School of Medicine
Showing 1-50 of 68 Results
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Stephen A. Baccus
Professor of Neurobiology
Current Research and Scholarly InterestsWe study how the neural circuitry of the vertebrate retina encodes visual information and performs computations. To control and measure the retinal circuit, we present visual images while performing simultaneous two-photon imaging and multielectrode recording. We perturb the circuit as it operates using simultaneous intracellular current injection and multielectrode recording, and use the resulting large data sets to construct models of retinal computation.
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Thomas Clandinin
Shooter Family Professor
Current Research and Scholarly InterestsThe Clandinin lab focuses on understanding how neuronal circuits assemble and function to perform specific computations and guide behavior. Taking advantage of a rich armamentarium of genetic tools available in the fruit fly, combined with imaging, physiology and analytical techniques drawn from systems neuroscience, we examine a variety of visual circuits.
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Shaul Druckmann
Associate Professor of Neurobiology, of Psychiatry and Behavioral Sciences and, by courtesy, of Electrical Engineering
Current Research and Scholarly InterestsOur research goal is to understand how dynamics in neuronal circuits relate and constrain the representation of information and computations upon it. We adopt three synergistic strategies: First, we analyze neural circuit population recordings to better understand the relation between neural dynamics and behavior, Second, we theoretically explore the types of dynamics that could be associated with particular network computations. Third, we analyze the structural properties of neural circuits.
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Surya Ganguli
Associate Professor of Applied Physics, Senior Fellow at the Stanford Institute for Human-Centered AI and Associate Professor, by courtesy, of Neurobiology and of Electrical Engineering
Current Research and Scholarly InterestsTheoretical / computational neuroscience
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Lisa Giocomo
Professor of Neurobiology
Current Research and Scholarly InterestsMy laboratory studies the cellular and molecular mechanisms underlying the organization of cortical circuits important for spatial navigation and memory. We are particularly focused on medial entorhinal cortex, where many neurons fire in spatially specific patterns and thus offer a measurable output for molecular manipulations. We combine electrophysiology, genetic approaches and behavioral paradigms to unravel the mechanisms and behavioral relevance of non-sensory cortical organization. Our first line of research is focused on determining the cellular and molecular components crucial to the neural representation of external space by functionally defined cell types in entorhinal cortex (grid, border and head direction cells). We plan to use specific targeting of ion channels, combined with in vivo tetrode recordings, to determine how channel dynamics influence the neural representation of space in the behaving animal. A second, parallel line of research, utilizes a combination of in vivo and in vitro methods to further parse out ionic expression patterns in entorhinal cortices and determine how gradients in ion channels develop. Ultimately, our work aims to understand the ontogenesis and relevance of medial entorhinal cortical topography in spatial memory and navigation.
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Chenzhou Hao
Basic Life Research Scientist, Department of Neurobiology
BioMy expertise encompasses drug design, screening, and optimization. Currently, I am collaborating with my team to discover next-generation antiviral drugs targeting potentially pandemic viruses through structure-based drug discovery approaches.
My research interests include scientific visualization and structural biology, and I am eager to contribute to human health as a drug hunter in the future. In addition to my passion for research, I enjoy music, history, and architecture.
https://orcid.org/0000-0001-6803-7270 -
Keren Haroush
Assistant Professor of Neurobiology
Current Research and Scholarly InterestsOur laboratory studies the mechanisms by which highly complex behaviors are mediated at the neuronal level, mainly focusing on the example of dynamic social interactions and the neural circuits that drive them. From dyadic interactions to group dynamics and collective decision making, the lab seeks a mechanistic understanding for the fundamental building blocks of societies, such as cooperation, empathy, fairness and reciprocity.
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Andrew D. Huberman
Associate Professor of Neurobiology and, by courtesy, of Psychiatry and Behavioral Sciences
Current Research and Scholarly InterestsAndrew Huberman is a tenured associate professor of neurobiology and of ophthalmology at Stanford University School of Medicine, where he directs the Huberman Lab. After earning his B.A. from the University of California, Santa Barbara and completing M.A. and Ph.D. degrees in neuroscience at UC Berkeley and UC Davis, he conducted post-doctoral work at Stanford.
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Eric I. Knudsen
Edward C. and Amy H. Sewall Professor in the School of Medicine, Emeritus
Current Research and Scholarly InterestsCellular mechanisms of spatial attention and learning, studied in the central nervous system in birds, using behavioral, systems, cellular and molecular techniques.
