Featured News Image Research news | Jun 24, 2026 Knight Initiative for Brain Resilience Why do some cells die in ALS but not others? New Knight Initiative research identifies a molecular signature in vulnerable cells that could lead to treatments to promote ALS resilience Image Research news | Jun 17, 2026 Wu Tsai Neurosciences Institute It’s time to revamp the motor homunculus An update to the 89-year-old model shows that the brain’s motor cortex isn’t as neatly organized as previously thought Image Research news | Jun 15, 2026 Stanford Medicine Cell types' biological age predicts our disease risk A blood-test analysis can determine the biological ages of individual cell types and predict the health consequences Image Knight Initiative news | May 26, 2026 Knight Initiative for Brain Resilience Slowing aging, predicting lifespan, and excitement for the future at the Knight ... The symposium showcased research ranging from rejuvenating the brain’s immune system to predicting cognitive health, and celebrated the next chapter of the Knight Initiative Displaying 1 - 3 news posts of 3 Filter Sort by Newest to oldest Oldest to newest News Type Wu Tsai Neuro News Knight Initiative news Director's messages Research news Researcher profiles News Features Awards and honors Podcast episodes Press coverage Publications Research Theme NeuroDiscovery NeuroEngineering NeuroHealth Image Research news | Apr 9, 2025 Stanford Medicine Re-creating neural pathway in dish may speed pain treatment Researchers with the Wu Tsai Neuro–funded Stanford Brain Organogenesis project have rebuilt, in laboratory glassware, the neural pathway that sends information from the body’s periphery to the brain. Image Research news | Apr 24, 2024 Stanford Medicine Brain organoids and assembloids are new models for elucidating, treating neurode... New research led by Wu Tsai Neuro affiliate Sergiu Pasca on Timothy syndrome may have implications beyond the rare genetic disorder — including conditions like schizophrenia. Supported by the Wu Tsai Neuro Big Ideas in Neuroscience grant program. Image Research news | Jul 27, 2022 Stanford Medicine Here come the assembloids Institute affiliate Sergiu Pasca's brain models reveals the organ’s workings in unparalleled detail.
Image Research news | Jun 24, 2026 Knight Initiative for Brain Resilience Why do some cells die in ALS but not others? New Knight Initiative research identifies a molecular signature in vulnerable cells that could lead to treatments to promote ALS resilience
Image Research news | Jun 17, 2026 Wu Tsai Neurosciences Institute It’s time to revamp the motor homunculus An update to the 89-year-old model shows that the brain’s motor cortex isn’t as neatly organized as previously thought
Image Research news | Jun 15, 2026 Stanford Medicine Cell types' biological age predicts our disease risk A blood-test analysis can determine the biological ages of individual cell types and predict the health consequences
Image Knight Initiative news | May 26, 2026 Knight Initiative for Brain Resilience Slowing aging, predicting lifespan, and excitement for the future at the Knight ... The symposium showcased research ranging from rejuvenating the brain’s immune system to predicting cognitive health, and celebrated the next chapter of the Knight Initiative
Image Research news | Apr 9, 2025 Stanford Medicine Re-creating neural pathway in dish may speed pain treatment Researchers with the Wu Tsai Neuro–funded Stanford Brain Organogenesis project have rebuilt, in laboratory glassware, the neural pathway that sends information from the body’s periphery to the brain.
Image Research news | Apr 24, 2024 Stanford Medicine Brain organoids and assembloids are new models for elucidating, treating neurode... New research led by Wu Tsai Neuro affiliate Sergiu Pasca on Timothy syndrome may have implications beyond the rare genetic disorder — including conditions like schizophrenia. Supported by the Wu Tsai Neuro Big Ideas in Neuroscience grant program.
Image Research news | Jul 27, 2022 Stanford Medicine Here come the assembloids Institute affiliate Sergiu Pasca's brain models reveals the organ’s workings in unparalleled detail.
