Your search keyword '"Daniel Kapner"' showing total 8 results

1. A scalable and modular automated pipeline for stitching of large electron microscopy datasets

Author

Gayathri Mahalingam, Russel Torres, Daniel Kapner, Eric T Trautman, Tim Fliss, Shamishtaa Seshamani, Eric Perlman, Rob Young, Samuel Kinn, JoAnn Buchanan, Marc M Takeno, Wenjing Yin, Daniel J Bumbarger, Ryder P Gwinn, Julie Nyhus, Ed Lein, Steven J Smith, R Clay Reid, Khaled A Khairy, Stephan Saalfeld, Forrest Collman, and Nuno Macarico da Costa

Subjects

connectomics, image processing, image alignment, image stitching, large-scale microscopy, Medicine, Science, Biology (General), QH301-705.5

Abstract

Serial-section electron microscopy (ssEM) is the method of choice for studying macroscopic biological samples at extremely high resolution in three dimensions. In the nervous system, nanometer-scale images are necessary to reconstruct dense neural wiring diagrams in the brain, so -called connectomes. The data that can comprise of up to 108 individual EM images must be assembled into a volume, requiring seamless 2D registration from physical section followed by 3D alignment of the stitched sections. The high throughput of ssEM necessitates 2D stitching to be done at the pace of imaging, which currently produces tens of terabytes per day. To achieve this, we present a modular volume assembly software pipeline ASAP (Assembly Stitching and Alignment Pipeline) that is scalable to datasets containing petabytes of data and parallelized to work in a distributed computational environment. The pipeline is built on top of the Render Trautman and Saalfeld (2019) services used in the volume assembly of the brain of adult Drosophila melanogaster (Zheng et al. 2018). It achieves high throughput by operating only on image meta-data and transformations. ASAP is modular, allowing for easy incorporation of new algorithms without significant changes in the workflow. The entire software pipeline includes a complete set of tools for stitching, automated quality control, 3D section alignment, and final rendering of the assembled volume to disk. ASAP has been deployed for continuous stitching of several large-scale datasets of the mouse visual cortex and human brain samples including one cubic millimeter of mouse visual cortex (Yin et al. 2020); Microns Consortium et al. (2021) at speeds that exceed imaging. The pipeline also has multi-channel processing capabilities and can be applied to fluorescence and multi-modal datasets like array tomography.

Published

2022

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

Author

Wenjing Yin, Derrick Brittain, Jay Borseth, Marie E. Scott, Derric Williams, Jedediah Perkins, Christopher S. Own, Matthew Murfitt, Russel M. Torres, Daniel Kapner, Gayathri Mahalingam, Adam Bleckert, Daniel Castelli, David Reid, Wei-Chung Allen Lee, Brett J. Graham, Marc Takeno, Daniel J. Bumbarger, Colin Farrell, R. Clay Reid, and Nuno Macarico da Costa

Subjects

Science

Abstract

Electron microscopy (EM) is the gold standard for biological ultrastructure but acquisition speed is slow, making it unsuitable for large volumes. Here the authors present a parallel imaging pipeline for continuous autonomous imaging with six transmission EMs to image 1 mm3 of mouse cortex in less than 6 months.

