Funded Awards

The National Institutes of Health (NIH) BRAIN Initiative funds a wide-variety of research: toolmakers, trainees, individual labs testing new hypotheses, and large, team-based efforts aiming to catalyze neuroscience inquiry forward. Explore NIH BRAIN Initiative funded awards listed below. Click on the project title to learn more about it within NIH RePORTER.

To see more NIH-funded awards and associated publications, please visit the NIH RePORTER.

Funded Awards Search

Title

Investigator(s)

Institution

Fiscal Year

Funding Opportunity #

Project #

Thalamocortical state control of tactile sensing: Mechanisms, Models, and Behavior

Garrett B. Stanley

georgia institute of technology

2018

RFA-NS-17-014

1R01NS104928-01

Thalamocortical state control of tactile sensing: Mechanisms, Models, and Behavior Despite the fact that the sensory thalamus plays a major role in shaping sensory representations in cortex, and thus shaping our percepts, most of what we know has been determined through electrophysiological investig

The biophysics and potential cell-type selectivity of acoustic neuromodulation

Robert Crooks Froemke, Eitan Kimmel, Shy Shoham

new york university school of medicine

2018

RFA-NS-18-018

1R01NS109885-01

Summary Neuroscience has an essential requirement for large-scale perturbation tools. Such tools would be transformative in the mapping of brain function, the causal testing of neurotheoretic models, and the diagnosis and treatment of neurological disorders.

The Brainstorm Project: A Collaborative Approach to Facilitating the Neuroethics of Bioengineered Brain Modeling Research

Insoo Hyun

case western reserve university

2018

RFA-MH-18-500

1RF1MH117803-01

Project Summary – Abstract Neuroscientists are getting close to building realistic bioengineered ex vivo human brain models by: (1) introducing perfusable vascular networks to maintain tissue viability and promote 3D brain model growth; (2) generating the full complement of currently missing cell ty

The Development and Human Translation of Temporal Interference Brain Stimulation

Daniel Z. Press

beth israel deaconess medical center

2018

RFA-MH-17-240

1R01MH117063-01

PROJECT SUMMARY Deep brain stimulation (DBS) has had great impact, helping patients with disorders such as Parkinson's disease and obsessive–compulsive disorder (OCD), and with great potential for other disorders such as depression and Alzheimer's disease.

The diversity of dopamine neurons: from connectivity and activity to functions.

Naoshige Uchida

harvard university

2018

RFA-NS-18-009

1R01NS108740-01

Project Summary Dopamine neurons (DNs) are key regulators of motivated behaviors, and defects in dopamine signaling may underlie some psychiatric disorders including addiction, depression, and schizophrenia, as well as neurological disorders such as Parkinson's.

The impact of spontaneous cortical activity on neural oscillations and behavioral performance: Evidence from high-definition tDCS and MEG

Tony W Wilson

university of nebraska medical center

2018

RFA-MH-17-245

1RF1MH117032-01

Project Summary/Abstract This proposal responds to RFA-MH-17-245, which requests applications focusing on the mechanisms and dose- response relationships of noninvasive neuromodulatory methods.

The Neuronal Underpinnings of Non-invasive Laminar fMRI

Orrin Devinsky, Essa Yacoub

university of minnesota

2018

RFA-MH-17-235

1RF1MH116978-01

The six layers of cortex form distinct computational units that together govern the information flow and processing required for complex behavior. Hence, unravelling the brain's computational strategies requires understanding the layer-specific organization of the neocortex.

Toward 3D human brain-like tissues for targeting dysregulated synapse and proteostasis mechanisms in autism spectrum disorder

Joshua Dean Erndt-Marino

tufts university medford

2018

RFA-MH-18-510

1F32MH118678-01

TOWARD 3D HUMAN BRAIN-LIKE TISSUES FOR TARGETING DYSREGULATED SYNAPSE AND PROTEOSTASIS MECHANISMS IN AUTISM SPECTRUM DISORDER Autism spectrum disorder (ASD) is a neurodevelopmental disease affecting nearly 1/50 children in US with an estimated $268 billion in annual costs.

Toward a human adult brain cell atlas with single-cell technologies

Jerold Chun, Kun Zhang

university of california, san diego

2018

RFA-MH-17-210

1U01MH114828-01A1

Abstract Human brain is an exceedingly complex network of spatially organized and functionally connected neurons imbedded in glia.

Towards integrated 3D reconstruction of whole human brains at subcellular resolution

Kwanghun Chung

massachusetts institute of technology

2018

RFA-MH-17-210

1U01MH117072-01

Project Summary A detailed understanding of the anatomical and molecular architectures of brain cells and their brain-wide organization is essential for interrogating human brain function and dysfunction.

