OARS funding Neuroscience

The purpose of this graduate-level training program is to improve the health of infants, children, and adolescents who have, or are at risk for developing, autism spectrum disorder (ASD) or other neurodevelopmental and other related disabilities (DD), by expanding interdisciplinary training opportunities for graduate-level trainees from a wide variety of professional disciplines. 

The National Institutes of Health (NIH) invites applications for institutional research capacity building programs from entities/institutions in Institutional Development Award (IDeA)-eligible States that propose to support a team of experts to engage and implement pediatric clinical trials. The program aims to provide research infrastructure as well as supervised professional development in research and clinical trial implementation to assist institutions in IDeA-eligible States in establishing and maintaining pediatric clinical trial teams.

The purpose of this Funding Opportunity Announcement is to encourage research on the basic biology of the intervertebral disc and on the molecular mechanisms underlying intervertebral disc degeneration. Back/spinal pain, which is a major public health concern in the United States, is strongly associated with intervertebral disc degeneration. Acute low back pain that is serious enough to disrupt daily routines affects about 70 percent of adults sometime during their lives. In the vast majority of patients, low back pain resolves within a few weeks with conservative medical management. 

The CDC Epilepsy Program is announcing a new, FY16 non-research FOAs designed to improve health and quality of life for people with epilepsy.

The purpose of this FOA is to invite innovative research pre-applications from applicants who have an interest in submitting an application to "Stimulating Peripheral Activity to Relieve Conditions (SPARC): Technologies to Understand the Control of Organ Function by the Peripheral Nervous System (OT2)", companion announcement RFA-RM-16-003.  This NIH Funding Opportunity Announcement (FOA) solicits pre-applications to develop new and/or enhance existing tools and technologies to be used to elucidate the neurobiology and neurophysiology underlying autonomic control of organs in health or disease, which will ultimately inform next generation neuromodulation therapies. These two-year projects will facilitate technology development for neural mapping activities through the NIH SPARC Common Fund program.

The purpose of this FOA is to invite innovative research pre-applications from applicants who have an interest in submitting an application to "Stimulating Peripheral Activity to Relieve Conditions (SPARC): Technologies to Understand the Control of Organ Function by the Peripheral Nervous System (OT2)", companion announcement RFA-RM-16-003.  This NIH Funding Opportunity Announcement (FOA) solicits pre-applications to develop new and/or enhance existing tools and technologies to be used to elucidate the neurobiology and neurophysiology underlying autonomic control of organs in health or disease, which will ultimately inform next generation neuromodulation therapies. These two-year projects will facilitate technology development for neural mapping activities through the NIH SPARC Common Fund program.

The purpose of this Brain Research through Advancing Innovative Neurotechnologies (BRAIN) Initiative is to encourage applications that will develop and validate novel tools to facilitate the detailed analysis of complex circuits and provide insights into cellular interactions that underlie brain function. The new tools and technologies should inform and/or exploit cell-type and/or circuit-level specificity. Plans for validating the utility of the tool/technology will be an essential feature of a successful application. The development of new genetic and non-genetic tools for delivering genes, proteins and chemicals to cells of interest or approaches that are expected to target specific cell types and/or circuits in the nervous system with greater precision and sensitivity than currently established methods are encouraged. Tools that can be used in a number of species/model organisms rather than those restricted to a single species are highly desired. Applications that provide approaches that break through existing technical barriers to substantially improve current capabilities are highly encouraged.

The purpose of this Brain Research through Advancing Innovative Neurotechnologies (BRAIN) Initiative is to encourage applications that will develop and validate novel tools to facilitate the detailed analysis of complex circuits and provide insights into cellular interactions that underlie brain function. The new tools and technologies should inform and/or exploit cell-type and/or circuit-level specificity. Plans for validating the utility of the tool/technology will be an essential feature of a successful application. The development of new genetic and non-genetic tools for delivering genes, proteins and chemicals to cells of interest or approaches that are expected to target specific cell types and/or circuits in the nervous system with greater precision and sensitivity than currently established methods are encouraged. Tools that can be used in a number of species/model organisms rather than those restricted to a single species are highly desired. Applications that provide approaches that break through existing technical barriers to substantially improve current capabilities are highly encouraged.

The General & Age Related Disabilities Engineering (GARDE) program supports fundamental engineering research that will lead to the development of new technologies, devices, or software that improve the quality of life of persons with disabilities. Research may be supported that is directed toward the characterization, restoration, and/or substitution of human functional ability or cognition, or to the interaction of persons with disabilities and their environment. Areas of particular interest are disability-related research in neuroengineering and rehabilitation robotics. Emphasis is placed on significant advancement of fundamental engineering knowledge that facilitates transformative outcomes. We discourage applications that propose incremental improvements. Applicants are encouraged to contact the Program Director prior to submitting a proposal.

