Image Jun Ding Professor of Neurosurgery and of Neurology and Neurological Sciences Affiliation: Knight Initiative Funded Researchers Wu Tsai Neuro Faculty Affiliates Committee: Seminar Series Ding lab website Stanford Profile dingjun@stanford.edu (650) 736-9360 Related Projects Knight Initiative for Brain Resilience Catalyst Momentum Awards 2025 Preserving Motor Engrams in Parkinson's Disease: Neural Circuit and Transcriptomic Studies and Strategies for Resilient Motor Control (renewed) Wu Tsai Neurosciences Institute Synthetic Neuroscience Grants 2024 A synthetic ultrasound neural interface for non-invasive and spatiotemporally precise chemogenetic and pharmacological neuromodulation Knight Initiative for Brain Resilience Catalyst Awards 2022 Preserving motor engrams in Parkinson's disease: Neural circuit and transcriptomic studies and strategies for resilient motor control Pagination Previous page Current page 1 Page 2 Next page Related News More News Image Research news | Sep 8 2025 Knight Initiative for Brain Resilience Rethinking how we learn to move in the world Knight Initiative researchers are uncovering the fine points of how our brains learn to move. In the long run, their findings could help devise better treatments for Parkinson's disease. Image Research news | Oct 29 2024 Wu Tsai Neurosciences Institute New voltage indicator enables ultra-sensitive synaptic imaging Bioengineers and neuroscientists at the Wu Tsai Neurosciences Institute at Stanford University have developed a highly sensitive tool for detecting brain cells’ subtlest electrical signals. Image Wu Tsai Neuro News | Sep 13 2024 Wu Tsai Neurosciences Institute Synthetic neuroscience grants promote transformative brain tech Research projects funded by the Wu Tsai Neurosciences Institute's Synthetic Neuroscience Grants will advance molecular and tissue engineering tools to more precisely study and interact with brain circuits. Image Research news | Oct 5 2023 Wu Tsai Neurosciences Institute Uncovering a role for plasticity in innate behavior Through an unexpected collaboration, Wu Tsai Neuro interdisciplinary postdoc Renzhi Yang discovered that the brain circuits controlling mouse sexual behavior are far more dynamic than researchers had realized. Pagination Previous page Current page 1 Page 2 Next page
Knight Initiative for Brain Resilience Catalyst Momentum Awards 2025 Preserving Motor Engrams in Parkinson's Disease: Neural Circuit and Transcriptomic Studies and Strategies for Resilient Motor Control (renewed)
Wu Tsai Neurosciences Institute Synthetic Neuroscience Grants 2024 A synthetic ultrasound neural interface for non-invasive and spatiotemporally precise chemogenetic and pharmacological neuromodulation
Knight Initiative for Brain Resilience Catalyst Awards 2022 Preserving motor engrams in Parkinson's disease: Neural circuit and transcriptomic studies and strategies for resilient motor control
Image Research news | Sep 8 2025 Knight Initiative for Brain Resilience Rethinking how we learn to move in the world Knight Initiative researchers are uncovering the fine points of how our brains learn to move. In the long run, their findings could help devise better treatments for Parkinson's disease.
Image Research news | Oct 29 2024 Wu Tsai Neurosciences Institute New voltage indicator enables ultra-sensitive synaptic imaging Bioengineers and neuroscientists at the Wu Tsai Neurosciences Institute at Stanford University have developed a highly sensitive tool for detecting brain cells’ subtlest electrical signals.
Image Wu Tsai Neuro News | Sep 13 2024 Wu Tsai Neurosciences Institute Synthetic neuroscience grants promote transformative brain tech Research projects funded by the Wu Tsai Neurosciences Institute's Synthetic Neuroscience Grants will advance molecular and tissue engineering tools to more precisely study and interact with brain circuits.
Image Research news | Oct 5 2023 Wu Tsai Neurosciences Institute Uncovering a role for plasticity in innate behavior Through an unexpected collaboration, Wu Tsai Neuro interdisciplinary postdoc Renzhi Yang discovered that the brain circuits controlling mouse sexual behavior are far more dynamic than researchers had realized.
