Beating Seizures by Jamming the Cellular Circuitry
UCSF researchers discover how gabapentin interacts with calcium channels, opening doors for more effective treatments in epilepsy and Lupus by influencing channel biogenesis.
University of California San Francisco
Give to UCSFUCSF researchers discover how gabapentin interacts with calcium channels, opening doors for more effective treatments in epilepsy and Lupus by influencing channel biogenesis.
In a first, researchers have identified chronic pain pathways in individuals directly from their neural activity, showing promising paths forward for treatment.
Exposure to trichloroethylene (TCE), a chemical found in the air, water, and soil, may increase the risk of Parkinson's disease by 70%, according to a UCSF study. TCE is commonly used today as a degreasing solvent.
UCSF scientists have found that brain cancer glioblastoma can cause cognitive decline by affecting neural connections, but the epilepsy drug gabapentin shows promise in blocking this activity, offering hope for new treatments.
Sleep spindles, bursts of brain activity during NREM2 sleep, may regulate anxiety in PTSD, challenging recent studies. Non-invasive therapies could provide relief, such as prescription drugs or electrical brain stimulation. Sleep hygiene is also recommended to maximize the benefit of spindles after a stressful episode.
Ten graduate school finalists competed in this year’s UCSF Grad Slam, in which students present their research in three minutes or less in terms easily understood by a general audience.
A newly discovered brain circuit recruits brain cells called astrocytes to calm overactive neurons to produce a calming and relaxing effect.
Thermo Fisher Scientific Inc. and UCSF will accelerate advanced cell therapies for difficult to treat conditions like cancer from a new manufacturing facility.
Jon Kleen is named the 2023 Dreifuss-Penry Epilepsy Award recipient by the American Academy of Neurology (AAN). He is honored for his contributions to epilepsy treatment.
In a first, UCSF scientists created a molecular-level, 3D picture of how an odor molecule activates a human odorant receptor.
Faranak Fattahi’s lab is a national leader in growing stem cells to model peripheral nerves, focusing on gastrointestinal diseases.