Vice Provost and Dean of Research
Showing 11-20 of 27 Results
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Joyce Teng, MD, PhD
Professor of Dermatology and, by courtesy, of Pediatrics
BioJoyce Teng, MD, PhD is a professor in dermatology at Stanford University. She is affiliated with multiple hospitals in the area, including Lucile Salter Packard Children's Hospital (LPCH) at Stanford and Stanford Hospital and Clinics (SHC). She received her medical degree from Vanderbilt University School of Medicine and has been in practice for more than 12 years. She is one of the 6 pediatric dermatologists practicing at LPCH and one of 72 at SHC who specialize in Dermatology. She sees patients with rare genetic disorders, birthmarks, vascular anomalies and a variety of inflammatory skin diseases. She is also an experienced pediatric dermatological surgeon. Her research interests are drug discovery and novel therapy for skin disorders.
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Christoph Thaiss
Assistant Professor of Pathology
Current Research and Scholarly InterestsThe Thaiss Lab investigates how gut-brain interactions influence health and disease. By studying microbiome-host communication, the lab explores how microbial signals impact immune function, metabolism, and neurological health. Using multi-omic technologies and computational models, they aim to uncover mechanisms underlying inflammation, neurological disorders, and metabolic diseases. Their research supports the development of personalized therapies targeting the gut-brain axis.
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Avnesh Thakor
Professor of Radiology (Pediatric Radiology)
Current Research and Scholarly InterestsInterventional Radiologists can access almost any part of the human body without the need for conventional open surgical techniques. As such, they are poised to change the way patients can be treated, given they can locally deliver drug, gene, cell and cell-free therapies directly to affected organs using image-guided endovascular, percutaneous, endoluminal, and even using device implantation approaches
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Suzanne Tharin
Associate Professor of Neurosurgery
Current Research and Scholarly InterestsThe long-term goal of my research is the repair of damaged corticospinal circuitry. Therapeutic regeneration strategies will be informed by an understanding both of corticospinal motor neuron (CSMN) development and of events occurring in CSMN in the setting of spinal cord injury. MicroRNAs are small, non-coding RNAs that regulate the expression of “suites” of genes. The work in my lab seeks to identify microRNA controls over CSMN development and over the CSMN response to spinal cord injury.
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Hawa Racine Thiam
Assistant Professor of Bioengineering and of Microbiology and Immunology
Current Research and Scholarly InterestsOur current work has two branches. Branch #1 is building a quantitative and predictive understanding of how neutrophils initiate and complete NETosis. Branch #2 is identifying the molecular and biophysical mechanisms that regulate high deformability in neutrophils. These branches converge onto understanding and harnessing the impact of nuclear biophysics on immune cell functions to re-engineer neutrophils for improved health.
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Robert Tibshirani
Professor of Biomedical Data Science and of Statistics
Current Research and Scholarly InterestsMy research is in applied statistics and biostatistics. I specialize in computer-intensive methods for regression and classification, bootstrap, cross-validation and statistical inference, and signal and image analysis for medical diagnosis.
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Alice Ting
Professor of Genetics, of Biology and, by courtesy, of Chemistry
On Leave from 09/22/2025 To 06/10/2026Current Research and Scholarly InterestsWe develop chemogenetic and optogenetic technologies for probing and manipulating protein networks, cellular RNA, and the function of mitochondria and the mammalian brain. Our technologies draw from protein engineering, directed evolution, computational design, chemical biology, organic synthesis, microscopy, and genomics.
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Andreas Tolias
Professor of Ophthalmology
BioAndreas Tolias is a faculty member at Stanford University, where he co-leads the Enigma Project. His research lies at the interface of neuroscience and AI, combining large-scale neuroscience experiments with machine learning to uncover the principles of natural intelligence. By focusing on perceptual inference and decision-making, his lab integrates systems and computational neuroscience with AI to decipher the network-level principles of intelligence. Dr. Tolias’s work aims to reverse-engineer these principles to create AI systems that are smarter, more robust, trustworthy, and efficient, while providing a powerful platform to test brain algorithms under complex natural tasks. He earned his B.A. and M.A. in Natural Sciences from the University of Cambridge, a Ph.D. in Systems and Computational Neuroscience from MIT, and completed postdoctoral training in Neuroscience and Machine Learning at the Max Planck Institute for Biological Cybernetics in Tübingen.
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Kimberley Tolias
Professor (Research) of Anesthesiology, Perioperative and Pain Medicine
Current Research and Scholarly InterestsThe human brain is composed of billions of neurons connected through trillions of synapses that form the neural circuits underlying thought, emotion, learning, memory, and behavior. These synaptic connections are not static - they are continuously shaped and remodeled throughout life in response to experience, a processes critical for learning and memory. When neural circuits fail to develop or function properly, the consequences can be devastating, contributing to conditions ranging from autism spectrum disorder and intellectual disability to chronic pain, depression, schizophrenia, Alzheimer's disease, and cognitive decline.
Research in the Tolias laboratory seeks to understand the fundamental molecular and cellular mechanisms that govern how neural circuits form, adapt, and repair themselves in the mammalian central nervous system (CNS). Our work focuses on how neurons sense signals from their environment and convert them into intracellular signaling pathways that drive synapse formation and remodeling, dendritic and axonal growth, and cell migration. We are also interested in how disruption of these pathways contributes to neurological and neuropsychiatric disease, and whether targeting specific signaling mechanisms can promote recovery following CNS injury or disease.
The laboratory combines mouse genetics with molecular, cellular, biochemical, electrophysiological, genomic, and behavioral approaches to bridge fundamental neuroscience with translational discovery.
Current Research Areas:
- Molecular mechanisms regulating synapse development, neural circuit formation, and synaptic plasticity during learning and memory
- Roles of Rho GTPase signaling pathways in brain development, circuit remodeling, and neurological disease
- Functions of Adhesion-GPCRs in synapse development, dendritic and axonal growth, and neural circuit function
- Mechanisms underlying chronic pain, opioid tolerance, and chronic pain-associated mood and cognitive disorders
- Synaptic and circuit dysfunction following traumatic brain injury, radiotherapy, and other CNS injuries
- Development of new tools to visualize and map synaptic remodeling during learning and disease
- Interactions between the gut microbiome, brain development, neural circuit function, and behavior
