Removing aging brain cells eases epilepsy in mice

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.

2025년 12월 24일 AI에 의해 보고됨

Researchers have demonstrated that restoring levels of a key brain energy molecule can reverse advanced Alzheimer's disease in mouse models, repairing damage and restoring cognitive function. The study, published on December 22, challenges the long-held view that the condition is irreversible. Findings from human brain tissue support the approach's potential relevance to patients.

A recently recognized form of dementia, known as LATE, is reshaping understanding of cognitive decline in the elderly, with rising diagnoses and guidelines for doctors published this year. It is estimated to affect about one-third of people aged 85 or older and 10% of those aged 65 or older, often mistaken for Alzheimer's. Experts emphasize the need for a broader range of treatments for this condition.

2025년 12월 19일 AI에 의해 보고됨

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.

A new study finds that people over 80 who maintain sharp mental abilities, known as super agers, carry fewer copies of the main Alzheimer's risk gene and more of a protective variant. This genetic profile sets them apart even from other healthy seniors in the same age group. The research, led by Vanderbilt University Medical Center, highlights potential resilience factors against dementia.

2025년 12월 09일 AI에 의해 보고됨 사실 확인됨

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.