Browse wide-ranging research at the frontiers of neuroscience supported by Wu Tsai Neurosciences Institute grants, awards, and training fellowships.
Projects
A minimally-invasive intracranial pressure microsensor (mICP) for long-term, continuous ambulatory monitoring
Topical Hedgehog modulators to enhance motor nerve regeneration after injury and repair
Development and validation of selective novel small molecule therapeutics for Parkinson's Disease
Extended Reality(XR) enhanced behavioral activation for treatment of Major Depressive Disorder
This team has created an extended reality–enhanced implementation of "behavioral activation," one of the most effective forms of evidence-based psychotherapy for major depression. They will use the Neuroscience:Translate award to test the efficacy and scalability of this approach and accelerate the development of extended reality technologies to improve treatment options for major depression.
Autism digital therapy with embedded endpoints and artificial intelligence for progress tracking and adaptive care - Renewal
Development of an extracochlear neurostimulation device to restore hearing – Renewal
Sensorineural hearing loss is an increasingly prevalent condition that causes disability to over a third of US adults aged over 65. This team is developing a breakthrough device to restore high-frequency hearing that preserves residual hearing through a reversible and minimally invasive approach.
Remote reliable measurements of movement using bluetooth enabled engineered keyboard for diagnosis of neurological diseases - Renewal
This team is developing a device that will enable accurate diagnosis of Parkinson’s disease via telemedicine. They initially introduced the technology of Quantitative DigitoGraphy (QDG) using a repetitive alternating finger tapping (RAFT) task on a musical instrument digital interface (MIDI) keyboard and will use Neuroscience: Translate funding for the next stage of device development.
Manipulating inflammation in the aging brain to promote brain resilience
Inflammation is a hallmark of brain aging, yet the source of inflammation in the old brain — and how to eliminate it — is unknown. This team aims to provide insight on how inflammation affects the aging brain that could potentially lead to the generation of new therapies to promote brain resilience.
Mechanistic dissection and therapeutic capture of an exercise-inducible metabolite signaling pathway for brain resilience
Exercise improves cognition and protects against age-associated neurodegenerative diseases, but further research is needed to understand exactly how this occurs. This project aims to pave the way for therapeutics that can capture the benefits of exercise for promoting brain resilience.
Mutant microglia and resilience to Alzheimer’s disease
This project aims to identify how mutant peripheral immune cells that invade the brain might actually reduce Alzheimer’s disease risk. The research will explore how to mimic these cells’ resilience-promoting effects to design new Alzheimer’s therapies.
From gut to brain: reprogramming peripheral macrophages at the intestinal barrier to prevent age-associated inflammation and cognitive decline
This team will investigate whether a decline in intestinal immune cell metabolism drives age-related inflammation and cognitive decline. By replacing aged intestinal macrophages with metabolically healthy ones, they hope to develop a novel approach to enhance cognitive resilience.
Unleashing engineered T cells as disease sensors and therapeutic actuators for neurodegenerative disease
This project will explore whether amyotrophic lateral sclerosis (ALS) and frontotemporal dementia (FTD) result from immune cells attacking altered neurons. The team aims to pioneer the use of engineered immune cells as therapies for neurodegenerative disorders.
Role of Proteostasis and Organelle Homeostasis in Brain Resilience during Aging
This team aims to define how and why protein production breaks down in aging cells, leading to disease. This research may lead to new diagnostic and therapeutic approaches against neurodegenerative diseases and potentially aging itself.