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. We will combine the complementary strengths of three innovative microscopy techniques.
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.
This Funding Opportunity Announcement (FOA) supports Specialized Projects to develop current or emerging technologies to generate comprehensive atlases of brain connectivity, with an emphasis on human, non-human primate (NHP), and mouse. Projects validating approaches using other species are also permitted if well justified. Applications may address any aspects of the data collection, analysis, and dissemination pipelines, to enable faster and more cost-effective generation and interpretation of brain-wide wiring diagrams.
This Funding Opportunity Announcement (FOA) supports Comprehensive Centers to develop and test technologies that can be scaled to brain-wide atlases of mouse circuit connectivity. Centers will establish data collection, analysis, and dissemination pipelines to demonstrate the feasibility of mapping cell-to-cell connectivity with a minimum resolution of synaptic connections. They will demonstrate the significance of the approach within the context of a chosen CNS sub-volume, by testing specific hypotheses relating circuit structure to function.
This Funding Opportunity Announcement (FOA) supports Comprehensive Centers to develop and test technologies that can be scaled to brain-wide atlases of human and non-human primate circuit connectivity. Centers will establish data collection, analysis, and dissemination pipelines to demonstrate the feasibility of mapping region-to-region connectivity with a minimum resolution of individual cells and/or axon fibers. They will demonstrate the significance of the approach within the context of a chosen CNS sub-volume, by testing specific hypotheses relating circuit structure to function.
