Electroencephalography (EEG) measures the brain’s local field potential from the surface of the scalp. This method is useful for studying cognitive processes, neurological states, and medical conditions.
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.
Project Summary Categorizing individual neurons into different groups, or cell types, is a classical approach to studying the nervous system.
PROJECT SUMMARY / ABSTRACT The BRAIN Initiative’s -omics data archive NeMO contains all the BICCN single cell single cell data, more than one million files at the time of writing.
PROJECT SUMMARY / ABSTRACT Functional MRI (fMRI) is today the predominant tool for noninvasive imaging of brain function, which has revolutionized our understanding of the human brain.
ABSTRACT Perceptually guided behavior involves a complex and dynamic interplay between external inputs and internal states that are related, for example, to alertness, motivation, expectations and attention.
Project Summary Schizophrenia is a debilitating mental illness affecting an estimated 1% of the global population.
Project Summary Learning and performing complex skills such as speech or music requires precise control of motor variability. While elevated motor variability can spur the learning of new behaviors, excessive variability can impair performance of learned skills.
Direct local electrical stimulation (DLES) is an increasingly important therapeutic tool for treating brain disorders such as Parkinson’s, epilepsy, and OCD.
ABSTRACT The generation of scientifically rich, high resolution neuroimaging volumes continues to increase in extent and rate due to the advancement of new Electron Microscopy (EM) and X-ray Microtomography (XRM) imaging sys- tems and data processing methodologies.
Project Summary/Abstract The proposed project will demonstrate the feasibility of generating a complete synapse-level brain map (connectome) by developing a serial-section electron microscopy pipeline that could scale to a whole mouse brain.
Project Summary: Center for whole mouse brain connectomics using high-throughput integrated volumetric electron microscopy (HIVE) Two fundamental components of the structural basis of brain function are cell type composition and the wiring diagram between those cells.
PROJECT SUMMARY To understand complex neural pathways and networks and their remarkable ability to generate human behaviors, it is critical to precisely map brain connectomics in vivo.
SUMMARY This ambitious proposal will establish an integrated experimental-computational platform to create the first comprehensive brain-wide mesoscale connectivity map in a non-human primate, the common marmoset (Callithrix jacchus),.
Project Summary Mapping the brain-wide connections of neurons provides a foundation for understanding the structure and functions of a brain.
Project Summary/Abstract (30 lines of text limit) The ~1 billion neurons that form the human brainstem are organized at multiple scales, ranging from their cell type-specific patterns of dendritic arborization, to local circuits embedded within large-scale projection systems spanning the brainste
Project Summary/Abstract Volume electron microscopy is the only technique to-date that provides both sufficient resolution (100 μm) for the dense reconstruction of neuronal wiring diagrams.
Project Summary / Abstract Upcoming brain-wide descriptions of synaptic connectivity are poised to transform our understanding of brain circuitry in the same way single-cell genomics has revolutionized our understanding of cell type diversity.
SUMMARY High-throughput connectomics is needed to generate the TB-, PB- and EB-scale wiring diagrams of mammalian brains, but is limited to the few research institutes (e.g., Janelia, Allen, Max Planck) with sufficient infrastructure.
ABSTRACT Single-cell transcriptomics has revolutionized our understanding of neuronal diversity and enabled high-throughput characterization of molecular cell types across brain areas and species.
Project summary: This project will develop and validate a comprehensive toolset of novel technologies for imaging axonal projections across scales, and will deploy this toolset to map a complex system of cortico- subcortical projections in the macaque and human brain.