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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.

Studies funded by our Basic Research RFP will fall into one the following key areas, which are listed in random order: 1. Studies focused on the molecular and biochemical mechanisms regulating SMN expression or mediating SMN function. Results should lead to a better understanding of the requirements for SMN protein biologically, informing therapy development. Such studies may also identify genetic modifiers, upstream regulators of SMN expression / splicing / function, and downstream effectors of SMN functional activity, resulting in novel drug targets.      2.  Studies resulting in greater understanding of the pathophysiology of SMA, using well-validated animal or cellular models of the SMA. This includes focus on the tissue requirements for SMN protein, clarifying the cellular autonomy of the disease in motor neurons and other cells, peripheral versus central manifestations of the disease, and other areas.  3. Early proof-of concept assessment of novel therapeutic approaches for SMA in well-validated animal or cellular models of the disease. 4. Work focused on generating research and clinical trial tools, such as new animal models for SMA, phenotypic cellular assays for SMA, biomarkers or outcome measures for SMA clinical trials, newborn screening protocols, and others.

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.   

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. Available technologies for recording and manipulating neural circuit activity in human and animal experiments are not sufficient to accomplish this goal. 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. Previous BRAIN FOAs sought to develop novel technology (RFA-NS-15-003) or to optimize existing technology ready for in-vivo proof-of-concept testing and collection of preliminary data (RFA-NS-15-004). This FOA seeks applications for technology at an even earlier stage of development. It seeks new and untested ideas that are in the very earliest stages. The support provided might enable calculations, simulations, computational models, or other mathematical approaches for demonstrating that the signal sources and/or measurement technologies are theoretically capable of meeting the demands of large-scale recording or manipulation of circuit activity. The support might also be used for building and testing phantoms, prototypes, in-vitro or other bench-top models in order to validate underlying theoretical assumptions in preparation for future FOAs aimed at testing in animal models. Invasive or non-invasive approaches are sought that will ultimately enable or reduce the current barriers to large-scale recording or manipulation of neural activity, and that would be compatible with experiments in humans or behaving animals. Applications are encouraged from any qualified individuals, including physicists, engineers, theoreticians, and scientists, especially those no

This funding opportunity supports projects that test whether modifying electrophysiological patterns during behavior can improve cognitive, affective, or social processing. Applications must use experimental designs that incorporate active manipulations to address at least one, and ideally more, of the following topics: (1) in animals or humans, determine which parameters of neural coordination, when manipulated in isolation, improve particular aspects of cognitive, affective, or social processing; (2) in animals or humans, determine how particular abnormalities at the genomic, molecular, or cellular levels affect the systems-level 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 healthy persons or clinical populations; and (4) use biologically-realistic computational models that include systems-level aspects to understand the function and mechanisms by which oscillatory and other electrophysiological patterns unfold across the brain to impact cognitive, affective, or social processing.

The National Institute on Aging is seeking applications to develop systems biology approaches to understand the basic biology underpinning neurodegeneration which might ultimately contribute to Alzheimer's disease or related dementias, using non-mammalian laboratory animal models. It is expected that research carried under the auspices of this FOA will lead to discovery of new mechanisms that provoke neurodegeneration and to new molecular pathways that might be involved in causing, amplifying or protecting against neurodegeneration. Applications should propose to use established non-mammalian laboratory animals which have a history of contributions to our understanding of neurobiology or aging biology.  

This funding opportunity announcement (FOA) issued by ORIP, National Institutes of Health, encourages research grant applications from institutions/organizations that propose to develop, characterize or improve animal models for human disease or to improve diagnosis and control of diseases that might interfere with animal use for biomedical research purposes.

The Klarman Family Foundation is interested in providing strategic investment in translational research that will accelerate progress in developing effective treatments for anorexia nervosa, bulimia nervosa and binge eating disorder. The Program's short-term goal is to support the most outstanding science and expand the pool of scientists whose research explores the basic biology of feeding, anorexia nervosa, bulimia nervosa, and/or binge eating disorder. The long-term goal is to improve the lives of patients suffering from these conditions. Examples of funding areas include but are not limited to molecular genetic analysis of relevant neural circuit assembly and function; genetic and epigenetic research; animal models created by genetically altering neural circuits; and testing of new chemical entities that might be used in animal models as exploratory treatments.  Please note that imaging studies involving humans are not eligible. Investigators conducting research in the neuro-circuitry of fear conditioning or reward behavior may also apply but must justify the relevance of their research projects to the basic biology of eating disorders. Clinical psychotherapeutic studies, medication trials and research in the medical complications of these disorders are outside the scope of this Program.

The overall goal of this initiative is to identify, optimize, and evaluate measures of neurophysiological processes that are disrupted within or across mental disorders and which can be assessed in animals and humans. The goal is to support further development of these measures as assays for evaluating potential new drug and device therapies and their targets. Data will also reveal assay measures where the performance between preclinical species and humans is dissimilar, thus establishing a firm basis for limiting speculative extrapolations of preclinical findings. Ultimately, the goal of this FOA is to improve the efficiency of the therapeutic development process by addressing inconsistencies between the preclinical screening pipeline and clinical evaluation of new treatment candidates and thereby hasten the development of more effective treatments for mental disorders. The objectives of the FOA will be accomplished by supporting partnerships among basic and translational neuroscientists who are committed to advancing the discovery of physiological measures as tools for target validation and therapeutic development. Groups will be tasked with building a target-engagement-linked-to-functional-brain-effect suite of assays with potential to translate from animals to humans and thus serve as a basis for selecting preclinical treatment candidates for further development and clinical testing. Towards this goal, the FOA will support development, optimization and evaluation of brain based assays in both preclinical species and in healthy humans and the evaluation of assay performance in response to carefully selected chemical, physiological, or behavioral manipulations.