Published

2020

3. Stimulus novelty uncovers coding diversity in visual cortical circuits

Author

Marina Garrett, Peter Groblewski, Alex Piet, Doug Ollerenshaw, Farzaneh Najafi, Iryna Yavorska, Adam Amster, Corbett Bennett, Michael Buice, Shiella Caldejon, Linzy Casal, Florence D’Orazi, Scott Daniel, Saskia EJ de Vries, Daniel Kapner, Justin Kiggins, Jerome Lecoq, Peter Ledochowitsch, Sahar Manavi, Nicholas Mei, Christopher B. Morrison, Sarah Naylor, Natalia Orlova, Jed Perkins, Nick Ponvert, Clark Roll, Sam Seid, Derric Williams, Allison Williford, Ruweida Ahmed, Daniel Amine, Yazan Billeh, Chris Bowman, Nicholas Cain, Andrew Cho, Tim Dawe, Max Departee, Marie Desoto, David Feng, Sam Gale, Emily Gelfand, Nile Gradis, Conor Grasso, Nicole Hancock, Brian Hu, Ross Hytnen, Xiaoxuan Jia, Tye Johnson, India Kato, Sara Kivikas, Leonard Kuan, Quinn L’Heureux, Sophie Lambert, Arielle Leon, Elizabeth Liang, Fuhui Long, Kyla Mace, Ildefons Magrans de Abril, Chris Mochizuki, Chelsea Nayan, Katherine North, Lydia Ng, Gabriel Koch Ocker, Michael Oliver, Paul Rhoads, Kara Ronellenfitch, Kathryn Schelonka, Josh Sevigny, David Sullivan, Ben Sutton, Jackie Swapp, Thuyanh K Nguyen, Xana Waughman, Joshua Wilkes, Michael Wang, Colin Farrell, Wayne Wakeman, Hongkui Zeng, John Phillips, Stefan Mihalas, Anton Arkhipov, Christof Koch, and Shawn R Olsen

Abstract

The detection of novel stimuli is critical to learn and survive in a dynamic environment. Though novel stimuli powerfully affect brain activity, their impact on specific cell types and circuits is not well understood. Disinhibition is one candidate mechanism for novelty-induced enhancements in activity. Here we characterize the impact of stimulus novelty on disinhibitory circuit components using longitudinal 2-photon calcium imaging of Vip, Sst, and excitatory populations in the mouse visual cortex. Mice learn a behavioral task with stimuli that become highly familiar, then are tested on both familiar and novel stimuli. Mice consistently perform the task with novel stimuli, yet responses to stimulus presentations and stimulus omissions are dramatically altered. Further, we find that novelty modifies coding of visual as well as behavioral and task information. At the population level, the direction of these changes is consistent with engagement of the Vip-Sst disinhibitory circuit. At the single cell level, we identify separate clusters of Vip, Sst, and excitatory cells with unique patterns of novelty-induced coding changes. This study and the accompanying open-access dataset reveals the impact of novelty on sensory and behavioral representations in visual cortical circuits and establishes novelty as a key driver of cellular functional diversity.

Published

2023

4. A scalable and modular automated pipeline for stitching of large electron microscopy datasets

Author

Sharmishtaa Seshamani, Sam Kinn, Clay Reid, Julie Nyhus, Wenjing Yin, Eric T. Trautman, Stephan Saalfeld, JoAnn Buchanan, Stephen J. Smith, Khaled Khairy, R. P. Gwinn, Russel Torres, Tim P. Fliss, N. Macarico da Costa, Daniel J. Bumbarger, Gayathri Mahalingam, Marc Takeno, Ed S. Lein, Daniel Kapner, R.D. Young, Forrest Collman, and Eric Perlman

Subjects

Assembly software, General Immunology and Microbiology, business.industry, Computer science, Pipeline (computing), General Neuroscience, Volume (computing), Brain, General Medicine, Workflow engine, General Biochemistry, Genetics and Molecular Biology, Rendering (computer graphics), Image stitching, Mice, Microscopy, Electron, Software, Drosophila melanogaster, Image Processing, Computer-Assisted, Animals, Humans, business, Throughput (business), Computer hardware, Algorithms

Abstract

Serial-section electron microscopy (ssEM) is the method of choice for studying macroscopic biological samples at extremely high resolution in three dimensions. In the nervous system, nanometer-scale images are necessary to reconstruct dense neural wiring diagrams in the brain, so calledconnectomes. In order to use this data, consisting of up to 108individual EM images, it must be assembled into a volume, requiring seamless 2D stitching from each physical section followed by 3D alignment of the stitched sections. The high throughput of ssEM necessitates 2D stitching to be done at the pace of imaging, which currently produces tens of terabytes per day. To achieve this, we present a modular volume assembly software pipelineASAP(Assembly Stitching and Alignment Pipeline) that is scalable to datasets containing petabytes of data and parallelized to work in a distributed computational environment. The pipeline is built on top of theRender[18] services used in the volume assembly of the brain of adultDrosophila melanogaster[2]. It achieves high throughput by operating on the meta-data and transformations of each image stored in a database, thus eliminating the need to render intermediate output. ASAP is modular, allowing for easy incorporation of new algorithms without significant changes in the workflow. The entire software pipeline includes a complete set of tools for stitching, automated quality control, 3D section alignment, and final rendering of the assembled volume to disk. ASAP has been deployed for continuous processing of several large-scale datasets of the mouse visual cortex and human brain samples including one cubic millimeter of mouse visual cortex [1, 25] at speeds that exceed imaging. The pipeline also has multi-channel processing capabilities and can be applied to fluorescence and multi-modal datasets like array tomography.

