Browse wide-ranging research at the frontiers of neuroscience supported by Wu Tsai Neurosciences Institute grants, awards, and training fellowships.
Projects
High-Fidelity Artificial Retina for Vision Restoration
This team will use their Neuroscience:Translate award to develop a large-scale bi-directional neural interface that will restore high-fidelity vision to people blinded by retinal degeneration.
Programmable RNA editing in Parkinson’s disease therapy
This team will use their Neuroscience:Translate award to employ a novel therapeutic technique to correct pathogenic mutations causing Parkinson’s disease.
New Thrombectomy Device for Endovascular Neurosurgery
This team will use their Neuroscience:Translate award to develop an entirely new class of ischemic stroke treatment device that will lead to improved clot extraction to improve the success of endovascular thrombectomy.
Development of an Ultrasound Neuromodulation Therapy to Treat Rheumatoid Arthritis
This team will use their Neuroscience:Translate award to develop the first wearable ultrasound (US) device for the treatment of inflammatory diseases, such as Rheumatoid Arthritis (RA) and Inflammatory Bowel Disease.
Small molecule ion channel modulator to treat acute episodes of peripheral vertigo
This team is developing a small molecule that targets a voltage-gated ion channel within the inner ear for the symptomatic relief of peripheral vertigo attacks. They will use their Neuroscience:Translate award to further develop this molecule to restore normal function and improve activities of daily living for patients experiencing peripheral vertigo.
Creating a pharmacologic stroke recovery therapy
This team has identified a promising protein-based therapeutic to improve stroke recovery. The team will use the Neuroscience:Translate award to identify key components of this protein to maximize its therapeutic potential for stroke treatments.
Clinical translation of a new PET radiotracer for mapping innate immune activation in multiple sclerosis and other neurodegenerative diseases
This team recently identified a selective biomarker of inflammation-promoting immune cells in the central nervous system. They will use their Neuroscience:Translate award to develop non-invasive molecular imaging strategies to distinguish between harmful (pro-inflammatory) and helpful (anti-inflammatory) immune cells in patients with Multiple sclerosis (MS).
Assessing the feasibility of an autologous cell/gel therapy for spinal cord injury
This team has developed a new therapy for patients with spinal cord injury, involving injection into the spinal cord of patient-derived stem cells within an engineered protective gel. They will use their Neuroscience:Translate award to further test and develop this novel therapy in preparation for first-in-human clinical trials.
Targeting mitochondria in glioblastoma
This team recently discovered that a small molecule they had originally developed to treat Parkinson’s disease can also reduce the volume of glioblastoma tumors – the most common form of aggressive brain tumor — by targeting the mitochondrial protein Miro1. They will use their Neuroscience:Translate award to study the mechanisms of the compound’s anti-tumor action and prepare to apply for investigational-new-drug status to move this discovery toward the clinic.
NeuroChoice Initiative (Phase 2)
Stanford NeuroTechnology Initiative (Phase 2)
Our goal is to develop the next generation of neural interfaces that match the resolution and performance of the biological circuitry. We will focus on two signature efforts to spearhead the necessary advances: high-density wire bundles for electrical recording and stimulation, and analog and digital bi-directional retinal prostheses for restoration of vision.
Stanford Brain Rejuvenation Project (Phase 2)
The Stanford Brain Rejuvenation Project is an initiative by leading aging researchers, neuroscientists, chemists, and engineers to understand the basis of brain aging and rejuvenation and how they relate to neurodegeneration.
Neuro-circuit interventional research consortium for understanding the brain and improving treatment
Combining a detailed understanding of brain circuits with technology that modulates neural activity to develop improved ways of treating mental health conditions.
NeuroVision Initiative
The goal is to forge an inter-disciplinary collaboration between physicists, biologists, chemists, and translational medical scientists by inventing new ways of visualizing the brain, from individual molecules to neuronal circuits to entire brain regions, from a normally functioning neuron to a diseased brain.
The NeuroFab: The hub for new ideas in neuro-engineering
Creating an incubator for next-generation neural interface platforms.
Brain-machine interfaces: Science, engineering, and application
Developing technology to interface with the brain and create intelligent prosthetics.
Stroke Collaborative Action Network
Breaches barriers in our understanding of stroke to develop therapies and improve stroke recovery.
NeuroChoice: Optimizing Choice - from neuroscience to public policy
NeuroPlant Initiative
The NeuroPlant Initiative aims to leverage a botanical armamentarium to manipulate the brain — by building a pipeline to explore chemicals synthesized in plants as potential new treatments for neurological disease and as a window into the chemistry of the brain.
Neurodevelopment Initiative
Investigating how the brain develops from infancy to adulthood across species, focusing on how the interplay between structural development, functional development, experience and affect brain computations and ultimately behavior.
Stanford Brain Organogenesis Program (Phase 1)
Developing brain organoids – three dimensional brain tissues grown in the lab – to study human brain development, evolution and neuropsychiatric disorders.
Neuro-omics Initiative (Phase 1)
Creating new tools to help neuroscientists bridge the study of genes and proteins operating in the brain to the study of brain circuits and systems, which could lead to a deeper understanding of brain function and disease.
The rehab glove: Passive tactile stimulation for stroke rehabilitation
Project's stimulation method may provide a powerful tool to reduce disability after a stroke, and the wearable form factor allows users to receive intensive therapy during their normal daily routine
Multi-modal deep learning for automated seizure localization
Developing an automated seizure detection and localization system based on deep neural networks, EEG data, and real-time video with the goal to dramatically increase neurologist diagnostic capabilities while improving quality of care.