Your search keyword '"Shemonti, AS"' showing total 2 results

1. High-throughput segmentation of unmyelinated axons by deep learning.

Author

Plebani E, Biscola NP, Havton LA, Rajwa B, Shemonti AS, Jaffey D, Powley T, Keast JR, Lu KH, and Dundar MM

Subjects

Animals, Rats, Deep Learning, Image Processing, Computer-Assisted methods, Microscopy, Electron, Transmission, Nerve Fibers, Unmyelinated ultrastructure

Abstract

Axonal characterizations of connectomes in healthy and disease phenotypes are surprisingly incomplete and biased because unmyelinated axons, the most prevalent type of fibers in the nervous system, have largely been ignored as their quantitative assessment quickly becomes unmanageable as the number of axons increases. Herein, we introduce the first prototype of a high-throughput processing pipeline for automated segmentation of unmyelinated fibers. Our team has used transmission electron microscopy images of vagus and pelvic nerves in rats. All unmyelinated axons in these images are individually annotated and used as labeled data to train and validate a deep instance segmentation network. We investigate the effect of different training strategies on the overall segmentation accuracy of the network. We extensively validate the segmentation algorithm as a stand-alone segmentation tool as well as in an expert-in-the-loop hybrid segmentation setting with preliminary, albeit remarkably encouraging results. Our algorithm achieves an instance-level [Formula: see text] score of between 0.7 and 0.9 on various test images in the stand-alone mode and reduces expert annotation labor by 80% in the hybrid setting. We hope that this new high-throughput segmentation pipeline will enable quick and accurate characterization of unmyelinated fibers at scale and become instrumental in significantly advancing our understanding of connectomes in both the peripheral and the central nervous systems., (© 2022. The Author(s).)

Published

2022

2. High-throughput segmentation of unmyelinated axons by deep learning

Author

Emanuele Plebani, Natalia P. Biscola, Leif A. Havton, Bartek Rajwa, Abida Sanjana Shemonti, Deborah Jaffey, Terry Powley, Janet R. Keast, Kun-Han Lu, and M. Murat Dundar

Subjects

Nerve Fibers, Unmyelinated, Multidisciplinary, Science, Article, Rats, Deep Learning, Microscopy, Electron, Transmission, Neurology, Image processing, Computational neuroscience, Machine learning, Image Processing, Computer-Assisted, Medicine, Animals, Neuroscience

Abstract

Axonal characterizations of connectomes in healthy and disease phenotypes are surprisingly incomplete and biased because unmyelinated axons, the most prevalent type of fibers in the nervous system, have largely been ignored as their quantitative assessment quickly becomes unmanageable as the number of axons increases. Herein, we introduce the first prototype of a high-throughput processing pipeline for automated segmentation of unmyelinated fibers. Our team has used transmission electron microscopy images of vagus and pelvic nerves in rats. All unmyelinated axons in these images are individually annotated and used as labeled data to train and validate a deep instance segmentation network. We investigate the effect of different training strategies on the overall segmentation accuracy of the network. We extensively validate the segmentation algorithm as a stand-alone segmentation tool as well as in an expert-in-the-loop hybrid segmentation setting with preliminary, albeit remarkably encouraging results. Our algorithm achieves an instance-level $$F_1$$ F 1 score of between 0.7 and 0.9 on various test images in the stand-alone mode and reduces expert annotation labor by 80% in the hybrid setting. We hope that this new high-throughput segmentation pipeline will enable quick and accurate characterization of unmyelinated fibers at scale and become instrumental in significantly advancing our understanding of connectomes in both the peripheral and the central nervous systems.

Published

2021