Published

2022

5. Author response: A scalable and modular automated pipeline for stitching of large electron microscopy datasets

Author

Russel Torres, Gayathri Mahalingam, Daniel Kapner, Eric T Trautman, Tim Fliss, Shamishtaa Seshamani, Eric Perlman, Rob Young, Samuel Kinn, JoAnn Buchanan, Marc M Takeno, Wenjing Yin, Daniel J Bumbarger, Ryder P Gwinn, Julie Nyhus, Ed Lein, Steven J Smith, R Clay Reid, Khaled A Khairy, Stephan Saalfeld, Forrest Collman, and Nuno Macarico da Costa

Published

2022

6. Petascale neural circuit reconstruction: automated methods

Author

Sven Dorkenwald, Russel Torres, Nicholas L. Turner, Eric Mitchell, Manuel Castro, Saumil S. Patel, Nico Kemnitz, William Silversmith, Paul G. Fahey, Thomas Macrina, H. Sebastian Seung, Ran Lu, Fabian H. Sinz, Wenjing Yin, J. Alexander Bae, Szi-chieh Yu, Xaq Pitkow, Kisuk Lee, Leila Elabbady, Agnes L. Bodor, Shang Mu, Emmanouil Froudarakis, Forrest Collman, Sam Kinn, Sergiy Popovych, Jacob Reimer, JoAnn Buchanan, Daniel J. Bumbarger, Erick Cobos, Barak Nehoran, Gayathri Mahalingam, Akhilesh Halageri, Stelios Papadopoulos, Daniel Kapner, Marc Takeno, Casey M Schneider-Mizell, Kai Li, Nuno Maçarico da Costa, R. Clay Reid, Jingpeng Wu, Shanka Subhra Mondal, Zhen Jia, Chris S. Jordan, William Wong, Derrick Brittain, and Andreas S. Tolias

Subjects

business.industry, Computer science, Pipeline (computing), media_common.quotation_subject, Volume (computing), Pattern recognition, Cloud computing, computer.software_genre, Petascale computing, medicine.anatomical_structure, Debugging, Voxel, medicine, Soma, Artificial intelligence, business, Cloud storage, computer, media_common

Abstract

3D electron microscopy (EM) has been successful at mapping invertebrate nervous systems, but the approach has been limited to small chunks of mammalian brains. To scale up to larger volumes, we have built a computational pipeline for processing petascale image datasets acquired by serial section EM, a popular form of 3D EM. The pipeline employs convolutional nets to compute the nonsmooth transformations required to align images of serial sections containing numerous cracks and folds, detect neuronal boundaries, label voxels as axon, dendrite, soma, and other semantic categories, and detect synapses and assign them to presynaptic and postsynaptic segments. The output of neuronal boundary detection is segmented by mean affinity agglomeration with semantic and size constraints. Pipeline operations are implemented by leveraging distributed and cloud computing. Intermediate results of the pipeline are held in cloud storage, and can be effortlessly viewed as images, which aids debugging. We applied the pipeline to create an automated reconstruction of an EM image volume spanning four visual cortical areas of a mouse brain. Code for the pipeline is publicly available, as is the reconstructed volume.

