Your search keyword '"Mathew A. Saunders"' showing total 3 results

1. Annotating Synapses in Large EM Datasets.

Author

Stephen M. Plaza, Toufiq Parag, Gary B. Huang, Donald J. Olbris, Mathew A. Saunders, and Patricia K. Rivlin

Published

2014

2. A visual motion detection circuit suggested by Drosophila connectomics

Author

Zhiyuan Lu, Lei-Ann Chang, Satoko Takemura, Richard D. Fetter, Katerina Blazek, Donald J. Olbris, Christopher Sigmund, Philip Brown Winston, Shin-ya Takemura, William T. Katz, Jane Anne Horne, Arjun Bharioke, Victor Shapiro, Stephen M. Plaza, Patricia K. Rivlin, Mathew A. Saunders, Dmitri B. Chklovskii, Omotara Ogundeyi, Louis K. Scheffer, Shiv Naga Prasad Vitaladevuni, Aljoscha Nern, Ting Zhao, Gerald M. Rubin, and Ian A. Meinertzhagen

Subjects

Connectomics, Retina, Multidisciplinary, Motion Perception, Motion detection, Biology, Models, Biological, Article, Retinal bipolar neuron, Calcium imaging, medicine.anatomical_structure, Models of neural computation, Connectome, medicine, Animals, Drosophila, Female, Visual Pathways, Neuroscience, Medulla

Abstract

Animal behaviour arises from computations in neuronal circuits, but our understanding of these computations has been frustrated by the lack of detailed synaptic connection maps, or connectomes. For example, despite intensive investigations over half a century, the neuronal implementation of local motion detection in the insect visual system remains elusive. Here we develop a semi-automated pipeline using electron microscopy to reconstruct a connectome, containing 379 neurons and 8,637 chemical synaptic contacts, within the Drosophila optic medulla. By matching reconstructed neurons to examples from light microscopy, we assigned neurons to cell types and assembled a connectome of the repeating module of the medulla. Within this module, we identified cell types constituting a motion detection circuit, and showed that the connections onto individual motion-sensitive neurons in this circuit were consistent with their direction selectivity. Our results identify cellular targets for future functional investigations, and demonstrate that connectomes can provide key insights into neuronal computations. Reconstruction of a connectome within the fruitfly visual medulla, containing more than 300 neurons and over 8,000 chemical synapses, reveals a candidate motion detection circuit; such a circuit operates by combining displaced visual inputs, an operation consistent with correlation based motion detection. Three papers in this issue of Nature use the retina as a model for mapping neuronal circuits from the level of individual synaptic contacts to the long-range scale of dendritic interactions. Helmstaedter et al. used electron microscopy to map a mammalian retinal circuit of close to a thousand neurons. The work reveals a new type of retinal bipolar neuron and suggests functional mechanisms for known visual computations. The other two groups study the detection of visual motion in the Drosophila visual system — a classic neural computation model. Takemura et al. used semi-automated electron microscopy to reconstruct the basic connectome (8,637 chemical synapses among 379 neurons) of Drosophila's optic medulla. Their results reveal a candidate motion detection circuit with a wiring plan consistent with direction selectivity. Maisak et al. used calcium imaging to show that T4 and T5 neurons are divided into specific subpopulations responding to motion in four cardinal directions, and are specific to 'ON' versus 'OFF' edges, respectively.

Published

2013

3. Minimizing Manual Image Segmentation Turn-Around Time for Neuronal Reconstruction by Embracing Uncertainty

Author

Mathew A. Saunders, Stephen M. Plaza, and Louis K. Scheffer

Subjects

Similarity (geometry), Computer science, Image Processing, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, lcsh:Medicine, Scale-space segmentation, Pattern Recognition, Automated, Visual processing, Segmentation, Engineering, Molecular Cell Biology, Morphogenesis, Image Processing, Computer-Assisted, Animals, Humans, Computer vision, lcsh:Science, Biology, Neurons, Ground truth, Multidisciplinary, Neuronal Morphology, Segmentation-based object categorization, business.industry, lcsh:R, Probabilistic logic, Uncertainty, Computational Biology, Image segmentation, Models, Theoretical, Cellular Neuroscience, Computer Science, Signal Processing, lcsh:Q, Artificial intelligence, Cellular Types, business, Algorithms, Research Article, Developmental Biology, Neuroscience

Abstract

The ability to automatically segment an image into distinct regions is a critical aspect in many visual processing applications. Because inaccuracies often exist in automatic segmentation, manual segmentation is necessary in some application domains to correct mistakes, such as required in the reconstruction of neuronal processes from microscopic images. The goal of the automated segmentation tool is traditionally to produce the highest-quality segmentation, where quality is measured by the similarity to actual ground truth, so as to minimize the volume of manual correction necessary. Manual correction is generally orders-of-magnitude more time consuming than automated segmentation, often making handling large images intractable. Therefore, we propose a more relevant goal: minimizing the turn-around time of automated/manual segmentation while attaining a level of similarity with ground truth. It is not always necessary to inspect every aspect of an image to generate a useful segmentation. As such, we propose a strategy to guide manual segmentation to the most uncertain parts of segmentation. Our contributions include 1) a probabilistic measure that evaluates segmentation without ground truth and 2) a methodology that leverages these probabilistic measures to significantly reduce manual correction while maintaining segmentation quality.

Published

2012