| Literature DB >> 26232230 |
Narayanan Kasthuri1, Kenneth Jeffrey Hayworth2, Daniel Raimund Berger3, Richard Lee Schalek2, José Angel Conchello2, Seymour Knowles-Barley2, Dongil Lee2, Amelio Vázquez-Reina4, Verena Kaynig4, Thouis Raymond Jones5, Mike Roberts4, Josh Lyskowski Morgan2, Juan Carlos Tapia2, H Sebastian Seung6, William Gray Roncal7, Joshua Tzvi Vogelstein8, Randal Burns7, Daniel Lewis Sussman9, Carey Eldin Priebe10, Hanspeter Pfister4, Jeff William Lichtman11.
Abstract
We describe automated technologies to probe the structure of neural tissue at nanometer resolution and use them to generate a saturated reconstruction of a sub-volume of mouse neocortex in which all cellular objects (axons, dendrites, and glia) and many sub-cellular components (synapses, synaptic vesicles, spines, spine apparati, postsynaptic densities, and mitochondria) are rendered and itemized in a database. We explore these data to study physical properties of brain tissue. For example, by tracing the trajectories of all excitatory axons and noting their juxtapositions, both synaptic and non-synaptic, with every dendritic spine we refute the idea that physical proximity is sufficient to predict synaptic connectivity (the so-called Peters' rule). This online minable database provides general access to the intrinsic complexity of the neocortex and enables further data-driven inquiries.Entities:
Mesh:
Year: 2015 PMID: 26232230 DOI: 10.1016/j.cell.2015.06.054
Source DB: PubMed Journal: Cell ISSN: 0092-8674 Impact factor: 41.582