论文信息 - A petascale automated imaging pipeline for mapping neuronal circuits with high-throughput transmission electron microscopy - 字舞流文

A petascale automated imaging pipeline for mapping neuronal circuits with high-throughput transmission electron microscopy

Serial-section electron microscopy is the method of choice for studying cellular structure and network connectivity in the brain. We have built a pipeline of parallel imaging using transmission electron automated microscopes (piTEAM) that scales this technology and enables the acquisition of petascale datasets containing local cortical microcircuits. The distributed platform is composed of multiple transmission electron microscopes that image, in parallel, different sections from the same block of tissue, all under control of a custom acquisition software (pyTEM) that implements 24/7 continuous autonomous imaging. The suitability of this architecture for large scale electron microscopy imaging was demonstrated by acquiring a volume of more than 1 mm3 of mouse neocortex spanning four different visual areas. Over 26,500 ultrathin tissue sections were imaged, yielding a dataset of more than 2 petabytes. Our current burst imaging rate is 500 Mpixel/s (image capture only) per microscope and net imaging rate is 100 Mpixel/s (including stage movement, image capture, quality control, and post processing). This brings the combined burst acquisition rate of the pipeline to 3 Gpixel/s and the net rate to 600 Mpixel/s with six microscopes running acquisition in parallel, which allowed imaging a cubic millimeter of mouse visual cortex at synaptic resolution in less than 6 months.

Wenjing Yin | Derrick Brittain | Jay Borseth | Derric Williams | Daniel Kapner | Adam Bleckert | Daniel Castelli | David Reid | Wei-Chung Allen Lee | Colin Farrell | Nuno Macarico da Costa | Brett J. Graham | R. Clay Reid | Jed Perkins | Marc Takeno | Marie E. Scott | Chris Own | Matt Murfitt | Russel M. Torres | Dan J. Bumbarger | R. Reid | W. Lee | Adam A. Bleckert | Marc M. Takeno | N. D. da Costa | Derric Williams | Jed Perkins | C. Farrell | D. Kapner | David Reid | M. Murfitt | C. Own | D. Castelli | D. Brittain | D. Bumbarger | R. Torres | W. Yin | J. Borseth | Dan Castelli | Colin Farrell

[1] W. Denk,et al. Serial Block-Face Scanning Electron Microscopy to Reconstruct Three-Dimensional Tissue Nanostructure , 2004, PLoS biology.

[2] Daniel J. Uhlrich,et al. Synaptic connectivity of a local circuit neurone in lateral geniculate nucleus of the cat , 1985, Nature.

[3] David Grant Colburn Hildebrand,et al. Imaging ATUM ultrathin section libraries with WaferMapper: a multi-scale approach to EM reconstruction of neural circuits , 2014, Front. Neural Circuits.

[4] Eric T. Trautman,et al. A Complete Electron Microscopy Volume of the Brain of Adult Drosophila melanogaster , 2017, Cell.

[5] A. L. Eberle,et al. High-resolution, high-throughput imaging with a multibeam scanning electron microscope , 2015, Journal of microscopy.

[6] R. Sommer,et al. System-wide Rewiring Underlies Behavioral Differences in Predatory and Bacterial-Feeding Nematodes , 2013, Cell.

[7] M. Helmstaedter,et al. Axonal synapse sorting in medial entorhinal cortex , 2017, Nature.

[8] Brett J. Graham,et al. Anatomy and function of an excitatory network in the visual cortex , 2016, Nature.

[9] M. Helmstaedter,et al. Large-volume en-bloc staining for electron microscopy-based connectomics , 2015, Nature Communications.

[10] William F Tobin,et al. Wiring variations that enable and constrain neural computation in a sensory microcircuit , 2017, bioRxiv.

[11] Anna Lena Eberle,et al. Multi-Beam Scanning Electron Microscopy for High-Throughput Imaging in Connectomics Research , 2018, Front. Neuroanat..

[12] Wei-Chung Allen Lee,et al. High-throughput transmission electron microscopy with automated serial sectioning , 2019, bioRxiv.

[13] Arthur W. Wetzel,et al. Network anatomy and in vivo physiology of visual cortical neurons , 2011, Nature.

[14] E. G. Gray,et al. Electron Microscopy of Synaptic Contacts on Dendrite Spines of the Cerebral Cortex , 1959, Nature.

[15] Kevin L. Briggman,et al. Wiring specificity in the direction-selectivity circuit of the retina , 2011, Nature.

[16] Alexandro D. Ramirez,et al. Electron Microscopic Reconstruction of Functionally Identified Cells in a Neural Integrator , 2017, Current Biology.

[17] Srinivas C. Turaga,et al. Connectomic reconstruction of the inner plexiform layer in the mouse retina , 2013, Nature.

[18] S. Brenner,et al. The structure of the nervous system of the nematode Caenorhabditis elegans. , 1986, Philosophical transactions of the Royal Society of London. Series B, Biological sciences.

[19] G. Knott,et al. Ultrastructurally-smooth thick partitioning and volume stitching for larger-scale connectomics , 2015, Nature Methods.

[20] Winfried Denk,et al. EM connectomics reveals axonal target variation in a sequence-generating network , 2017, eLife.

[21] Won-Ki Jeong,et al. Whole-brain serial-section electron microscopy in larval zebrafish , 2017, Nature.

[22] Travis A. Jarrell,et al. The Connectome of a Decision-Making Neural Network , 2012, Science.

[23] Louis K. Scheffer,et al. A visual motion detection circuit suggested by Drosophila connectomics , 2013, Nature.

[24] Louis K. Scheffer,et al. Synaptic circuits and their variations within different columns in the visual system of Drosophila , 2015, Proceedings of the National Academy of Sciences.

[25] F. S. Sjostrand. Ultrastructure of retinal rod synapses of the guinea pig eye as revealed by three-dimensional reconstructions from serial sections. , 1958, Journal of ultrastructure research.

[26] K. Hayworth,et al. Enhanced FIB-SEM systems for large-volume 3D imaging , 2017, eLife.

[27] Daniel R. Berger,et al. The Fuzzy Logic of Network Connectivity in Mouse Visual Thalamus , 2016, Cell.