Researchers identify rare NAMPT-linked disorder known as MINA syndrome

Researchers at the University of California, Riverside, have identified how inflammation in multiple sclerosis disrupts mitochondrial function in the brain, leading to the loss of key neurons that control balance and coordination. Published in the Proceedings of the National Academy of Sciences, the findings highlight a potential pathway for new treatments to preserve mobility in the 2.3 million people affected by the disease worldwide. The study examined human brain tissue and a mouse model to trace these energy failures over time.

December 09, 2025 Ti AI ṣe iroyin Ti ṣayẹwo fun ododo

Researchers in Germany have identified a rare mutation in the GPX4 enzyme that disables its protective role in neurons, allowing toxic lipid peroxides to damage cell membranes and trigger ferroptotic cell death. Studies in patient-derived cells and mice show a pattern of neurodegeneration that resembles changes seen in Alzheimer’s disease and other dementias.

Researchers report that reduced ATP signaling in the dorsal hippocampus of male mice, driven by changes in the protein connexin 43, can trigger both depression- and anxiety-like behaviors. The study, published in The Journal of Neuroscience, finds that chronic stress lowers extracellular ATP and connexin 43 levels, that experimentally reducing the protein induces similar behaviors even without stress, and that restoring it in stressed animals improves behavioral signs of distress.

December 16, 2025 Ti AI ṣe iroyin Ti ṣayẹwo fun ododo

Researchers have developed a genomic mapping technique that reveals how thousands of genes work together to influence disease risk, helping to bridge gaps left by traditional genetic studies. The approach, described in a Nature paper led by Gladstone Institutes and Stanford University scientists, combines large-scale cell experiments with population genetics data to highlight promising targets for future therapies and deepen understanding of conditions such as blood disorders and immune-mediated diseases.

Washington University scientists report that inhibiting the circadian regulator REV-ERBα raised brain NAD+ and reduced tau pathology in mouse models, pointing to a clock-focused strategy worth exploring for Alzheimer’s disease.

January 26, 2026 Ti AI ṣe iroyin

Researchers have uncovered how amyloid beta and inflammation may both trigger synapse pruning in Alzheimer's disease through a common receptor, potentially offering new treatment avenues. The findings challenge the notion that neurons are passive in this process, showing they actively erase their own connections. Led by Stanford's Carla Shatz, the study suggests targeting this receptor could preserve memory more effectively than current amyloid-focused drugs.