Lifeboat Foundation

A team of researchers from Jilin University, NYU Abu Dhabi’s Smart Materials Lab, and the Center for Smart Engineering Materials, led by Professor of Chemistry Pance Naumov, has developed a new crystalline material that can harvest water from fog without any energy input.

The design of the novel type of smart crystals, which the researchers named Janus crystals, is inspired by desert plants and animals, which can survive in arid conditions. Desert beetles and lizards, for example, have evolved to develop surface structures that have both hydrophilic and hydrophobic areas and effectively capture moisture from the air. Water is attracted to the hydrophilic areas and droplets are accumulated and transported through the hydrophobic areas.

The findings are presented in the paper titled “Efficient Aerial Water Harvesting with Self-Sensing Dynamic Janus Crystals,” recently published in the Journal of the American Chemical Society.

Basically bio electricity once controlled could offer eternal life for humans because we could simply use the electricity to have longer if not indefinite lifespans that don’t require as much food for energy.

In the near future, birth defects, traumatic injuries, limb loss and perhaps even cancer could be cured through bioelectricity—electrical signals that communicate to our cells how to rebuild themselves. This innovative idea has been tested on flatworms and frogs by biologist Michael Levin, whose research investigates how bioelectricity provides the blueprint for how our bodies are built—and how it could be the future of regenerative medicine.

Levin is a professor of biology at Tufts University and director of the Tufts Center for Regenerative and Developmental Biology.

Dr. Elana Miller talks about The Longevity Benefits of Acarbose and Rapamycin.

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Researchers develop a novel edge-highlighting visualization technique for more comprehensible 3D-scanned objects. Improvements in three-dimensional (3D) scanning have enabled quick and accurate scanning of 3D objects, including cultural heritage objects, as 3D point cloud data. However, conventional edge-highlighting visualization techniques, used for understanding complex 3D structures, result in excessive line clutter, reducing clarity. Addressing these issues, a multinational team of researchers have developed a novel technique, involving independent rendering of soft and sharp edges in 3D structures, resulting in improved clarity and depth perception.

Recent advances in three-dimensional (3D) scanning, particularly in photogrammetry and laser scanning, have made it possible to quickly and accurately scan complex 3D objects in the real world. These techniques generate detailed models by collecting large-scale point cloud data, representing the object’s surface geometry through millions of individual points. This technology has applications in different fields, such as the 3D scanning of cultural heritage objects. By preserving these objects in digital formats, researchers can analyze their structures in greater depth. However, the complexity of data is often significant, especially when the scanned object has internal 3D structures, like rough edges.

Edge-highlighting visualization is a technique used to improve the clarity of complex 3D structures by emphasizing the object’s edges, making its shape and structure more distinguishable. However, existing methods struggle when applied to highly complex objects. These methods draw too many lines, which decreases clarity by impairing resolution and depth perception.

It’s been more than three decades, but still there are only two treatments for a stroke: either rapid use of a clot-busting medication called tPA or surgical removal of a clot from the brain with mechanical thrombectomy. However, only 5% to 13% percent of stroke cases are actually eligible for these interventions.

“We need to be persistent with our research to find a new therapy for stroke,” says Rajkumar Verma, M.Pharm., Ph.D., assistant professor, Department of Neuroscience at UConn School of Medicine working in cross-campus collaboration with Professor Raman Bahal Ph.D. of the Department of Pharmaceutical Sciences in the UConn School of Pharmacy. “Stroke research is hard and challenging to do. But without trying we won’t make progress. We need to keep trying. UConn is determined to keep trying.”

In addition to being life-threatening, stroke is the major cause of long-term disability worldwide.

Imagine a thread so thin it’s invisible to the naked eye but packed with the mass of thousands of stars. This isn’t science fiction—it’s the theoretical description of cosmic strings, structures that may hold answers to the Universe’s greatest mysteries. If confirmed, researchers believe these theoretical strings could unlock the key to time travel.

Cosmic strings, if they exist, are thought to be incredibly slender. Some say they’d be long tubes, either stretching infinitely or looping back on themselves. Despite their thinness, a cosmic string’s mass could rival tens of thousands of stars, and it would gradually shrink over time, radiating gravitational waves as it “wiggles.”

Physicists have proposed two types of cosmic strings thus far. The first, “cosmic superstrings,” stems from string theory, a framework suggesting the Universe’s fundamental particles are vibrating strings. Superstrings could be stretched across the cosmos, providing clues about the fabric of reality and possibly holding the key to time travel, too.

Illinois researchers have found an unbelievable link between infection with Covid and cancer regression where tumors decrease in size or extent.

Using animals and tissue from humans, scientists observed that the RNA molecules of the SARS-CoV-2 virus, which is responsible for the disease, triggered the development of a special cell in the immune system that has anti-cancer properties.

Known as “inducible nonclassical monocytes” or “I-NCMs,” these special cells attack cancer cells and could be used to treat cancers that are resistant to current therapies, according to Northwestern Medicine Canning Thoracic Institute scientists.

Injectable magnetoelectric nanodiscs may activate neurons in localized brain regions when stimulated by a weak external magnetic field, say MIT scientists.