TRACT: A TOOL TO INVESTIGATE BRAIN CONNECTIVITY AND TO GENETICALLY MANIPULATE NEURONS CONNECTED BY SYNAPSES

Elizabeth Jennifer Hong, Carlos Lois

california institute of technology

2018

RFA-MH-18-505

1RF1MH117825-01

! PROJECT SUMMARY Deciphering the brain’s wiring diagram is widely thought to be necessary towards understanding how brain circuits process information. However, this goal is extremely challenging because currently available methods to study brain connectivity suffer from important limitations.

Trans-synaptic bidirectional tracing tools for imaging and omics analysis

Nirao Mahesh Shah, Alice Y Ting

stanford university

2018

RFA-MH-18-505

1RF1MH117821-01

Project Summary Trans‐synaptic bidirectional tracing tools for imaging and omics analysis A central question in systems neuroscience is how hormones, such as estrogen, regulate animal behavior at the level of synapses and circuits.

Transgenic mice and multiplexed, multi-beam instrumentation for large-scale optical experiments on brain states and ensemble cellular dynamics in behaving animals

Mark J Schnitzer, Hongkui Zeng

stanford university

2018

RFA-NS-17-004

1UF1NS107610-01

Abstract The NIH BRAIN Initiative report emphasizes the importance of integrated technological approaches that combine multiple, complementary and groundbreaking capabilities in a single, highly advanced instrument. Optical methods have tremendous potential for integration, by combining massive reco

Transparent graphene electrode arrays for simultaneous electrical and optical investigation of computations in the olfactory bulb

Morgan A Brown

university of oregon

2018

RFA-MH-18-510

1F32MH118724-01

Project Summary and Abstract A major obstacle to understanding the link between behavior and neuronal activity is the difficulty of electrophysiologically recording the activity of large neuronal populations without limiting visual access.

Ultra High Resolution Brain PET Scanner for in-vivo Autoradiography Imaging

Georges El Fakhri, Roger Lecomte

massachusetts general hospital

2018

RFA-EB-17-004

1U01EB027003-01

We propose to design, build, and evaluate the Scanner Approaching in Vivo Autoradiographic Neuro Tomography (SAVANT), a next generation PET scanner for ultra-high resolution imaging of the human brain using hardware advances developed by members of our collaborative team to achieve unprecedented spa

Ultrasonic neuromodulation: establishing mechanisms and parameters to optimize targeted neuromodulation and control sensory side-effects

Michael Ortiz, Shinsuke Shimojo, Mikhail Shapiro

california institute of technology

2018

RFA-MH-17-245

1RF1MH117080-01

Project Abstract One of the major goals of the BRAIN initiative is to develop technologies capable of interfacing with specific neural circuits in the human brain.

Understanding V1 circuit dynamics and computations

Kenneth D Miller, Massimo Scanziani

columbia university health sciences

2018

RFA-NS-17-018

1U19NS107613-01

Understanding the cerebral cortex requires data-based theoretical models that can yield in- sight into the circuit mechanisms of cortical computation, and reproduce detailed cortical dynamics across stimuli and brain states.

Unraveling constraints on motor cortical activity exploration and shaping during structural skill learning using large-scale 2-photon imaging and holographic optogenetic stimulation

Vivek Athalye

columbia university health sciences

2018

RFA-MH-18-510

1F32MH118714-01

Project Summary When learning new skills, experience with previously-learned skills can facilitate faster learning by constraining behavioral exploration and shaping, a concept known as “structural learning”3,4.

Unveiling the mechanisms of ultrasound neuromodulation via spatially confined stimulation and temporally resolved recording

Ji-Xin Cheng, Xue Han

boston university (charles river campus)

2018

RFA-NS-18-018

1R01NS109794-01

Project Summary Ultrasound has been explored as a modality to modulate nerves and muscles back in the 1920s. A number of recent studies have demonstrated the feasibility of using ultrasound to stimulate peripheral nerves, spinal cord, and brain.

Using functionally-defined glomeruli to probe circuit function in the mammalian olfactory bulb

Dale M Wachowiak

university of utah

2018

RFA-NS-18-009

1R01NS109979-01

PROJECT SUMMARY We seek to better understand how the brain processes olfactory information by focusing on how circuits of the olfactory bulb control two fundamental aspects of sensory processing: the relationship between sensory input and olfactory bulb output as a function of stimulus intensity, a

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Last reviewed on July 02, 2025