Our postdoctoral scholars program provides research support and a community of mentors and peers to extraordinary Stanford postdocs advancing our understanding of the mind and brain in health and disease.
The Wu Tsai Neurosciences Institute's Postdoctoral Scholar Awards support innovative, collaborative and creative postdoctoral researchers from across Stanford who are pursuing novel, multi-disciplinary approaches to understanding the workings of the mind and brain. In addition to receiving research funding, scholars meet regularly for workshops, journal clubs and other activities that allow them to learn from one another’s varied research and personal backgrounds and establish community and collaborations. These Interdisciplinary and Brain Resilience Scholars will advance our knowledge of brain health and aging.
Program Tracks
Interdisciplinary Postdoctoral Scholar Award
Since 2015, the Wu Tsai Neuro's Interdisciplinary Scholars track has supported innovative young researchers with backgrounds in basic and clinical neurosciences, biomedical sciences, physical sciences, social sciences, engineering, education, law, business and humanities who are engaged in cutting edge interdisciplinary research in the neurosciences, broadly defined.
Brain Resilience Postdoctoral Scholar Award
Since 2023, the Brain Resilience Postdoctoral Scholars award of the Knight Initiative for Brain Resilience supports trainees generating paradigm-shifting insights on the mechanisms of neurodegeneration and how to maintain brain resilience into old age.
Application
Deadline to submit your application for the 2025 cohort is Monday, August 26, 2024.
Click here for application and eligibility details.
Program frequently asked questions (FAQs)
Program terms and conditions
Our Model
This program awards two years of fellowship funding and is pleased to provide parental leave. Postdoctoral scholars also receive $5,000 of discretionary research funds annually.
Mentorship
The program provides scientific and career-growth opportunities and guidance under the leadership of program co-directors and faculty mentors Professors Miriam Goodman and Liqun Luo. Scholars meet monthly with their cohort and program faculty mentors to share ideas and discuss approaches to scientific and career challenges, visit each other’s labs to learn about different research techniques and areas of study, and practice communicating their research to scientific and general audiences.
In addition, Brain Resilience Postdoctoral Scholars attend events and seminars hosted by the Knight Initiative for Brain Resilience, and are stewarded by Knight Initiative Associate Director Natasha Hussain and faculty mentor Elizabeth Mormino to learn from one another and build community around the topic of neurodegeneration and brain resilience.
Diversity
The Wu Tsai Neurosciences Institute Postdoctoral program brings together cohorts of postdocs representing the broad range of demographic, experiential and scientific diversity. Women and postdocs from groups underrepresented in the neurosciences are strongly encouraged to apply.
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Application and Eligibility Details
Carefully review the detailed information below if you are interested in applying to the Interdisciplinary Postdoctoral Scholars track or the Brain Resilience Postdoctoral Scholars track of the program.
Meet current and past scholars
Funded Interdisciplinary Postdoctoral Scholar projects
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.
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.
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.
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.
Funded Brain Resilience Postdoctoral Scholar projects
Sleep and neuronal energy management in neurodegeneration
Neural mechanisms of episodic memory resilience in longitudinal aging brains
Maintaining the health and function of the aging brain is crucial to improving the quality of older people’s lives and reducing societal burden. Aging is often accompanied by a decline in memory for life events (episodic memory), especially in those at risk for Alzheimer’s disease (AD). Yet some at-risk individual’s manage to maintain memory function, which raises important questions about the brain mechanisms that underly memory resilience.
Evaluating the immunomodulatory role of circular RNAs in microglia
TREM1 in peripheral myeloid cells exacerbates cognitive decline in aging and Alzheimer's disease
Alzheimer’s disease (AD) is the sixth leading cause of death in the United States and there is a tremendous need for improved therapeutic strategies to treat this prevalent neurodegenerative disease. A devastating symptom of AD is progressive memory loss; this particular disease feature has proven difficult to treat. However, research has begun to unravel novel drivers of AD, including the important role the body’s immune system plays in promoting memory loss.