Lifeboat Foundation: Safeguarding Humanity
Toggle light / dark theme

Blog

Category: health

Genetic defect that weakens esophageal lining identified!

But the molecular factors responsible for the onset of Barrett’s esophagus remain poorly understood.

The findings, published in Nature Communications, combined family studies, laboratory experiments and genetically engineered mouse models to identify and understand how genetic defects contribute to disease development.

The team sequenced and analyzed genetic material of 684 people from 302 families where multiple members developed Barrett’s esophagus or esophageal cancer. They discovered that a subset of affected family members carry inherited mutations in a gene called VSIG10L.

“We found that this gene acts like a quality control system for the esophageal lining,” said the lead researcher. “When it’s defective, the cells do not mature properly and the protective barrier in the esophageal lining becomes weak, allowing stomach bile acid to cause tissue changes that enhances the risk of developing Barrett’s esophagus.”

When researchers genetically engineered mice with human-equivalent VSIG10L mutations, they found that the esophageal lining became disrupted structurally and molecularly, according to the author. The study found that when the mice were exposed to bile acid, they developed Barrett’s-like disease over time, effectively replicating the disease’s progression in humans.

These genetically engineered mice also represent the first animal model for Barrett’s esophagus based directly on human genetic predisposition to the disease, the author said.

With VSIG10L shown to be a key gene in maintaining esophageal health, family members can now be screened for genetic variants to identify those at a high-risk of developing Barrett’s esophagus or esophageal cancer. ScienceMission sciencenewshighlights.

Continue reading “Genetic defect that weakens esophageal lining identified!” | >

System isolates single extracellular vesicle surface proteins to map function

Extracellular vesicles (EVs) are tiny biological bubbles that carry nucleic acids and proteins between cells, playing an essential role in tissue repair, neuroprotection and immune health. By isolating the surface proteins of these bubbles, researchers can understand more about their biology and build tools to transform extracellular vesicles into next-generation drugs for cancer, neurological conditions and other diseases.

UC Davis biomedical engineers are using EVs to crack the code of the body’s message system. Their findings are detailed in a paper published in ACS Nano.

“EV-mediated intercellular communication is a very powerful system that controls many physiological and pathophysiological phenomena,” said Aijun Wang, a corresponding author of the new study. Wang is Chancellor’s Fellow and professor of biomedical engineering and surgery. “We know that EVs are therapeutically useful. But how do we define what dictates their functions?”

First evidence of a ‘critical priority’ fungal pathogen becoming more deadly when co-infected with tuberculosis

Cryptococcus neoformans is one of four fungi classified as “critical priority” on the WHO’s Fungal Pathogens Priority List, which was published in October 2022 following decades of research and calls for fungal pathogens to be classified alongside their bacterial and viral counterparts.

The fungus infects people through inhalation of spores or yeast cells in the environment, first colonizing the lungs and can then spread to the brain. In 2020, an estimated 112,000 deaths were associated globally to fungal meningitis caused by C. neoformans.

Increasing evidence shows that co-infection of Mycobacterium tuberculosis, the causative agent of tuberculosis, together with C. neoformans, is a grave public health concern, increasing the risk of death significantly compared to fungal infection alone.

SGLT2 Inhibitors and Cardiorenal Outcomes in T2D With Liver Cirrhosis

Among adults with Type2Diabetes and liver cirrhosis, SGLT2 inhibitor use was associated with lower risks of end-stage kidney disease, cardiovascular events, mortality, and hepatic decompensation compared with DPP4 inhibitors.

Importance Type 2 diabetes (T2D) and liver cirrhosis frequently coexist, creating a high-risk population for adverse outcomes. Patients with both conditions face elevated risks of kidney and cardiovascular complications, yet evidence regarding optimal antidiabetic therapy in this vulnerable population remains limited.

Objective To evaluate the association of sodium-glucose cotransporter–2 inhibitor (SGLT2i) vs dipeptidyl peptidase–4 inhibitor (DPP4i) use with kidney outcomes, cardiovascular events, and hepatic decompensation in patients with concurrent T2D and liver cirrhosis.

Design, Setting, and Participants This nationwide retrospective cohort study utilized data from the Taiwan’s National Health Insurance Database between May 2016 and December 2023. Adults with both T2D and liver cirrhosis who initiated either SGLT2is or DPP4is were included.

The shingles vaccine may reduce your dementia risk—here’s why

Shingles, a viral rash, can be incredibly painful. Vaccination can help prevent the infection, but new research is showing the shingles vaccine may also have another benefit: protection against the development of dementia. With more than 40 percent of Americans estimated to develop dementia at some point in their lives, this discovery could have groundbreaking implications for our health. But what explains the link between the shingles vaccine and reduced dementia risk?

Recent research is part of a growing body of evidence that vaccination against shingles—and potentially other infections—can help prevent and delay the progression of dementia.