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Michael Lin
Professor of Neurobiology, of Bioengineering and, by courtesy, of Chemical and Systems Biology
Current Research and Scholarly InterestsOur lab applies biochemical and engineering principles to the development of protein-based tools for investigating biology in living animals. Topics of investigation include fluorescent protein-based voltage indicators, synthetic light-controllable proteins, bioluminescent reporters, and applications to studying animal models of disease.
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Liqun Luo
Ann and Bill Swindells Professor and Professor, by courtesy, of Neurobiology
Current Research and Scholarly InterestsWe study how neurons are organized into specialized circuits to perform specific functions and how these circuits are assembled during development. We have developed molecular-genetic and viral tools, and are combining them with transcriptomic, proteomic, physiological, and behavioral approaches to study these problems. Topics include: 1) assembly of the fly olfactory circuit; 2) assembly of neural circuits in the mouse brain; 3) organization and function of neural circuits; 4) Tool development.
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Uel Jackson McMahan
Professor of Neurobiology and of Structural Biology, Emeritus
Current Research and Scholarly InterestsWe are currently investigating mechanisms involved in synaptic transmission and synaptogenesis using electron microscope tomography in ways that provide in situ 3D structural information at macromolecular resolution.
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Lloyd B. Minor, MD
The Carl and Elizabeth Naumann Dean of the School of Medicine, Vice President for Medical Affairs, Stanford University, Professor of Otolaryngology - Head and Neck Surgery and Professor of Neurobiology and of Bioengineering, by courtesy
Current Research and Scholarly InterestsThrough neurophysiological investigations of eye movements and neuronal pathways, Dr. Minor has identified adaptive mechanisms responsible for compensation to vestibular injury in a model system for studies of motor learning. Following his discovery of superior canal dehiscence, he published a description of the disorder’s clinical manifestations and related its cause to an opening in the bone covering of the superior canal. He subsequently developed a surgical procedure to correct the problem.
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Tirin Moore
Ben Barres Professor
Current Research and Scholarly InterestsWe study neural circuit mechanisms of visual perception, cognition and sensorimotor integration.
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William Newsome
Harman Family Provostial Professor and Professor of Neurobiology and, by courtesy, of Psychology
Current Research and Scholarly InterestsNeural processes that mediate visual perception and visually-based decision making. Influence of reward history on decision making.
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Jennifer L. Raymond
Berthold and Belle N. Guggenhime Professor
Current Research and Scholarly InterestsWe study the neural mechanisms of learning, using a combination of behavioral, neurophysiological, and computational approaches. The model system we use is a form of cerebellum-dependent learning that regulates eye movements.
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Laura Seeholzer
Assistant Professor of Neurobiology
BioMy laboratory studies how we detect, perceive, and respond to sensations from within our own bodies. We focus on understanding how the airways sense potentially harmful substances and trigger protective reflexes like coughing and sneezing. Using techniques ranging from molecular and biophysical studies of single cells to behavioral studies, we investigate how specialized epithelial cells lining the airways detect different types of stimuli and communicate this information to the nervous system. By studying epithelial cells from animal models and humans, we aim to understand how their dysfunction contributes to conditions like chronic cough and aspiration. We also examine how the brain processes these internal signals to create the conscious "urge" to cough or sneeze, and how we learn to suppress these reflexes in appropriate social contexts. This research advances our understanding of the fundamental mechanisms linking bodily sensations to conscious awareness, behavioral control, and disease.
I did my PhD at Rockefeller University with Dr. Vanessa Ruta and post-doctoral studies at UCSF with Dr. David Julius. -
Nirao Shah
Professor of Psychiatry and Behavioral Sciences (Major Laboratories and Clinical Translational Neurosciences Incubator), of Neurobiology and, by courtesy, of Obstetrics and Gynecology
Current Research and Scholarly InterestsWe study how our brains generate social interactions that differ between the sexes. Such gender differences in behavior are regulated by sex hormones, experience, and social cues. Accordingly, we are characterizing how these internal and external factors control gene expression and neuronal physiology in the two sexes to generate behavior. We are also interested in understanding how such sex differences in the healthy brain translate to sex differences in many neuro-psychiatric illnesses.
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Carla Shatz
Sapp Family Provostial Professor and Professor of Biology and of Neurobiology
Current Research and Scholarly InterestsThe goal of research in the Shatz Laboratory is to discover how brain circuits are tuned up by experience during critical periods of development both before and after birth by elucidating cellular and molecular mechanisms that transform early fetal and neonatal brain circuits into mature connections. To discover mechanistic underpinnings of circuit tuning, the lab has conducted functional screens for genes regulated by neural activity and studied their function for vision, learning and memory.
