Your search keyword '"Kasthuri N"' showing total 6 results

1. A three-dimensional thalamocortical dataset for characterizing brain heterogeneity.

Author

Prasad JA, Balwani AH, Johnson EC, Miano JD, Sampathkumar V, De Andrade V, Fezzaa K, Du M, Vescovi R, Jacobsen C, Kording KP, Gürsoy D, Gray Roncal W, Kasthuri N, and Dyer EL

Subjects

Animals, Brain diagnostic imaging, Mice, Brain anatomy & histology, Brain Mapping, Imaging, Three-Dimensional, X-Ray Microtomography

Abstract

Neural microarchitecture is heterogeneous, varying both across and within brain regions. The consistent identification of regions of interest is one of the most critical aspects in examining neurocircuitry, as these structures serve as the vital landmarks with which to map brain pathways. Access to continuous, three-dimensional volumes that span multiple brain areas not only provides richer context for identifying such landmarks, but also enables a deeper probing of the microstructures within. Here, we describe a three-dimensional X-ray microtomography imaging dataset of a well-known and validated thalamocortical sample, encompassing a range of cortical and subcortical structures from the mouse brain . In doing so, we provide the field with access to a micron-scale anatomical imaging dataset ideal for studying heterogeneity of neural structure.

Published

2020

2. Flexible Learning-Free Segmentation and Reconstruction of Neural Volumes.

Author

Shahbazi A, Kinnison J, Vescovi R, Du M, Hill R, Joesch M, Takeno M, Zeng H, da Costa NM, Grutzendler J, Kasthuri N, and Scheirer WJ

Subjects

Algorithms, Animals, Mice, Synchrotrons instrumentation, X-Ray Microtomography methods, Image Processing, Computer-Assisted methods, Imaging, Three-Dimensional methods, Machine Learning

Abstract

Imaging is a dominant strategy for data collection in neuroscience, yielding stacks of images that often scale to gigabytes of data for a single experiment. Machine learning algorithms from computer vision can serve as a pair of virtual eyes that tirelessly processes these images, automatically detecting and identifying microstructures. Unlike learning methods, our Flexible Learning-free Reconstruction of Imaged Neural volumes (FLoRIN) pipeline exploits structure-specific contextual clues and requires no training. This approach generalizes across different modalities, including serially-sectioned scanning electron microscopy (sSEM) of genetically labeled and contrast enhanced processes, spectral confocal reflectance (SCoRe) microscopy, and high-energy synchrotron X-ray microtomography (μCT) of large tissue volumes. We deploy the FLoRIN pipeline on newly published and novel mouse datasets, demonstrating the high biological fidelity of the pipeline's reconstructions. FLoRIN reconstructions are of sufficient quality for preliminary biological study, for example examining the distribution and morphology of cells or extracting single axons from functional data. Compared to existing supervised learning methods, FLoRIN is one to two orders of magnitude faster and produces high-quality reconstructions that are tolerant to noise and artifacts, as is shown qualitatively and quantitatively.

Published

2018

3. Large-scale automatic reconstruction of neuronal processes from electron microscopy images.

Author

Kaynig V, Vazquez-Reina A, Knowles-Barley S, Roberts M, Jones TR, Kasthuri N, Miller E, Lichtman J, and Pfister H

Subjects

Algorithms, Image Enhancement methods, Machine Learning, Reproducibility of Results, Sensitivity and Specificity, Subtraction Technique, Brain ultrastructure, Image Interpretation, Computer-Assisted methods, Imaging, Three-Dimensional methods, Microscopy, Electron methods, Neurons ultrastructure, Pattern Recognition, Automated methods

Abstract

Automated sample preparation and electron microscopy enables acquisition of very large image data sets. These technical advances are of special importance to the field of neuroanatomy, as 3D reconstructions of neuronal processes at the nm scale can provide new insight into the fine grained structure of the brain. Segmentation of large-scale electron microscopy data is the main bottleneck in the analysis of these data sets. In this paper we present a pipeline that provides state-of-the art reconstruction performance while scaling to data sets in the GB-TB range. First, we train a random forest classifier on interactive sparse user annotations. The classifier output is combined with an anisotropic smoothing prior in a Conditional Random Field framework to generate multiple segmentation hypotheses per image. These segmentations are then combined into geometrically consistent 3D objects by segmentation fusion. We provide qualitative and quantitative evaluation of the automatic segmentation and demonstrate large-scale 3D reconstructions of neuronal processes from a 27,000 μm(3) volume of brain tissue over a cube of 30 μm in each dimension corresponding to 1000 consecutive image sections. We also introduce Mojo, a proofreading tool including semi-automated correction of merge errors based on sparse user scribbles., (Copyright © 2015 Elsevier B.V. All rights reserved.)

