Your search keyword '"Michał Januszewski"' showing total 11 results

1. Gas cluster ion beam SEM for imaging of large tissue samples with 10 nm isotropic resolution

Author

Graham Knott, Michał Januszewski, Zhiyuan Lu, Kenneth J. Hayworth, David Peale, Harald F. Hess, and C. Shan Xu

Subjects

0303 health sciences, Materials science, Gas cluster ion beam, business.industry, Scanning electron microscope, Physics::Medical Physics, Resolution (electron density), Cell Biology, Electron, Biochemistry, Focused ion beam, law.invention, Condensed Matter::Materials Science, 03 medical and health sciences, Optics, law, Microscopy, Electron microscope, Ion milling machine, business, Molecular Biology, 030304 developmental biology, Biotechnology

Abstract

We demonstrate gas cluster ion beam scanning electron microscopy (SEM), in which wide-area ion milling is performed on a series of thick tissue sections. This three-dimensional electron microscopy technique acquires datasets with

Published

2019

2. Denoising-based Image Compression for Connectomics

Author

David Minnen, Michał Januszewski, Tim Blakely, Alexander Shapson-Coe, Richard L. Schalek, Johannes Ballé, Jeff W. Lichtman, and Viren Jain

Subjects

Connectomics, business.industry, Computer science, Noise reduction, Microscopy, Resolution (electron density), Codec, Petabyte, Computer vision, Artificial intelligence, business, Image (mathematics), Image compression

Abstract

Connectomic reconstruction of neural circuits relies on nanometer resolution microscopy which produces on the order of a petabyte of imagery for each cubic millimeter of brain tissue. The cost of storing such data is a significant barrier to broadening the use of connectomic approaches and scaling to even larger volumes. We present an image compression approach that uses machine learning-based denoising and standard image codecs to compress raw electron microscopy imagery of neuropil up to 17-fold with negligible loss of 3d reconstruction and synaptic detection accuracy.

Published

2021

3. Automated Reconstruction of a Serial-Section EM Drosophila Brain With Flood-Filling Networks and Local Realignment

Author

Davi D. Bock, Laramie Leavitt, Eric Perlman, István Taisz, Feng Li, Larry Lindsey, Michał Januszewski, Peter H. Li, Jeremy Maitin-Shepard, Gregory S.X.E. Jefferis, Alexander Shakeel Bates, Michael D. Tyka, Matthew Nichols, Viren Jain, Zhihao Zheng, and Tim Blakely

Subjects

business.industry, Computer science, Key (cryptography), Volume (computing), Pairwise sequence alignment, Image content, Segmentation, Computer vision, Serial section, Artificial intelligence, Tracing, business, Skeletonization

Abstract

Reconstruction of neural circuitry at single-synapse resolution is a key target for improving understanding of the nervous system in health and disease. Serial section transmission electron microscopy (ssTEM) is among the most prolific imaging methods employed in pursuit of such reconstructions. We demonstrate how Flood-Filling Networks (FFNs) can be used to computationally segment a forty-teravoxel whole-brain Drosophila ssTEM volume. To compensate for data irregularities and imperfect global alignment, FFNs were combined with procedures that locally re-align serial sections as well as dynamically adjust and synthesize image content. The proposed approach produced a largely merger-free segmentation of the entire ssTEM Drosophila brain, which we make freely available. As compared to manual tracing using an efficient skeletonization strategy, the segmentation enabled circuit reconstruction and analysis workflows that were an order of magnitude faster.

Published

2021

4. A Connectome of the Adult Drosophila Central Brain

Author

Audrey Francis, Ting Zhao, Feng Li, Megan Sammons, Madelaine K Robertson, SungJin Kim, Tyler Paterson, Philipp Schlegel, Chelsea X Alvarado, Viren Jain, Brandon S Canino, Omotara Ogundeyi, Nora Forknall, Dagmar Kainmueller, Tansy Yang, Natasha Cheatham, Neha Rampally, Caitlin Ribeiro, Kimothy L. Smith, Emily M Phillips, Ruchi Parekh, Jackie Swift, Donald J. Olbris, Takashi Kawase, Jon Thomson Rymer, Zhiyuan Lu, Nicholas Padilla, Christopher Ordish, Dorota Tarnogorska, Nicole Neubarth, Aya Shinomiya, Miatta Ndama, Samantha Finley, Stuart Berg, Erika Neace, Bryon Eubanks, John A. Bogovic, David G. Ackerman, Robert Svirskas, Sari McLin, Emily A Manley, Jane Anne Horne, Michael A Cook, Samantha Ballinger, Michał Januszewski, Jeremy Maitin-Shepard, Caroline Mooney, Nicole A Kirk, Shin-ya Takemura, Iris Talebi, Temour Tokhi, Kei K. Ito, Khaled Khairy, Stephen M. Plaza, Julie Kovalyak, Patricia K. Rivlin, Emily M Joyce, Kelli Fairbanks, Philip M Hubbard, Charli Maldonado, Nneoma Okeoma, Hideo Otsuna, Laurence F. Lindsey, Tim Blakely, Gerald M. Rubin, Alanna Lohff, William T. Katz, Anne K Scott, Mutsumi Ito, Peter H. Li, Ian A. Meinertzhagen, Natalie L Smith, Gary B. Huang, Dennis A Bailey, Reed A. George, Kenneth J. Hayworth, Tom Dolafi, Marisa Dreher, Tanya Wolff, Kazunori Shinomiya, Harald F. Hess, E.T. Troutman, Christopher J Knecht, Gary Patrick Hopkins, Alia Suleiman, Vivek Jayaraman, Emily Tenshaw, Octave Duclos, John J. Walsh, Stephan Saalfeld, Louis K. Scheffer, Elliott E Phillips, Lowell Umayam, Jens Goldammer, Sobeski, Jody Clements, Ashley L Scott, Shirley Lauchie, Sean M Ryan, Christopher Patrick, Jolanta A. Borycz, Claire Smith, C.S. Xu, and Laramie Leavitt

