree fossil in Arctic ice, this rare find challenges everything we thought we knew about primitive asteroids and the early mixing of planetary ingredients.
The pristine samples from asteroid Ryugu returned by the Hayabusa2 mission on December 6, 2020, have been vital to improving our understanding of primitive asteroids and the formation of the Solar System. The C-type asteroid Ryugu is composed of rocks similar to meteorites called CI chondrites, which contain relatively high amounts of carbon, and have undergone extensive aqueous alteration in their past.
A research team at Hiroshima University discovered the presence of the mineral djerfisherite, a potassium-containing iron-nickel sulfide, in a Ryugu grain. The presence of this mineral is wholly unexpected, as djerfisherite does not form under the conditions Ryugu is believed to have been exposed to over its existence. The findings were published on May 28, 2025, in the journal Meteoritics & Planetary Science.