Published

2015

4. Design and Evaluation of Interactive Proofreading Tools for Connectomics.

Author

Haehn D, Knowles-Barley S, Roberts M, Beyer J, Kasthuri N, Lichtman JW, and Pfister H

Subjects

Adult, Algorithms, Animals, Female, Humans, Internet, Male, Mice, Software, Young Adult, Computer Graphics, Connectome methods, Imaging, Three-Dimensional methods

Abstract

Proofreading refers to the manual correction of automatic segmentations of image data. In connectomics, electron microscopy data is acquired at nanometer-scale resolution and results in very large image volumes of brain tissue that require fully automatic segmentation algorithms to identify cell boundaries. However, these algorithms require hundreds of corrections per cubic micron of tissue. Even though this task is time consuming, it is fairly easy for humans to perform corrections through splitting, merging, and adjusting segments during proofreading. In this paper we present the design and implementation of Mojo, a fully-featured single-user desktop application for proofreading, and Dojo, a multi-user web-based application for collaborative proofreading. We evaluate the accuracy and speed of Mojo, Dojo, and Raveler, a proofreading tool from Janelia Farm, through a quantitative user study. We designed a between-subjects experiment and asked non-experts to proofread neurons in a publicly available connectomics dataset. Our results show a significant improvement of corrections using web-based Dojo, when given the same amount of time. In addition, all participants using Dojo reported better usability. We discuss our findings and provide an analysis of requirements for designing visual proofreading software.

Published

2014

5. NeuroLines: A Subway Map Metaphor for Visualizing Nanoscale Neuronal Connectivity.

Author

Al-Awami AK, Beyer J, Strobelt H, Kasthuri N, Lichtman JW, Pfister H, and Hadwiger M

Subjects

Brain cytology, Humans, Models, Theoretical, Neurons cytology, Railroads, Brain physiology, Computer Graphics, Connectome methods, Imaging, Three-Dimensional methods, Nerve Net physiology, Neurons physiology

Abstract

We present NeuroLines, a novel visualization technique designed for scalable detailed analysis of neuronal connectivity at the nanoscale level. The topology of 3D brain tissue data is abstracted into a multi-scale, relative distance-preserving subway map visualization that allows domain scientists to conduct an interactive analysis of neurons and their connectivity. Nanoscale connectomics aims at reverse-engineering the wiring of the brain. Reconstructing and analyzing the detailed connectivity of neurons and neurites (axons, dendrites) will be crucial for understanding the brain and its development and diseases. However, the enormous scale and complexity of nanoscale neuronal connectivity pose big challenges to existing visualization techniques in terms of scalability. NeuroLines offers a scalable visualization framework that can interactively render thousands of neurites, and that supports the detailed analysis of neuronal structures and their connectivity. We describe and analyze the design of NeuroLines based on two real-world use-cases of our collaborators in developmental neuroscience, and investigate its scalability to large-scale neuronal connectivity data.

Published

2014

6. ConnectomeExplorer: query-guided visual analysis of large volumetric neuroscience data.

Author

Beyer J, Al-Awami A, Kasthuri N, Lichtman JW, Pfister H, and Hadwiger M

Subjects

Algorithms, Computer Graphics, Image Enhancement methods, Reproducibility of Results, Sensitivity and Specificity, Brain ultrastructure, Connectome methods, Data Mining methods, Imaging, Three-Dimensional methods, Microscopy, Electron methods, Nerve Fibers, Myelinated ultrastructure, User-Computer Interface

Abstract

This paper presents ConnectomeExplorer, an application for the interactive exploration and query-guided visual analysis of large volumetric electron microscopy (EM) data sets in connectomics research. Our system incorporates a knowledge-based query algebra that supports the interactive specification of dynamically evaluated queries, which enable neuroscientists to pose and answer domain-specific questions in an intuitive manner. Queries are built step by step in a visual query builder, building more complex queries from combinations of simpler queries. Our application is based on a scalable volume visualization framework that scales to multiple volumes of several teravoxels each, enabling the concurrent visualization and querying of the original EM volume, additional segmentation volumes, neuronal connectivity, and additional meta data comprising a variety of neuronal data attributes. We evaluate our application on a data set of roughly one terabyte of EM data and 750 GB of segmentation data, containing over 4,000 segmented structures and 1,000 synapses. We demonstrate typical use-case scenarios of our collaborators in neuroscience, where our system has enabled them to answer specific scientific questions using interactive querying and analysis on the full-size data for the first time.

Published

2013