Subjects

Cell type, Computer science, Cell, Machine learning, computer.software_genre, Synapse, 03 medical and health sciences, 0302 clinical medicine, medicine, Biological neural network, 030304 developmental biology, Structure (mathematical logic), 0303 health sciences, biology, business.industry, Motor control, biology.organism_classification, Associative learning, medicine.anatomical_structure, Mushroom bodies, Identity (object-oriented programming), Connectome, Artificial intelligence, Drosophila melanogaster, Function and Dysfunction of the Nervous System, business, computer, 030217 neurology & neurosurgery

Abstract

The neural circuits responsible for behavior remain largely unknown. Previous efforts have reconstructed the complete circuits of small animals, with hundreds of neurons, and selected circuits for larger animals. Here we (the FlyEM project at Janelia and collaborators at Google) summarize new methods and present the complete circuitry of a large fraction of the brain of a much more complex animal, the fruit fly Drosophila melanogaster. Improved methods include new procedures to prepare, image, align, segment, find synapses, and proofread such large data sets; new methods that define cell types based on connectivity in addition to morphology; and new methods to simplify access to a large and evolving data set. From the resulting data we derive a better definition of computational compartments and their connections; an exhaustive atlas of cell examples and types, many of them novel; detailed circuits for most of the central brain; and exploration of the statistics and structure of different brain compartments, and the brain as a whole. We make the data public, with a web site and resources specifically designed to make it easy to explore, for all levels of expertise from the expert to the merely curious. The public availability of these data, and the simplified means to access it, dramatically reduces the effort needed to answer typical circuit questions, such as the identity of upstream and downstream neural partners, the circuitry of brain regions, and to link the neurons defined by our analysis with genetic reagents that can be used to study their functions.Note: In the next few weeks, we will release a series of papers with more involved discussions. One paper will detail the hemibrain reconstruction with more extensive analysis and interpretation made possible by this dense connectome. Another paper will explore the central complex, a brain region involved in navigation, motor control, and sleep. A final paper will present insights from the mushroom body, a center of multimodal associative learning in the fly brain.

Published

2020

5. Accelerated EM Connectome Reconstruction using 3D Visualization and Segmentation Graphs

Author

Philip M Hubbard, Lowell Umayam, Erika Neace, William T. Katz, Ting Zhao, Stuart Berg, Michał Januszewski, Jeremy Maitin-Shepard, Stephen M. Plaza, and Donald J. Olbris

Subjects

Computer science, business.industry, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, Connectome, Segmentation, Pattern recognition, Context (language use), Image segmentation, Artificial intelligence, business, Visualization

Abstract

Recent advances in automatic image segmentation and synapse prediction in electron microscopy (EM) datasets of the brain enable more efficient reconstruction of neural connectivity. In these datasets, a single neuron can span thousands of images containing complex tree-like arbors with thousands of synapses. While image segmentation algorithms excel within narrow fields of views, the algorithms sometimes struggle to correctly segment large neurons, which require large context given their size and complexity. Conversely, humans are comparatively good at reasoning with large objects. In this paper, we introduce several semi-automated strategies that combine 3D visualization and machine guidance to accelerate connectome reconstruction. In particular, we introduce a strategy to quickly correct a segmentation through merging and cleaving, or splitting a segment along supervoxel boundaries, with both operations driven by affinity scores in the underlying segmentation. We deploy these algorithms as streamlined workflows in a tool called Neu3 and demonstrate superior performance compared to prior work, thus enabling efficient reconstruction of much larger datasets. The insights into proofreading from our work clarify the trade-offs to consider when tuning the parameters of image segmentation algorithms.

