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wo classes of proposals will be considered in response to this solicitation: Research Proposals describing collaborative research projects, and Data Sharing Proposals to enable sharing of data and other resources. Domestic and international projects will be considered. As detailed in the solicitation, international components of collaborative projects may be funded in parallel by the participating agencies. Specific CRCNS opportunities for parallel funding are available for bilateral US-German Research Proposals, US-German Data Sharing Proposals, US-French Research Proposals, US-French Data Sharing Proposals, US-Israeli Research Proposals, US-Israeli Data Sharing Proposals, US-Japanese Research Proposals, US-Japanese Data Sharing Proposals, US-Spanish Research Proposals, US-Spanish Data Sharing Proposals, and multilateral proposals involving the United States and two or more CRCNS partner countries (please see Section VIII of the solicitation for country-specific instructions and limitations).

Despite significant scientific advancements made in substance use disorder research over the last century, the causes and consequences of drug use in later life remain poorly understood. The intent of this funding opportunity announcement is to support innovative research that examines aspects of marijuana and prescription opioid and benzodiazepine use in adults aged 50 and older. This FOA encourages research that examines the determinants of these types of drug use and/or characterizes the resulting neurobiological alterations, associated behaviors, and public health consequences. This initiative will focus on two distinct populations of older adults: individuals with earlier onset of drug use who are now entering this stage of adult development or individuals who initiate drug use after the age of 50. Applications are encouraged to utilize broad methodologies ranging from basic science, clinical, and epidemiological approaches. The insights gleaned from this initiative are critical to our understanding of the determinants of drug use in later life, as well as its consequences in the aging brain and on behavior. This knowledge may have the potential to identify risk factors and to guide clinical practices in older populations.

The National Institute on Aging is seeking applications on systems biology approaches using non-mammalian laboratory animal models to increase our understanding of the basic biology underpinning neurodegeneration. It is expected that research supported under this FOA will provide new insights into molecular networks that might be involved in causing, amplifying or protecting against neurodegeneration, and that, in turn, might ultimately contribute to Alzheimer's disease or related dementias. Importantly, a major goal of this FOA is to use interaction and regulatory networks produced and analyzed using systems biology to gain these new insights. Because this FOA is directed toward discovery, currently employed genetically modified laboratory animals used to study AD are not required, although they may be used. Because this FOA requires systems biology approaches, data used to build interaction or regulatory networks may also come from humans or other mammals in which AD, related dementias, or aging-related cognitive decline have been observed. This FOA will only support studies using non-mammalian laboratory animal models; studies involving humans or experiments with mammals will not be allowed under this FOA.

The National Institute on Aging is seeking applications on systems biology approaches using non-mammalian laboratory animal models to increase our understanding of the basic biology underpinning neurodegeneration. It is expected that research supported under this FOA will provide new insights into molecular networks that might be involved in causing, amplifying or protecting against neurodegeneration, and that, in turn, might ultimately contribute to Alzheimer's disease or related dementias. Importantly, a major goal of this FOA is to use interaction and regulatory networks produced and analyzed using systems biology to gain these new insights. Because this FOA is directed toward discovery, currently employed genetically modified laboratory animals used to study AD are not required, although they may be used. Because this FOA requires systems biology approaches, data used to build interaction or regulatory networks may also come from humans or other mammals in which AD, related dementias, or aging-related cognitive decline have been observed. This FOA will only support studies using non-mammalian laboratory animal models; studies involving humans or experiments with mammals will not be allowed under this FOA.

Long-term misuse and chronic exposure to abused substances can produce widespread changes in brain structure and function. Although much progress has been made, additional research is still needed to identify the neurobiological changes that result from substance use, and how these changes contribute to substance use disorders. The overarching goals of the research areas described in this FOA are to understand the neurobiological mechanisms underlying substance use disorders, with special emphasis on identifying changes and neuroadaptations that occur during dependence, withdrawal, and relapse to chronic substance use. An understanding of the basic mechanisms underlying substance use disorders can help to identify targets for prevention and treatment interventions. Research utilizing basic, translational, or clinical approaches is appropriate.