Nanotubes unlock new wavelengths for smarter sensing

Sensors made of carbon nanotubes that can measure infrared and terahertz radiation are being tested for uses ranging from detecting damaged cables after earthquakes, to collecting health data via ultrathin wearable devices, and assisting with pharmaceutical quality control, say researchers in Japan.

“Accurately visualizing the internal structures of organisms and objects is integral to our daily lives, from medical imaging to security scanning in airports,” and terahertz sensors built from carbon nanotubes are uniquely suited to this purpose, says Yukio Kawano is a professor of engineering at Chuo University in Tokyo, and project leader at the Kanagawa Institute of Industrial Science and Technology (KISTEC) in Japan.

Compared with many sensor technologies that can only detect one part of the electromagnetic spectrum, Kawano’s team is working to create sensors that can detect terahertz and a broader range of radiation, and use them to produce high-resolution images.

Stunning new maps of myelin-making mouse brain cells advance understanding of nervous system disorders

Johns Hopkins scientists say they have used 3D imaging, special microscopes and artificial intelligence (AI) programs to construct new maps of mouse brains showing a precise location of more than 10 million cells called oligodendrocytes. These cells form myelin, a protective sleeve around nerve cell axons, which speeds transmission of electrical signals and support brain health.

Published online Feb. 18 in Cell and funded by the National Institutes of Health, the maps not only paint a whole-brain picture of how myelin content varies between brain circuits, but also provide insights into how the loss of such cells impacts human diseases such as multiple sclerosis, Alzheimer’s disease and other disorders that affect learning, memory, sensory ability and movement, say the researchers. Although mouse and human brains are not the same, they share many characteristics and most biological processes.

“Our study identifies not only the location of oligodendrocytes in the brain, but also integrates information about gene expression and the structural features of neurons,” says Dwight Bergles, Ph.D., the Diana Sylvestre and Charles Homcy Professor in the Department of Neuroscience at the Johns Hopkins University School of Medicine. “It’s like mapping the location of all the trees in a forest, but also adding information about soil quality, weather and geology to understand the forest ecosystem.”

Astrocytes, not just neurons, found to drive fear memory signals in the amygdala

Picture a star-shaped cell in the brain, stretching its spindly arms out to cradle the neurons around it. That’s an astrocyte, and for a long time, scientists thought its job was caretaking the brain, gluing together neurons, and maintaining neural circuits. But now, a new study reveals that these supposed support cells that are spread all over the brain are as important as neurons in fear memory.

“Astrocytes are interwoven among neurons in the brain, and it seemed unlikely they were there just for housekeeping. We wanted to understand what they’re actually doing—and how they’re shaping neural activity in the process,” said Lindsay Halladay, assistant professor at the University of Arizona Department of Neuroscience and one of the study’s senior authors.

Halladay’s lab collaborated with researchers from the National Institutes of Health for this multi-institutional study, led by Andrew Holmes and Olena Bukalo of the Laboratory of Behavioral and Genomic Neuroscience.

What a zinc gradient in dentin could mean for fillings and tooth health

Teeth are composites of mineral and protein, with a bulk of bony dentin that is highly porous. This structure allows teeth to be both strong and sensitive. Besides calcium and phosphate, teeth contain trace elements such as zinc. Using complementary microscopy imaging techniques, a team from Charité Berlin, TU Berlin and HZB has quantified the distribution of natural zinc along and across teeth in 3 dimensions. The team found that, as porosity in dentin increases towards the pulp, zinc concentration increases 5~10 fold. These results help to understand the influence of widely-used zinc-containing biomaterials (e.g. filling) and could inspire improvements in dental medicine.

The paper is published in the journal VIEW.

Teeth have a complex structure: the dental pulp with the nerves is surrounded by dentin, a porous bony material, covered externally by enamel in the mouth and cementum in the roots. Although dentin is criss-crossed by countless micrometer-sized dentin tubules, teeth can withstand decades of cyclic, repeated forces. The density of the dentinal tubules increases towards the pulp, meaning that the dentin becomes increasingly porous towards the inside.

Will probiotics work for you? Models map gut metabolism to predict success

A new study demonstrates that computer models of gut metabolism can predict which probiotics will successfully establish themselves in a person’s gut and how different prebiotics affect production of health-promoting short-chain fatty acids. The findings are published in PLOS Biology by Sean Gibbons of the Institute for Systems Biology, US, and colleagues.

Probiotic and prebiotic supplements show highly variable results across individuals, making it difficult to predict who will benefit from these interventions. This variability comes from complex interactions between introduced probiotics, each person’s existing gut microbiota, and their diet.

In the new work, researchers first tested a metabolic model on data from two previous studies in which participants diagnosed with type 2 diabetes were given a placebo or probiotic/prebiotic mixture designed to improve glucose control and healthy participants were given a placebo or a probiotic treatment designed to treat recurrent Clostridioides difficile infections, respectively.

/* */