Published

2020

6. Neuronal Subcompartment Classification and Merge Error Correction

Author

Viren Jain, Peter H. Li, Michał Januszewski, and Hanyu Li

Subjects

0301 basic medicine, 3d electron microscopy, Connectomics, Computer science, business.industry, Pattern recognition, Dendrite, Brain tissue, computer.software_genre, Convolutional neural network, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, medicine.anatomical_structure, Voxel, medicine, Leverage (statistics), Artificial intelligence, Axon, Error detection and correction, business, computer, 030217 neurology & neurosurgery

Abstract

Recent advances in 3d electron microscopy are yielding ever larger reconstructions of brain tissue, encompassing thousands of individual neurons interconnected by millions of synapses. Interpreting reconstructions at this scale demands advances in the automated analysis of neuronal morphologies, for example by identifying morphological and functional subcompartments within neurons. We present a method that for the first time uses full 3d input (voxels) to automatically classify reconstructed neuron fragments as axon, dendrite, or somal subcompartments. Based on 3d convolutional neural networks, this method achieves a mean f1-score of 0.972, exceeding the previous state of the art of 0.955. The resulting predictions can support multiple analysis and proofreading applications. In particular, we leverage finely localized subcompartment predictions for automated detection and correction of merge errors in the volume reconstruction, successfully detecting 90.6% of inter-class merge errors with a false positive rate of only 2.7%.

Published

2020

7. Learning cellular morphology with neural networks

Author

Michał Januszewski, Philipp J Schubert, Sven Dorkenwald, Joergen Kornfeld, and Viren Jain

Subjects

Male, 0301 basic medicine, Cell type, Computer science, Science, Datasets as Topic, General Physics and Astronomy, Image processing, 02 engineering and technology, Brain tissue, Article, General Biochemistry, Genetics and Molecular Biology, law.invention, 03 medical and health sciences, law, Image Processing, Computer-Assisted, medicine, Animals, Passeriformes, lcsh:Science, Neurons, Multidisciplinary, Artificial neural network, business.industry, Brain, Pattern recognition, General Chemistry, 021001 nanoscience & nanotechnology, Computational biology and bioinformatics, Microscopy, Electron, medicine.anatomical_structure, 030104 developmental biology, Neuronal circuits, Synapses, Feasibility Studies, lcsh:Q, Neural Networks, Computer, Neuron, Artificial intelligence, Cellular Morphology, Electron microscope, 0210 nano-technology, business, Algorithms, Neuroscience

Abstract

Reconstruction and annotation of volume electron microscopy data sets of brain tissue is challenging but can reveal invaluable information about neuronal circuits. Significant progress has recently been made in automated neuron reconstruction as well as automated detection of synapses. However, methods for automating the morphological analysis of nanometer-resolution reconstructions are less established, despite the diversity of possible applications. Here, we introduce cellular morphology neural networks (CMNs), based on multi-view projections sampled from automatically reconstructed cellular fragments of arbitrary size and shape. Using unsupervised training, we infer morphology embeddings (Neuron2vec) of neuron reconstructions and train CMNs to identify glia cells in a supervised classification paradigm, which are then used to resolve neuron reconstruction errors. Finally, we demonstrate that CMNs can be used to identify subcellular compartments and the cell types of neuron reconstructions., Volume electron microscopy data of brain tissue can tell us much about neural circuits, but increasingly large data sets demand automation of analysis. Here, the authors introduce cellular morphology neural networks and successfully automate a range of morphological analysis tasks.

Published

2019

8. Automated Reconstruction of a Serial-Section EM Drosophila Brain with Flood-Filling Networks and Local Realignment

Author

István Taisz, Michał Januszewski, Michael D. Tyka, Gregory S.X.E. Jefferis, Jeremy Maitin-Shepard, Viren Jain, Alexander Shakeel Bates, Eric Perlman, Zhihao Zheng, Laramie Leavitt, Feng Li, Matthew Nichols, Larry Lindsey, Tim Blakely, Peter H. Li, and Davi D. Bock

Subjects

0303 health sciences, Computer science, business.industry, Volume (computing), Serial section, Skeletonization, 03 medical and health sciences, 0302 clinical medicine, Transmission electron microscopy, Segmentation, Computer vision, Artificial intelligence, business, 030217 neurology & neurosurgery, 030304 developmental biology

Abstract

Reconstruction of neural circuitry at single-synapse resolution is a key target for improving understanding of the nervous system in health and disease. Serial section transmission electron microscopy (ssTEM) is among the most prolific imaging methods employed in pursuit of such reconstructions. We demonstrate how Flood-Filling Networks (FFNs) can be used to computationally segment a forty-teravoxel whole-brain Drosophila ssTEM volume. To compensate for data irregularities and imperfect global alignment, FFNs were combined with procedures that locally re-align serial sections as well as dynamically adjust and synthesize image content. The proposed approach produced a largely merger-free segmentation of the entire ssTEM Drosophila brain, which we make freely available. As compared to manual tracing using an efficient skeletonization strategy, the segmentation enabled circuit reconstruction and analysis workflows that were an order of magnitude faster.