Long-term misuse and chronic exposure to abused substances can produce widespread changes in brain structure and function. Although much progress has been made, additional research is still needed to identify the neurobiological changes that result from substance use, and how these changes contribute to substance use disorders. The overarching goals of the research areas described in this FOA are to understand the neurobiological mechanisms underlying substance use disorders, with special emphasis on identifying changes and neuroadaptations that occur during dependence, withdrawal, and relapse to chronic substance use. An understanding of the basic mechanisms underlying substance use disorders can help to identify targets for prevention and treatment interventions. Research utilizing basic, translational, or clinical approaches is appropriate.

The purpose of this Funding Opportunity Announcement (FOA) is to support intramural-extramural collaborations to develop and implement the use of 3D biofabricated tissue models as novel drug screening platforms and advance pre-clinical discovery and development of non-addictive treatments for nociception, opioid use disorder (OUD) and/or overdose. In particular, support during the UH2 phase is for the application of 3D biofabrication technologies to develop novel multicellular tissue constructs for drug screening by using human iPSC-derived cells representing sensory/pain neurons, brain regions, and other tissues involved in nociception, addiction and/or overdose, including tissue models of the blood-brain barrier (BBB). Support during the UH3 is for implementation of drug screens using the 3D tissue models developed during the UH2 phase. Please limit this field to a brief description of to page in length. Brevity is appreciated. This FOA is part of the of the NIHs Helping to End Addiction Long-term (HEAL) initiative to speed scientific solutions to the national opioid public health crisis. The NIH HEAL Initiative will bolster research across NIH to (1) improve treatment for opioid misuse and addiction and (2) enhance pain management. More information about the HEAL Initiative is available at: https://www.nih.gov/research-training/medical-research-initiatives/heal-initiative

The purpose of this Funding Opportunity Announcement (FOA) is to invite applications proposing the innovative analysis of existing social science, behavioral, administrative, and neuroimaging data to study the etiology and epidemiology of drug using behaviors (defined as alcohol, tobacco, prescription and other drug) and related disorders, prevention of drug use and HIV, and health service utilization. This FOA encourages the analyses of public use and other extant community-based or clinical datasets to their full potential in order to increase our knowledge of etiology, trajectories of drug using behaviors and their consequences including morbidity and mortality, risk and resilience in the development of psychopathology, strategies to guide the development, testing, implementation, and delivery of high quality, effective and efficient services for the prevention and treatment of drug abuse and HIV.

Repeated exposure to drugs of abuse can cause changes in neuronal structure and function that contribute to and sustain drug use. Research has largely focused on the interactions of drugs with specific neuronal targets, and on the consequences of drug exposure on neuronal function, excitability, neuroplasticity, and neurochemistry. However, emerging evidence shows that neuroimmune factors, released from both glia or neurons, can modulate neuronal structure and function, either by affecting neuron-glia interactions or through direct effects on neurons. Yet the role of neuroimmune signaling in the modulation of neuronal function as it affects the expression of substance use behaviors is poorly understood. Research has shown that drugs of abuse, including methamphetamine, morphine, cocaine and nicotine, can elicit neuroinflammatory responses. Stress, an important contributor to relapse, can also elicit neuroimmune responses. Consequently, neuroimmune signaling may be integral to mechanisms underlying drug misuse, addiction, and other consequences of repeated drug use. Further, because the molecular targets and receptors for abused substances differ, the complement of neuroimmune factors affected by exposure to a particular drug may be drug-specific. Research to identify the commonalities between specific drugs of abuse, the neuroimmune factors released by drug use, and the neuroanatomical specificity of the responses is needed. It is expected that the contributing actions of neuroimmune signaling to addictive behaviors are most likely due not to obvious brain damage and overt pathology, but to the consequences of such signaling in altering specific molecular and cellular processes within glia, neurons, and neural circuits.

The purpose of this Funding Opportunity Announcement (FOA) is to invite applications proposing the innovative analysis of existing social science, behavioral, administrative, and neuroimaging data to study the etiology and epidemiology of drug using behaviors (defined as alcohol, tobacco, prescription and other drug) and related disorders, prevention of drug use and HIV, and health service utilization. This FOA encourages the analyses of public use and other extant community-based or clinical datasets to their full potential in order to increase our knowledge of etiology, trajectories of drug using behaviors and their consequences including morbidity and mortality, risk and resilience in the development of psychopathology, strategies to guide the development, testing, implementation, and delivery of high quality, effective and efficient services for the prevention and treatment of drug abuse and HIV.