The General & Age Related Disabilities Engineering (GARDE) program supports fundamental engineering research that will lead to the development of new technologies, devices, or software that improve the quality of life of persons with disabilities. Research may be supported that is directed toward the characterization, restoration, and/or substitution of human functional ability or cognition, or to the interaction of persons with disabilities and their environment. Areas of particular interest are disability-related research in neuroengineering and rehabilitation robotics. Emphasis is placed on significant advancement of fundamental engineering knowledge that facilitates transformative outcomes. We discourage applications that propose incremental improvements. Applicants are encouraged to contact the Program Director prior to submitting a proposal.

The goal of this FOA is to advance research on the underlying basis for the transfer (or transposition) of aging phenotypes observed between young and old rodents and discovered through heterochronic parabiosis. Examples of transposed phenotypes include reversal of cardiac hypertrophy, partial restoration of cognitive function, improved vascularization, and repair of skeletal muscle after cryo-injury (anti-geronic transposition), or as accelerated loss of cognitive function and neurogenesis (pro-geronic transposition). Other transposed phenotypes, as revealed solely through heterochronic parabiosis, may also be reported in the literature. There are also reports of candidate factors found in circulation that might be causally related to the transposition of these aging phenotypes; these are termed "circulating geronic factors" for purposes of this FOA. To date, these are proteins and peptides that pass between the young and old mice joined by parabiosis, due to anastomosis of their circulatory systems. Based on these novel findings and this novel experimental paradigm, the specific objective of this FOA is to test whether these candidate geronic factors are necessary for the transposition of aging phenotypes. The focus is on phenotypes transposed in heterochronic parabiosis and the candidate factors which are present and functional at physiological concentrations in circulation.

The goal of this FOA is to advance research on the underlying basis for the transfer (or transposition) of aging phenotypes observed between young and old rodents and discovered through heterochronic parabiosis. Examples of transposed phenotypes include reversal of cardiac hypertrophy, partial restoration of cognitive function, improved vascularization, and repair of skeletal muscle after cryo-injury (anti-geronic transposition), or as accelerated loss of cognitive function and neurogenesis (pro-geronic transposition). Other transposed phenotypes, as revealed solely through heterochronic parabiosis, may also be reported in the literature. There are also reports of candidate factors found in circulation that might be causally related to the transposition of these aging phenotypes; these are termed "circulating geronic factors" for purposes of this FOA. To date, these are proteins and peptides that pass between the young and old mice joined by parabiosis, due to anastomosis of their circulatory systems. Based on these novel findings and this novel experimental paradigm, the specific objective of this FOA is to test whether these candidate geronic factors are necessary for the transposition of aging phenotypes. The focus is on phenotypes transposed in heterochronic parabiosis and the candidate factors which are present and functional at physiological concentrations in circulation.

This Funding Opportunity Announcement (FOA) solicits grant applications in two related but distinct areas.The first area is in the development and testing of novel tools and methods of neuromodulation that go beyond the existing variations on magnetic or electrical stimulation, and that represent more than an incremental advance over existing electromagnetic approaches. The second distinct area that this FOA seeks to encourage is the optimization of existing electrical and magnetic stimulation methods.

This FOA seeks applications for proof-of-concept testing and development of new technologies and novel approaches for large-scale recording and manipulation of neural activity to enable transformative understanding of dynamic signaling in the nervous system.  In particular, we seek exceptionally creative approaches to address major challenges associated with recording and manipulating neural activity, at or near cellular resolution, at multiple spatial and/or temporal scales, in any region and throughout the entire depth of the brain. 

Understanding the dynamic activity of neural circuits is central to the NIH BRAIN Initiative.This FOA seeks applications for proof-of-concept testing and development of new technologies and novel approaches for large-scale recording and manipulation of neural activity to enable transformative understanding of dynamic signaling in the nervous system.

The purpose of this Brain Research through Advancing Innovative Neurotechnologies (BRAIN) Initiative is to encourage applications that will develop and validate novel tools to facilitate the detailed analysis of complex circuits and provide insights into cellular interactions that underlie brain function. The new tools and technologies should inform and/or exploit cell-type and/or circuit-level specificity. 

The goal of the Office of Science Graduate Student Research (SCGSR) program is to prepare graduate students for science, technology, engineering, or mathematics (STEM) careers critically important to the DOE Office of Science mission, by providing graduate thesis research opportunities at DOE laboratories.  The SCGSR program provides supplemental awards to outstanding U.S. graduate students to pursue part of their graduate thesis research at a DOE laboratory in areas that address scientific challenges central to the Office of Science mission. The research opportunity is expected to advance the graduate students' overall doctoral thesis while providing access to the expertise, resources, and capabilities available at the DOE laboratories.

The Office of Nuclear Physics (NP), Office of Science (SC), U.S. Department of Energy (DOE), hereby announces its interest in receiving applications for research and development that will allow existing technology candidates to demonstrate down-selection criteria for the next generation of neutrinoless double beta decay measurements.

