Removing aging brain cells eases epilepsy in mice

Researchers at the University of California, San Francisco, have discovered a mechanism by which exercise helps protect the brain from age-related damage associated with Alzheimer's disease. Physical activity prompts the liver to release an enzyme that repairs the blood-brain barrier, reducing inflammation and improving memory in older mice. The findings, published in the journal Cell, highlight a body-to-brain pathway that could lead to new therapies.

26. januar 2026 Rapporteret af AI

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.

Alzheimer's trials are shifting to a multi-target approach inspired by cancer research, even after failures with Novo Nordisk's semaglutide. Only two drugs, Eli Lilly's Kisunla and Eisai and Biogen's Leqembi, are widely approved to slow progression. This evolution treats the brain-wasting disease as a complex system, seeking new ways to halt it amid its global impact.

23. november 2025 Rapporteret af AI Faktatjekket

Researchers at Baylor College of Medicine report that raising levels of the protein Sox9 in astrocytes enables these brain support cells to remove existing amyloid plaques and preserve cognitive performance in mouse models of Alzheimer’s disease that already show memory deficits. The findings, published in Nature Neuroscience, highlight astrocytes as a potential target for slowing neurodegenerative decline.

Researchers at UNSW Sydney have identified around 150 functional DNA enhancers in human astrocytes that regulate genes associated with Alzheimer's disease. By testing nearly 1,000 potential switches using advanced genetic tools, the team revealed how non-coding DNA influences brain cell activity. The findings, published on December 18 in Nature Neuroscience, could aid in developing targeted therapies and improving AI predictions of gene control.

1. november 2025 Rapporteret af AI Faktatjekket

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.