Browse wide-ranging research at the frontiers of neuroscience supported by Wu Tsai Neurosciences Institute grants, awards, and training fellowships.
Projects
Structural and mechanistic analysis of the protein-protein interface between ABCA1 and ApoE as a potential therapeutic target for Alzheimer’s Disease
We propose a new line of research whose goal is to examine the druggability of a protein-protein interface involving ApoE, an apolipoprotein whose gene variants represent the strongest genetic risk factor for AD.
Dissecting mechanisms of gut-brain communication in Parkinson’s Disease
People with Parkinson’s Disease (PD) have different types of bacteria in their guts compared to people without neurological diseases. We will study which gut bacteria for people with PD to gain a better understanding of how gut bacteria contribute to inflammation in the body and in the brain or people with this condition.
Novel ketone-derived anticonvulsant agents for the treatment of childhood refractory epilepsy
We propose to apply mass spectrometry techniques to measure BHB-Phe and other KD metabolites in children undergoing KD for refractory epilepsy at Stanford. Further, in a mouse model of refractory genetic epilepsy, we will compare targeted BHB-Phe treatment to full KD treatment using transcriptomics, EEG assessment of seizures and cognitive testing.
Life-long, minimally invasive, and multiplex transcriptional profiling of the cerebellum
Why do all our brains mature and age in different ways, leading to different cognitive and behavioral outcomes? We envision a novel method that “copies” the information from the RNAs made by the neurons to sensor RNAs we artificially introduce into live animals.
Use of gut-brain electrophysiology to study interoception in eating disorders
In this study, we aim to (i) perform a feasibility study to determine the acceptance and feasibility of performing such recordings in the AN and ARFID eating disorders population and (ii) test the hypothesis that the electrophysiologic monitoring of the brain and stomach is associated with a clinically validated behavioral measure of interoception involving water distention of the stomach.
Multifunctional vascular-like electronics for integration and monitoring of human neural organoids
This study will introduce a vascular-like electronic system that merges seamlessly with neural organoids,
establishing an integrated vascular-electronic-neural network. This envisaged platform holds the promise of heralding a transformative phase in the evolution of human neural organoid research and elucidating the
fundamental understanding on the roles of oxygen and nutrient perfusion during neural development.
Neuronal innervation dynamics in uterine function and maternal age-associated miscarriage
This proposal addresses three interconnected, yet independent aims focused on the neural mechanisms implicated in age-associated miscarriages. First, the proposal aims to construct a comprehensive neuro-uterine atlas delineating neuronal subtypes innervating the uterus, elucidating how innervation patterns and transcriptome profiles evolve with age. Second, the proposal aims to implement cutting-edge tissue clearing techniques on extracted uteri to discern alterations in uterine innervation patterns and signaling across the rodent estrous cycle and the first trimester of pregnancy.
How do early life experiences shape the neural underpinnings of caregiver olfactory recognition?
The ability of an infant to distinguish caregivers from strangers is fundamental for survival early in life. Across
many taxa, newborns use olfactory cues to recognize caregivers. Caregiver odors induce proximity-seeking
behavior and alleviate stress in neonatal mammals, including humans. Since all altricial animals rely on parental
care for survival and children with developmental disorders (e.g., fragile X syndrome and autism) often have
deficits in the olfactory system, it is essential to understand the mechanisms for linking caregiver odors with
affiliative behavior.
Interrogating the effects of serotonin and dopamine on neural activity in the nucleus accumbens during aggression
Studying the brain circuits involved in aggression will help us tackle big social issues like hate crimes, antisocial
behavior, and violence. Imagine if we could better understand why some people act aggressively towards
others—we could use this knowledge to protect people from harm and create a world where everyone feels safe. Chemicals in our brain, such as dopamine and serotonin, affect neural activity to modulate behavior. When we experience something rewarding, like having good food or meeting friends, dopamine is released in the brain.
Interpretable machine learning to decipher gene regulation in brain development and disruption in disease
Brain development is a complex process where cells must self-renew and differentiate at the right place and right time. Gene regulation during development involves sequences in the genome which affect the expression of genes locally, and transcription factors, proteins that bind these sequences and activate genes throughout the genome. At active regulatory sequences and genes, DNA is accessible to these proteins, while inactive DNA is tightly compacted.