The Office of Nuclear Physics (NP), Office of Science (SC), U.S. Department of Energy (DOE), hereby announces its interest in receiving applications for research and development that will allow existing technology candidates to demonstrate down-selection criteria for the next generation of neutrinoless double beta decay measurements.

This funding opportunity announcement (FOA) supports high impact efforts to make resources available to neuroscience researchers.  Projects should engage in one or more of the following activities: facilitating access to cutting edge reagents or techniques, dissemination of resources to new user groups, or innovative approaches to increase the scale/efficiency of resource production and delivery.  Applications focused primarily on technology or software development are not responsive to this FOA, as the focus is on dissemination or provision of resources.  Use of existing technologies to develop new reagents or genetic lines of significant value to the research community may be appropriate. Projects should address compelling needs of broad communities of neuroscience researchers or should offer unique services that otherwise would be unavailable.

A central goal of the BRAIN Initiative is to understand how electrical and chemical signals code information in neural circuits and give rise to sensations, thoughts, emotions and actions. While currently available technologies can provide some understanding, they may not be sufficient to accomplish this goal. For example, non-invasive technologies are low resolution and/or provide indirect measures such as blood flow, which are imprecise; invasive technologies can provide information at the level of single neurons producing the fundamental biophysical signals, but they can only be applied to tens or hundreds of neurons, out of a total number in the human brain estimated at 85 billion. Other BRAIN FOAs seek to develop novel technology (RFA-NS-16-006) or to optimize existing technology ready for in-vivo proof-of-concept testing and collection of preliminary data (RFA-NS-16-007) for recording or manipulating neural activity on a scale that is beyond what is currently possible. This FOA seeks applications for unique and innovative technologies that are in an even earlier stage of development than that sought in other FOAs, including new and untested ideas that are in the initial stages of conceptualization.

The purpose of the BRAIN Initiative Fellows (F32) program is to enhance the research training of promising postdoctorates, early in their postdoctoral training period, who have the potential to become productive investigators in research areas that will advance the goals of the BRAIN Initiative. Applications are encouraged in any research area that is aligned with the BRAIN Initiative, including neuroethics. Applicants are expected to propose research training in an area that complements their predoctoral research. Formal training in quantitative perspectives and analytical tools is expected to be an integral part of the proposed research training plan. In order to maximize the training potential of the F32 award, this program encourages applications from individuals who have not yet completed their terminal doctoral degree and who expect to do so within 12 months of the application due date. On the application due date, candidates may not have completed more than 6 months of postdoctoral training.  

Computational neuroscience provides a theoretical foundation and a rich set of technical approaches for understanding complex neurobiological systems, building on the theory, methods, and findings of computer science, neuroscience, and numerous other disciplines. Through the CRCNS program, the National Science Foundation (NSF), the National Institutes of Health (NIH), the German Federal Ministry of Education and Research (Bundesministerium für Bildung und Forschung, BMBF), the French National Research Agency (Agence Nationale de la Recherche, ANR), and the United States-Israel Binational Science Foundation (BSF) support collaborative activities that will advance the understanding of nervous system structure and function, mechanisms underlying nervous system disorders, and computational strategies used by the nervous system. 

The General & Age Related Disabilities Engineering (GARDE) program supports fundamental engineering research that will lead to the development of new technologies, devices, or software that improve the quality of life of persons with disabilities. Research may be supported that is directed toward the characterization, restoration, and/or substitution of human functional ability or cognition, or to the interaction of persons with disabilities and their environment. Areas of particular interest are disability-related research in neuroengineering and rehabilitation robotics. Emphasis is placed on significant advancement of fundamental engineering knowledge that facilitates transformative outcomes. We discourage applications that propose incremental improvements. Applicants are encouraged to contact the Program Director prior to submitting a proposal.

The General & Age Related Disabilities Engineering (GARDE) program supports fundamental engineering research that will lead to the development of new technologies, devices, or software that improve the quality of life of persons with disabilities. Research may be supported that is directed toward the characterization, restoration, and/or substitution of human functional ability or cognition, or to the interaction of persons with disabilities and their environment. Areas of particular interest are disability-related research in neuroengineering and rehabilitation robotics. Emphasis is placed on significant advancement of fundamental engineering knowledge that facilitates transformative outcomes. We discourage applications that propose incremental improvements. Applicants are encouraged to contact the Program Director prior to submitting a proposal.

The purpose of this Funding Opportunity Announcement (FOA) is to invite applications (via limited competition) for SPARC Comprehensive Functional Mapping of Neuroanatomy and Neurobiology of Organs. These projects will comprehensively provide data for developing detailed, predictive functional and anatomical neural circuit maps for neural control of major functions of organs and their functionally-associated structures.