Published

2021

7. Functional connectomics spanning multiple areas of mouse visual cortex

Author

Russel Torres, Kai Kuehner, Wenjing Yin, Saumil S. Patel, Chris Xu, Emmanouil Froudarakis, Grace Williams, Amy L. R. Sterling, Nicholas L. Turner, Daniel J. Bumbarger, Anthony Ramos, Andreas S. Tolias, Zheng H Tan, Fei Ye, J. Alexander Bae, Brendan Celii, Szi-chieh Yu, Runzhe Yang, Jingpeng Wu, Oluwaseun Ogedengbe, Merlin Moore, Gayathri Mahalingam, Kyle Willie, Xaq Pitkow, Sarah Williams, Christos Papadopoulos, Sven Dorkenwald, Daniel Kapner, Sam Kinn, Ran Lu, Dimitri Yatsenko, Leila Elabbady, Fabian H. Sinz, Selden Koolman, Agnes L. Bodor, Ben Silverman, Nico Kemnitz, Chris S. Jordan, Sergiy Popovych, Elanine Miranda, Cameron Smith, Akhilesh Halageri, Paul G. Fahey, Tianyu Wang, William Silversmith, Sarah McReynolds, Ryan Willie, Eric Mitchell, Jacob Reimer, JoAnn Buchanan, Edgar Y. Walker, Barak Nehoran, Thomas Macrina, Zhen Jia, H. Sebastian Seung, William Wong, Stelios Papadopoulos, James Hebditch, Derrick Brittain, Casey M Schneider-Mizell, Nuno Maçarico da Costa, Manuel Castro, Forrest Collman, R. Clay Reid, Shanka Subhra Mondal, Marc Takeno, Kai Li, Tim P. Fliss, Jay Gager, Taliah Muhammad, Shang Mu, Clare Gamlin, Shelby Suckow, Erick Cobos, Mahaly Baptiste, and Kisuk Lee

Subjects

Connectomics, Calcium imaging, medicine.anatomical_structure, Visual cortex, Neocortex, nervous system, Excitatory postsynaptic potential, medicine, Neuron, Axon, Biology, Inhibitory postsynaptic potential, Neuroscience

Abstract

To understand the brain we must relate neurons’ functional responses to the circuit architecture that shapes them. Here, we present a large functional connectomics dataset with dense calcium imaging of a millimeter scale volume. We recorded activity from approximately 75,000 neurons in primary visual cortex (VISp) and three higher visual areas (VISrl, VISal and VISlm) in an awake mouse viewing natural movies and synthetic stimuli. The functional data were co-registered with a volumetric electron microscopy (EM) reconstruction containing more than 200,000 cells and 0.5 billion synapses. Subsequent proofreading of a subset of neurons in this volume yielded reconstructions that include complete dendritic trees as well the local and inter-areal axonal projections that map up to thousands of cell-to-cell connections per neuron. Here, we release this dataset as an open-access resource to the scientific community including a set of tools that facilitate data retrieval and downstream analysis. In accompanying papers we describe our findings using the dataset to provide a comprehensive structural characterization of cortical cell types1–3and the most detailed synaptic level connectivity diagram of a cortical column to date2, uncovering unique cell-type specific inhibitory motifs that can be linked to gene expression data4. Functionally, we identify new computational principles of how information is integrated across visual space5, characterize novel types of neuronal invariances6and bring structure and function together to decipher a general principle that wires excitatory neurons within and across areas7, 8.

Published

2021

8. A Petascale Automated Imaging Pipeline for Mapping Neuronal Circuits with High-throughput Transmission Electron Microscopy

Author

Marie E. Scott, Marc Takeno, Daniel Kapner, Daniel J. Bumbarger, Christopher S. Own, R. Clay Reid, M.F. Murfitt, Adam Bleckert, Derric Williams, Brett J. Graham, Wenjing Yin, David Reid, Daniel Castelli, Wei-Chung Allen Lee, Nuno Macarico da Costa, Colin Farrell, Derrick Brittain, Jed Perkins, Jay Borseth, and Russel Torres

Subjects

Microscope, business.industry, Computer science, Pipeline (computing), Resolution (electron density), law.invention, Petascale computing, Transmission (telecommunications), law, Transmission electron microscopy, Electron microscope, business, Throughput (business), Computer hardware

Abstract

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.

Published

2019