Circuit Diagrams

 DESCRIPTION (provided by applicant): Genetic tools have dramatically increased the power and resolution of neuroscientific experiments, allowing monitoring and perturbation of specific neuronal populations within the brain, often in the context of complex cognitive and behavioral paradigms. However, the usefulness of these tools is limited by the available means of delivering them in circuit-specific ways, a major drawback in view of the critical importance of specific connectivity between individual neurons and between neuronal classes.

 DESCRIPTION (provided by applicant): Our understanding of brain function at the cellular and circuit level is critically dependent on the ability to interrogate and alter neural cells withhigh specificity. The use of light, either through single-photon or multi- photon excitation, is the onl method that provides sufficient resolution to probe the brain at the cellular and subcellular levels.

 DESCRIPTION (provided by applicant): Dramatic new insights into the functioning of neural networks have been made possible by our ability to visualize neural function with calcium-sensitive fluorophores, and biology has been revolutionized by the ability to sequence and manipulate DNA, RNA, and proteins. Both of these tremendous advances have unexplored "flip sides". Our understanding of neural network function remains limited by our inability see GABA-mediated synaptic activity: we can't measure the output of the remarkable diversity of interneuron structure and function.

 DESCRIPTION (provided by applicant): Cajal revolutionized the study of the brain through the use of the Golgi stain to label cells sparsely and stochastically in a fashion that revealed a neuron's morphology in its entirety. Although genetic tools for sparse and stochastic labeling and manipulation of single neurons in Drosophila have been used extensively over the past 15 years, they have only recently become available for mammalian systems, but the latter tools are limited to only a few systems for which cell-type specific reagents (e.g.

 DESCRIPTION (provided by applicant): This proposal is to administer and further develop a successfully established two-week summer training course titled "Mining and Modeling of Neuroscience Data" which is held at UC Berkeley. The course teaches methods for analyzing neurophysiology data, that is, measurements of the neural activity over time, co-registered with behavior or stimuli.

Project Summary We seek support to develop and build the next generation 7-Tesla magnetic resonance (MR)-compatible positron emission tomography (PET) brain scanner with dramatically improved spatiotemporal resolution (HSTR-BrainPET). PET and MRI are two of the most powerful imaging modalities currently in use for studying the human brain. Recently, scanners capable of simultaneous PET and MR whole-body data acquisition in human subjects have become commercially available.

ABSTRACT The overarching goal of this project is to optimize, validate and implement a revolutionary and safe modality for noninvasive functional imaging of neural currents deep in the human brain through the skull at unprecedented spatial and temporal resolution. Transcranial Acoustoelectric Brain Imaging (tABI) is a disruptive technology that exploits pulses of ultrasound (US) to transiently interact with physiologic current, producing a radiofrequency (RF) signature detected by one or more sensors (e.g., surface electrodes).

PROJECT SUMMARY/ABSTRACT An innovative head-only 7T MRI system that delivers spatial resolution that is difficult to achieve with today's whole-body 7T systems, and has the footprint and weight of a whole-body 3T scanner is proposed. This new im- aging system combines a high-performance asymmetrical head gradient that delivers 130 mT/m and 900 T/m/s performance in an actively shielded, low-cryogen, lightweight head-only 7T magnet.

Project Summary: High SNR Functional Brain Imaging using Oscillating Steady State MRI Functional brain imaging using MRI (functional MRI or fMRI) has grown rapidly over the past 25 years and is widely used for basic cognitive neuroscience research and for presurgical planning. It is increasingly being used for developing biomarkers for neurological and psychiatric disorders and for population based studies of, for example, normal and abnormal development and aging.

PROJECT SUMMARY    Understanding how neural circuits operate and interconnect at mesoscopic (sub-­millimeter) scale, and how  neuroenergetic  metabolism  and  neurotransmitters  support  brain  function  at  resting  and  working  state  is  essential to brain research and