Source: Allen Institute.
The BRAIN Initiative® Cell Atlas Network (BICAN) has launched its first major data release, marking a significant milestone in the ambitious effort to map the whole human brain.
The data, accessible through the BICAN Rapid Release Inventory, includes single-cell and single-nucleus transcriptomic and epigenomic profiles from humans, mice, and 10 other mammalian species.
Posted in biotech/medical, life extension
The LEV Foundation is a nonprofit organization dedicated to advancing the field of rejuvenation biotechnology with the goal of reversing biological aging. Under the leadership of renowned gerontologist Aubrey de Grey, the foundation focuses on conducting early-stage research on animals, specifically testing combination therapies that aim to dramatically extend lifespan. LEV Foundation stands out in the aging research community by targeting middle-aged mice, developing treatments that could one day be applied to humans, helping achieve longevity escape velocity — the point at which aging can be controlled through medical interventions.
Pathogen encounter can result in epigenetic remodeling that shapes disease caused by heterologous pathogens.
The therapeutic potential of antigen-independent innate immune memory (IIM) is of particular relevance in the context of respiratory viruses with pandemic potential. Lercher et al. find that antiviral IIM in alveolar macrophages following SARS-CoV-2 infection ameliorates disease caused by a secondary unrelated pathogen, influenza A virus.
This paper demonstrates how AI accelerates discoveries in archaeology, even in a region as well known as the United Nations Educational, Scientific and Cultural Organization (UNESCO) World Heritage site of Nazca.
It took nearly a century to discover a total of 430 figurative Nazca geoglyphs, which offer significant insights into the ancient cultures at the Nazca Pampa. Here, we report the deployment of an AI system to the entire Nazca region, a UNESCO World Heritage site, leading to the discovery of 303 new figurative geoglyphs within only 6 mo of field survey, nearly doubling the number of known figurative geoglyphs. Even with limited training examples, the developed AI approach is demonstrated to be effective in detecting the smaller relief-type geoglyphs, which unlike the giant line-type geoglyphs are very difficult to discern. The improved account of figurative geoglyphs enables us to analyze their motifs and distribution across the Nazca Pampa.
When it comes to searching for life beyond Earth, specifically on exoplanets or exomoons, are researchers searching for the correct biomarkers? This is what a recent study published in The Astrophysical Journal Letters hopes to address as an international team of researchers investigated how certain organic compounds that were long hypothesized to be created by life can be created in a laboratory setting without life present. This study holds the potential to challenge longstanding hypotheses regarding what biomarkers scientists should search for when trying to identify life on other worlds and how we should adapt our search methods accordingly.
For the study, the researchers successfully created dimethyl sulfide, which is an organic sulfur compound typically produced by marine algae, using a combination of light and gases that have been identified in the atmospheres of exoplanets. The caveat is no organisms were present to create the dimethyl sulfide, which left the researchers puzzled due to the longstanding hypothesis that marine organisms were the only way dimethyl sulfide was created.
“The sulfur molecules that we’re making are thought to be indicators of life because they’re produced by life on Earth,” said Dr. Eleanor Browne, who is an associate professor in the Department of Chemistry at the University of Colorado Boulder, and a co-author on the study. “But we made them in the lab without life — so it might not be a sign of life but could be a sign of something hospitable for life.”
Researchers have uncovered how hormones profoundly affect our immune systems, explaining why men and women are affected by diseases differently.
Scientists from the Karolinska Institutet in Sweden and Imperial College London have shown for the first time which aspects of our immune systems are regulated by sex hormones, and the impacts this has on disease risk and health outcomes in males and females.
It is well established that diseases can affect men and women differently, due to subtle differences in our immune systems. For example, the immune condition systemic lupus erythematosus (SLE) is nine-times more likely to affect women, or with COVID-19, males are known to have a greater risk of acute first-time infections, while females have a greater risk of long-COVID.
Encoding an image into the quantum correlations of photon pairs makes it invisible to conventional imaging techniques.
Immune checkpoint inhibitors (ICIs) immunotherapy facilitates new approaches to achieve precision cancer treatment.
Zhang, D., Wang, M., Liu, G. et al. Novel FABP4+C1q+ macrophages enhance antitumor immunity and associated with response to neoadjuvant pembrolizumab and chemotherapy in NSCLC via AMPK/JAK/STAT axis. Cell Death Dis 15, 717 (2024). https://doi.org/10.1038/s41419-024-07074-x.
Although quantum computing is a nascent field, there are plenty of key moments that defined it over the last few decades as scientists strive to create machines that can solve impossible problems.
On September 29, 1901 Enrico Fermi ForMemRS was born.
On May 11, 1974, National Accelerator Laboratory was given a new name: Fermi National Accelerator Laboratory. The eponym honors famed Italian physicist Enrico Fermi, whose accomplishments in both theoretical and experimental physics place him among the greatest scientists of the 20th century.
Many visitors to Fermilab reasonably conclude from its name that Enrico Fermi worked at the laboratory, but he never did. In fact, he died in 1954, years before scientists even officially recommended the construction of a U.S. accelerator laboratory in 1963.
In 1938, Fermi won the Nobel Prize for work that eventually led to the first controlled release of nuclear energy. He and his family then left Italy and came to the United States, where he accepted a position at Columbia University. He later moved to the University of Chicago, where he built the first atomic pile in the squash court under the university’s Stagg Field. While there, he continued investigating the nature of particles that make up the nucleus. He was also active in the design of the school’s synchrocyclotron. At the time of its completion, it was one of the most powerful atom smashers in the world.