The Collaborative Research on Addiction at the NIH (CRAN) - composed of the National Institute on Drug Abuse (NIDA), the National Institute on Alcohol Abuse and Alcoholism (NIAAA), the National Cancer Institute (NCI), and - along with the Eunice Kennedy Shriver Institute of Child Health and Human Development (NICHD), the National Institute of Mental Health (NIMH), the National Institute on Minority Health and Health Disparities (NIMHD), and the Office of Behavioral and Social Sciences Research (OBSSR) intend to jointly fund the Adolescent Brain Cognitive Development (ABCD) Study Consortium using the cooperative agreement award mechanism.  The objective of the consortium is to establish a national, multisite, longitudinal cohort study to prospectively examine the neurodevelopmental and behavioral effects of substance use from early adolescence (approximately age 9-10) through the period of risk for substance use and substance use disorders.

This Notice supersedes NOT-OD-15-024 about the NIH and AHRQ requirement for use of a new biosketch format and provides some latitude in the transition for those who have already been compiling biosketches for their large grant applications with deadlines in early in 2015. NIH and AHRQ encourages applicants to use the newly published biosketch format for all grant and cooperative agreement applications submitted for due dates on or after January 25, 2015, and will require use of the new format for applications submitted for due dates on or after May 25, 2015. Applicants may submit using the new biosketch format for due dates before January 25, 2015, if they wish.

This Funding Opportunity Announcement (FOA) uses a R61/R33 Phased Innovation Award mechanism to support clinical research applications that are exploratory and developmental in nature and focus on understanding the neurobiological mechanisms underlying Substance Use Disorders (SUD), including fundamental brain function relevant to substance use.

A rich body of evidence suggests that cognitive processes are associated with particular patterns of neural activity. These data indicate that oscillatory rhythms, their co-modulation across frequency bands, spike-phase correlations, spike population dynamics, and other patterns might be useful drivers of therapeutic development for cognitive improvement in neuropsychiatric disorders. This initiative encourages applications to test whether modifying electrophysiological patterns during behavior can improve cognitive abilities. Applications should use experimental designs that incorporate active manipulations to address at least one, and ideally more, of the following topics: (1) in behaving animals, determine which parameters of neural coordination, when manipulated in isolation, improve particular aspects of cognition; (2) in animals or humans, determine how particular abnormalities at the cellular or molecular level, such as specific receptor dysfunction, affect the coordination of electrophysiological patterns during behavior; (3) determine whether in vivo, systems-level electrophysiological changes in behaving animals predict analogous electrophysiological and cognitive improvements in normal humans or clinical populations; and (4) use systems-level computational modeling to develop a principled understanding of the function and mechanisms by which oscillatory and other electrophysiological temporal dynamic patterns unfold across the brain (cortically and subcortically) to impact cognition.

A rich body of evidence suggests that cognitive processes are associated with particular patterns of neural activity. These data indicate that oscillatory rhythms, their co-modulation across frequency bands, spike-phase correlations, spike population dynamics, and other patterns might be useful drivers of therapeutic development for cognitive improvement in neuropsychiatric disorders. This initiative encourages applications to test whether modifying electrophysiological patterns during behavior can improve cognitive abilities. Applications should use experimental designs that incorporate active manipulations to address at least one, and ideally more, of the following topics: (1) in behaving animals, determine which parameters of neural coordination, when manipulated in isolation, improve particular aspects of cognition; (2) in animals or humans, determine how particular abnormalities at the cellular or molecular level, such as specific receptor dysfunction, affect the coordination of electrophysiological patterns during behavior; (3) determine whether in vivo, systems-level electrophysiological changes in behaving animals predict analogous electrophysiological and cognitive improvements in normal humans or clinical populations; and (4) use systems-level computational modeling to develop a principled understanding of the function and mechanisms by which oscillatory and other electrophysiological temporal dynamic patterns unfold across the brain (cortically and subcortically) to impact cognition.

A rich body of evidence suggests that cognitive processes are associated with particular patterns of neural activity. These data indicate that oscillatory rhythms, their co-modulation across frequency bands, spike-phase correlations, spike population dynamics, and other patterns might be useful drivers of therapeutic development for cognitive improvement in neuropsychiatric disorders.  This initiative encourages applications to test whether modifying electrophysiological patterns during behavior can improve cognitive abilities.  Applications should use experimental designs that incorporate active manipulations to address at least one, and ideally more, of the following topics: (1) in behaving animals, determine which parameters of neural coordination, when manipulated in isolation, improve particular aspects of cognition;  (2) in animals or humans, determine how particular abnormalities at the cellular or molecular level, such as specific receptor dysfunction, affect the coordination of electrophysiological patterns during behavior;  (3) determine whether in vivo, systems-level electrophysiological changes in behaving animals predict analogous electrophysiological and cognitive improvements in normal humans or clinical populations; and (4) use systems-level computational modeling to develop a principled understanding of the function and mechanisms by which oscillatory and other electrophysiological temporal dynamic patterns unfold across the brain (cortically and subcortically) to impact cognition.