The overall goal of this Funding Opportunity Announcement (FOA) is to identify, in animals, in vivo neurophysiological and behavioral measures for use as assays in the early screening phase of treatment development. The FOA will support efforts to optimize and evaluate measures of neurophysiological and behavioral processes that may serve as surrogate markers of neural processes of clinical interest based on available knowledge of the neurobiology of mental illnesses. The screening assays thus developed from this FOA are expected to build upon systems neurobiology and clinical neuroscience to enhance the scientific value of preclinical animal data contributing to a therapeutic development pipeline by assessing the impact of therapeutic targets and treatment candidates on neurobiological mechanisms of clinical relevance to mental illnesses.

This funding opportunity announcement (FOA) supports the development of PET radioligands that identify proteinopathies or pathological processes associated with the human biology of Alzheimer's disease related dementias (ADRDs). Activities supported under this FOA include, but are not limited to the in vitro screening of existing ligands against human ADRD brain tissue, medicinal chemistry support for development of new compounds and improvement of existing ligand specificity and selectivity, initial screening of ligands in appropriate animal models, and radioligand formulation and first-in-human testing. The Center without Walls should encompass research that will move promising ligands through in vitro and in vivo optimization to first-in-human studies. Applications must include an administrative core, a medicinal chemistry core, a clinical core, a scientific governance structure, and a minimum of two research projects with milestone plans that address workflows for screening of existing and newly derived ligands against human ADRD tissue and appropriate animal models. Synergy must be evident among Center research projects and cores, such that successful completion of the aims could not be accomplished without the Center structure. This FOA is in response to the Alzheimer's Disease Related Dementias (ADRD) challenges outlined in the 2016 update to the National Plan to Address Alzheimer's Disease.

This funding opportunity announcement (FOA) encourages the development and validation of: 1) animal models and human tissue ex vivo systems that recapitulate the phenotypic and physiologic characteristics of a defined neurological disorder and/or 2) clinically feasible pharmacodynamic markers for therapeutics designed to treat neurological disease. The goal of this FOA is to promote a significant improvement in the translational relevance of animal models, ex vivo systems, and pharmacodynamic markers that will be utilized to facilitate the development of neurotherapeutics. Ideally, models, model systems and pharmacodynamic markers proposed in applications for this FOA would have the potential to provide feasible and meaningful assessments of efficacy following therapeutic intervention that would be applicable in both preclinical and clinical settings. This FOA is part of a suite of Innovation Grants to Nurture Initial Translational Efforts (IGNITE) focused on enabling the exploratory and early stages of drug discovery.

This funding opportunity announcement (FOA) supports the development of PET radioligands that identify proteinopathies or pathological processes associated with the human biology of Alzheimer's disease related dementias (ADRDs). Activities supported under this FOA include, but are not limited to the in vitro screening of existing ligands against human ADRD brain tissue, medicinal chemistry support for development of new compounds and improvement of existing ligand specificity and selectivity, initial screening of ligands in appropriate animal models, and radioligand formulation and first-in-human testing. The Center without Walls should encompass research that will move promising ligands through in vitro and in vivo optimization to first-in-human studies. Applications must include an administrative core, a medicinal chemistry core, a clinical core, a scientific governance structure, and a minimum of two research projects with milestone plans that address workflows for screening of existing and newly derived ligands against human ADRD tissue and appropriate animal models. Synergy must be evident among Center research projects and cores, such that successful completion of the aims could not be accomplished without the Center structure.

This funding opportunity announcement(FOA) supports the development of PET radioligands that identify proteinopathies or pathological processes associated with the human biology of Alzheimer's disease related dementias (ADRDs). Activities supported under this FOA include, but are not limited to the in vitro screening of existing ligands against human ADRD brain tissue, medicinal chemistry support for improvement of ligand specificity and selectivity, initial screening of ligands in appropriated animal models, and radioligand formulation and first-in-human testing. Applications must include an administrative core, a medicinal chemistry core, a clincial core, a scientific governance structure, and a minimum of two research projects with milestone plans that address workflows for screening of existing and newly derived ligands against human ADRD tissue and appropriate animal models. Synergy must be evident among Center research projects and cores, such that successful completion of the aims could not be accomplished without the Center structure. This FOA is in response to the Alzheimer's Disease Related Dementias (ADRD) challenges outlined in the 2016 update to the National Plan to Address Alzheimer's Disease.

This Funding Opportunity Announcement (FOA) encourages applications to develop valid markers to assess the activity of fundamental aging mechanisms in humans that may influence the risk and progression of multiple aging conditions. Projects are encouraged that focus on selected mechanism(s) that may regulate aging changes, assess multiple possible markers for these mechanisms, test methods to improve their measurement properties, characterize their variability among individuals of differing ages and within the same age cohort, and assess their relationships in humans to in vivo functions influenced by the mechanism(s) under study. It is strongly encouraged that each project includes an interdisciplinary research team with expertise, as needed, in the biology of their selected mechanism(s), biomedical aging research, clinical pathology including laboratory assays, imaging methods, human cohort studies, tissue banking, biorepository resources, and statistics. Though the principal focus of the initiative is on development of markers in humans, studies in laboratory animals may also be conducted when necessary for the development of human markers, and potential development of parallel laboratory animal markers of a given mechanism.

The International Foundation for Ethical Research (IFER) is pleased to call for pre-proposal applications for its 2013 Graduate Student Fellowships for Alternatives to the Use of Animals in Science. The fellowships provide up to $12,500 annually in stipendiary support and up to $2,500 for supplies per year. The fellowships are renewable annually for up to three years. Continued funding is dependent on student progress and availability of funds.