Published

2019

9. GCIB-SEM: A path to 10 nm isotropic imaging of cubic millimeter volumes

Author

Kenneth J. Hayworth, David Peale, Graham Knott, Harald F. Hess, C.S. Xu, Zhiyuan Lu, and Michał Januszewski

Subjects

Optics, Materials science, Gas cluster ion beam, business.industry, Scanning electron microscope, Isotropy, Ultrastructure, Segmentation, Ion milling machine, business, Focused ion beam, Ultrashort pulse

Abstract

Focused Ion Beam Scanning Electron Microscopy (FIB-SEM) generates 3D datasets optimally suited for segmentation of cell ultrastructure and automated connectome tracing but is limited to small fields of view and is therefore incompatible with the new generation of ultrafast multibeam SEMs. In contrast, section-based techniques are multibeam-compatible but are limited in z-resolution making automatic segmentation of cellular ultrastructure difficult. Here we demonstrate a novel 3D electron microscopy technique, Gas Cluster Ion Beam SEM (GCIB-SEM), in which top-down, wide-area ion milling is performed on a series of thick sections, acquiring < 10 nm isotropic datasets of each which are then stitched together to span the full sectioned volume. Based on our results, incorporating GCIB-SEM into existing single beam and multibeam SEM workflows should be straightforward and should dramatically increase reliability while simultaneously improving z-resolution by a factor of 3 or more.

Published

2019

10. High-precision automated reconstruction of neurons with flood-filling networks

Author

Art Pope, Tim Blakely, Peter H. Li, Michał Januszewski, Viren Jain, Jeremy Maitin-Shepard, Larry Lindsey, Winfried Denk, Michael D. Tyka, and Jörgen Kornfeld

Subjects

0301 basic medicine, Male, Neurite, Computer science, Tracing, Machine learning, computer.software_genre, Biochemistry, Convolutional neural network, Machine Learning, 03 medical and health sciences, Mice, 0302 clinical medicine, Imaging, Three-Dimensional, Path length, Microscopy, Electron, Transmission, Biological neural network, Image Processing, Computer-Assisted, Neurites, Animals, Segmentation, Molecular Biology, Zebra finch, TRACE (psycholinguistics), Neurons, Computational neuroscience, business.industry, Brain, Cell Biology, Data set, 030104 developmental biology, Test set, Drosophila, Artificial intelligence, Finches, Nerve Net, business, Algorithm, computer, 030217 neurology & neurosurgery, Algorithms, Biotechnology

Abstract

Reconstruction of neural circuits from volume electron microscopy data requires the tracing of cells in their entirety, including all their neurites. Automated approaches have been developed for tracing, but their error rates are too high to generate reliable circuit diagrams without extensive human proofreading. We present flood-filling networks, a method for automated segmentation that, similar to most previous efforts, uses convolutional neural networks, but contains in addition a recurrent pathway that allows the iterative optimization and extension of individual neuronal processes. We used flood-filling networks to trace neurons in a dataset obtained by serial block-face electron microscopy of a zebra finch brain. Using our method, we achieved a mean error-free neurite path length of 1.1 mm, and we observed only four mergers in a test set with a path length of 97 mm. The performance of flood-filling networks was an order of magnitude better than that of previous approaches applied to this dataset, although with substantially increased computational costs.

Published

2018

11. Anisotropy of flow in stochastically generated porous media

Author

Jarosław Gołembiewski, Marcin Kostur, Maciej Matyka, Zbigniew Koza, and Michał Januszewski

Subjects

Body force, Materials science, business.industry, Fluid Dynamics (physics.flu-dyn), FOS: Physical sciences, Mechanics, Physics - Fluid Dynamics, 01 natural sciences, Grain size, 010305 fluids & plasmas, Optics, 0103 physical sciences, Representative elementary volume, Perpendicular, 010306 general physics, Anisotropy, Porous medium, Porosity, business, Pressure gradient

Abstract

Models of porous media are often applied to relatively small systems, which leads not only to system-size-dependent results, but also to phenomena that would be absent in larger systems. Here we investigate one such finite-size effect: anisotropy of the permeability tensor. We show that a non-zero angle between the external body force and macroscopic flux vector exists in three-dimensional periodic models of sizes commonly used in computer simulations and propose a criterion, based on the system size to the grain size ratio, for this phenomenon to be relevant or negligible. The finite-size anisotropy of the porous matrix induces a pressure gradient perpendicular to the axis of a porous duct and we analyze how this effect scales with the system and grain sizes., 5 pages, 3 figures

Published

2013