A rich body of evidence suggests that cognitive processes are associated with particular patterns of neural activity. These data indicate that oscillatory rhythms, their co-modulation across frequency bands, spike-phase correlations, spike population dynamics, and other patterns might be useful drivers of therapeutic development for cognitive improvement in neuropsychiatric disorders.  This initiative encourages applications to test whether modifying electrophysiological patterns during behavior can improve cognitive abilities.  Applications should use experimental designs that incorporate active manipulations to address at least one, and ideally more, of the following topics: (1) in behaving animals, determine which parameters of neural coordination, when manipulated in isolation, improve particular aspects of cognition;  (2) in animals or humans, determine how particular abnormalities at the cellular or molecular level, such as specific receptor dysfunction, affect the coordination of electrophysiological patterns during behavior;  (3) determine whether in vivo, systems-level electrophysiological changes in behaving animals predict analogous electrophysiological and cognitive improvements in normal humans or clinical populations; and (4) use systems-level computational modeling to develop a principled understanding of the function and mechanisms by which oscillatory and other electrophysiological temporal dynamic patterns unfold across the brain (cortically and subcortically) to impact cognition.   

This Funding Opportunity Announcement (FOA) intends to accelerate the integration and use of scalable technologies and tools to enhance and reinvigorate brain cell census research, including the development of technology platforms and/or resources that will enable a swift and comprehensive survey of brain cell types and circuits. Of particular interest are those that will (a) improve technology and resource platforms to remove limitations and bottlenecks in the current pipeline of brain cell census data generation; (b) integrate experimental and computational methods to enhance capabilities of cell census data generation and analysis and to reduce barriers to hypothesis-driven research; (c) generate a substantial amount of spatiotemporal cell census data and/or resources to demonstrate the utility of the improved technology and resource platforms; and (d) conduct comparative studies by using proper criteria to evaluate and benchmark quality of biospecimen, performance of cell census tools/technologies, and effectiveness of computational approaches. The projects funded under this FOA will align with the overarching goals of the BRAIN Initiative Cell Census Network (BICCN) and are expected to generate a substantial amount of cell census data using the proposed technologies or via collaboration with the BICCN.

This Funding Opportunity Announcement (FOA) encourages exploratory/developmental research grant applications, proposing the development of innovative, collaborative research projects on brain and other nervous system function and disorders throughout life, relevant to low- and middle-income countries (LMICs). Research on neurological, mental, behavioral, alcohol and substance use disorders may span the full range of science from basic to implementation research. Scientists in the United States (U.S.) or upper-middle income countries (UMICs) are eligible to partner with scientists in LMIC institutions. Scientists in upper middle-income LMICs (UMICs) are also eligible to partner directly with scientists at other LMIC institutions with or without out a US partner. Income categories used are as defined by the World Bank at http://data.worldbank.org/about/country-classifications/country-and-lending-groups.

This Funding Opportunity Announcement (FOA) encourages exploratory/developmental research grant applications, proposing the development of innovative, collaborative research projects on brain and other nervous system function and disorders throughout life, relevant to low- and middle-income countries (LMICs). Research on neurological, mental, behavioral, alcohol and substance use disorders may span the full range of science from basic to implementation research. Scientists in the United States (U.S.) or upper-middle income countries (UMICs) are eligible to partner with scientists in LMIC institutions. Scientists in upper middle-income LMICs (UMICs) are also eligible to partner directly with scientists at other LMIC institutions with or without out a US partner. Income categories used are as defined by the World Bank at http://data.worldbank.org/about/country-classifications/country-and-lending-groups. These grants are expected to foster the development of more comprehensive research programs that contribute to the long-term goals of building sustainable research capacity in LMICs to address nervous system development, function and impairment throughout life and to lead to diagnostics, prevention, treatment and implementation strategies. The proposed work may also contribute to developing a base for research networking and evidence-based policy beyond the specific research project.