This research develops a novel MRI-based method to detect blood–brain barrier leakage associated with stroke. By comparing pre- and post-contrast brain images, the approach enables early detection, monitoring of treatment response, and risk prediction, offering new possibilities for stroke prevention and improved patient outcomes

This research uncovers a newly identified neural cluster that controls how much sodium animals want based on internal bodily state. By activating or inhibiting these neurons, salt perception can be shifted without changing food content. Their accessibility and immune-linked receptors offer promising targets for treating sodium overconsumption and related health disorders.

This project develops an “Aptamer Express,” a DNA-based Trojan horse designed to bypass the brain’s protective barriers, target tumours, and deliver cancer-killing drugs directly to brain cancer cells. The approach aims to overcome treatment resistance, improve precision, and reduce side effects, offering new hope for patients and their families.

This research maps how drugs travel from the cerebrospinal fluid into the brain, offering an alternative to the blood–brain barrier for treating Alzheimer’s disease. Using mouse models, the study identifies specific drug-entry routes and differences in drug penetration, paving the way for targeted, efficient therapies guided by a “Google Brain Map” of delivery pathways.