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An international research team led by NYU Tandon School of Engineering and KAIST (Korea Advanced Institute of Science and Technology) has pioneered a new technique to identify and characterize atomic-scale defects in hexagonal boron nitride (hBN), a two-dimensional (2D) material often dubbed "white graphene" for its remarkable properties.
Researchers at WashU Medicine have reduced scar formation and improved heart function in mouse models of heart failure using a monoclonal antibody treatment, similar to one approved by the FDA for other conditions. The findings point to the possibility of developing such immunotherapies for heart failure in patients who have experienced a heart attack or other injury.
Scientists at the Icahn School of Medicine at Mount Sinai, in collaboration with colleagues in the field, have developed an innovative antibody platform aimed at tackling one of the greatest challenges in treating rapidly evolving viruses like SARS-CoV-2: their ability to mutate and evade existing vaccines and therapies. Their findings, including preclinical studies in mice, introduce the Adaptive Multi-Epitope Targeting and Avidity-Enhanced (AMETA) Nanobody Platform, a new antibody approach for addressing how viruses like SARS-CoV-2, which causes COVID-19, evolve to evade vaccines and treatments. Details on the results were published October 23 in the journal Cell.
At The University of Texas Rio Grande Valley, researchers are turning everyday glass waste into a possible innovative solution for coastal erosion and to be used in sustainable agriculture.
Scientists have identified a natural compound, (Z)-3-hexenyl butyrate (HB), that can induce stomatal closure in plants, a defense mechanism to conserve water and protect against pathogens. This discovery could lead to more sustainable agricultural practices by enhancing crop resilience to environmental stresses without the need for synthetic pesticides.
A new study has uncovered the genetic controls behind seed size and yield in yellow horn, a tree species valued for its high-quality oil. Researchers have identified a key gene, XsAP2, which could significantly boost the plant's productivity.
Scientists have leveraged CRISPR/Cas9 gene editing to enhance the nutritional properties of Chinese cabbage. By targeting the BrFLS1 gene, they engineered a variety with reduced flavonol content and increased levels of dihydroflavonols, compounds associated with enhanced health benefits and stress tolerance. This advancement paves the way for developing cabbage varieties with improved nutritional value, offering potential benefits in both health and agriculture.
A new study presents a significant leap in our understanding of Rosaceae fruits, unveiling a comparative genomic resource that could transform fruit breeding. The research provides insights into the gene expression patterns across different developmental stages of apples, peaches, strawberries, and raspberries, offering a robust platform for future crop improvement and variety development.
Cedars-Sinai and UCLA investigators studied first trimester placental tissue and found that for some genes, the process that turns their information into a biological function may depend on the sex of the fetus.
In a world first, a pig kidney preserved at subzero temperatures was successfully transported across the Atlantic Ocean multiple times, demonstrating the potential for a novel technology to greatly extend organ storage and preservation, and make long-distance organ transportation a clinical reality.
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