Neurotechnology

Picower Institute Neuroscientists don't just apply the latest technologies and methods for studying the brain, they also often invent them. To learn more about how researchers here work at, and expand, the frontiers of research, select them under Research Topics and you'll find relevant Picower people, discoveries and events.

Picower Professor of Neuroscience

Bear’s lab studies how experience and deprivation modify synaptic connections in the brain. Experience-dependent synaptic plasticity is the physical substrate of memory and sculpts connections during postnatal development to determine the capabilities and limitations of brain functions.

Research Areas

mGluR5, LTD, LTP, monocular deprivation, habituation, potentiation, amblyopia, visual cortex

Y. Eva Tan Professor in Neurotechnology, Howard Hughes Medical Institute and McGovern Institute, Departments of Brain and Cognitive Sciences, Media Arts and Sciences, and Biological Engineering

Ed Boyden's group develops tools for analyzing and repairing complex biological systems such as the brain, and applies them systematically to reveal ground truth principles of biological function as well as to repair these systems.

Research Areas

optogenetics, neurotechnology, circuits, oscillations, deep brain stimulation

Edward Hood Taplin Professor of Medical Engineering and Computational Neuroscience

Brown lab research contributes to understanding the neuroscience of how anesthetics act in the brain to create the states of general anesthesia. Brown has developed signal processing algorithms to solve important data analysis challenges in neuroscience.

Research Areas

anesthesia, arousal, consciousness, neural systems, fMRI, motor cortex, EEG, MEG, microdialysis, epilepsy

Investigator in The Picower Institute for Learning and Memory

Chung’s interdisciplinary research team develops technologies for holistic understanding of large-scale complex biological systems. Methods including CLARTIY, MAP and SWITCH enable identification of multi-scale functional networks and interrogation of their system-wide, multifactorial interactions.

Research Areas

CLARITY, MAP, SWITCH, neurotechnology, organoids, neural systems

Investigator in The Picower Institute for Learning and Memory

The goal of the Fan Lab is to decipher the neural codes underlying learning and memory and to identify the physical basis of learning and memory. In this work, the lab innovates and employs all-optical techniques to read out and manipulate neural circuits.

Research Areas

optogenetics, spatial memory, plasticity, synaptic plasticity, all-optical physiology, neurotechnology, voltage imaging

Investigator in The Picower Institute for Learning and Memory

Neural operations occur in milliseconds, yet the brain generates behaviors that can last hours. Flavell’s lab studies how neural circuits generate sustained behavioral states, and how physiological and environmental information is integrated into these circuits.

Research Areas

neuromodulation, behavior, calcium imaging, C. elegans, gut-brain signaling, feeding states, serotonin

Athinoula A. Martinos Associate Professor, Electrical Engineering & Computer Science

Lewis develops multimodal approaches for imaging the human brain, and applies them to study the neural circuitry that controls sleep, and the consequences of sleep for brain function.

Research Areas

Sleep, fMRI, EEG, attention, depression, aging, neurodegeneration, thalamus

Menicon Professor in Neuroscience

Littleton studies how neurons form synaptic connections, how synapses transmit information, and how synapses change during learning and memory. The research combines molecular biology, protein biochemistry, electrophysiology, and imaging approaches with Drosophila genetics.

Research Areas

synapse formation, synaptic transmission, glia, epilepsy, neurological disorders, NMJ

William R. (1964) & Linda R. Young Professor of Neuroscience

Nedivi’s lab investigates the cellular mechanisms of activity-dependent plasticity through studies of synaptic and neuronal remodeling, identification of participating genes, and characterization of the cellular functions of the proteins they encode.

Research Areas

synaptic plasticity, synapse assembly, synapse disassembly, plasticity genes, CPG15, Neuritin, CPG2, SYNE1, visual system, In vivo cellular imaging, inhibitory circuits, Bipolar Disorder

Newton Professor of Neuroscience

The goal of the Sur laboratory is to understand long-term plasticity and short-term dynamics in circuits of the developing and adult cortex, and to utilize this understanding to discover mechanisms underlying disorders of brain development.

Research Areas

cerebral cortex, plasticity, development, circuits, attention, autism spectrum disorders, Rett syndrome, organoids, neurotechnology, multiphoton imaging, astrocytes

Picower Professor of Biology and Neuroscience

With cutting-edge neuroscience techniques, the Tonegawa lab unravels the molecular, cellular, and neural circuit mechanisms that underlie learning and memory. Studies bridge basic science and disease models to causally dissect how memory works and breaks down.

Research Areas

hippocampus, memory consolidation, circuit mapping, neuromodulation, engram, neurotechnology, inception, depression, place cells, amygdala, valence

Picower Professor of Neuroscience

The Tsai lab is interested in elucidating the pathogenic mechanisms underlying neurological disorders that impact learning and memory by taking a multidisciplinary approach to investigate the molecular, cellular, and circuit basis of neurodegenerative disorders.

Research Areas

Alzheimer's dementia, Down syndrome, Single Cell Transcriptomics and Epigenomics, iPSCs, Brain Rhythms, Neuroimmune interactions, myelination, ApoE, lipid metabolism, Neuronal DNA damage

Mark Bear

Ed Boyden

Emery N. Brown

Kwanghun Chung

Linlin Fan

Steven Flavell

Laura Lewis

Troy Littleton

Elly Nedivi

Mriganka Sur

Susumu Tonegawa

Li-Huei Tsai