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Autori principali: Li, Yuzhu, Li, Hao, Chen, Weijie, O'Riordan, Keelan, Mani, Neha, Qi, Yuxuan, Liu, Tairan, Mani, Sridhar, Ozcan, Aydogan
Natura: Preprint
Pubblicazione: 2024
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Accesso online:https://arxiv.org/abs/2410.15229
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author Li, Yuzhu
Li, Hao
Chen, Weijie
O'Riordan, Keelan
Mani, Neha
Qi, Yuxuan
Liu, Tairan
Mani, Sridhar
Ozcan, Aydogan
author_facet Li, Yuzhu
Li, Hao
Chen, Weijie
O'Riordan, Keelan
Mani, Neha
Qi, Yuxuan
Liu, Tairan
Mani, Sridhar
Ozcan, Aydogan
contents Distinguishing between swarming and swimming, the two principal forms of bacterial movement, holds significant conceptual and clinical relevance. This is because bacteria that exhibit swarming capabilities often possess unique properties crucial to the pathogenesis of infectious diseases and may also have therapeutic potential. Here, we report a deep learning-based swarming classifier that rapidly and autonomously predicts swarming probability using a single blurry image. Compared with traditional video-based, manually-processed approaches, our method is particularly suited for high-throughput environments and provides objective, quantitative assessments of swarming probability. The swarming classifier demonstrated in our work was trained on Enterobacter sp. SM3 and showed good performance when blindly tested on new swarming (positive) and swimming (negative) test images of SM3, achieving a sensitivity of 97.44% and a specificity of 100%. Furthermore, this classifier demonstrated robust external generalization capabilities when applied to unseen bacterial species, such as Serratia marcescens DB10 and Citrobacter koseri H6. It blindly achieved a sensitivity of 97.92% and a specificity of 96.77% for DB10, and a sensitivity of 100% and a specificity of 97.22% for H6. This competitive performance indicates the potential to adapt our approach for diagnostic applications through portable devices or even smartphones. This adaptation would facilitate rapid, objective, on-site screening for bacterial swarming motility, potentially enhancing the early detection and treatment assessment of various diseases, including inflammatory bowel diseases (IBD) and urinary tract infections (UTI).
format Preprint
id arxiv_https___arxiv_org_abs_2410_15229
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Deep Learning-based Detection of Bacterial Swarm Motion Using a Single Image
Li, Yuzhu
Li, Hao
Chen, Weijie
O'Riordan, Keelan
Mani, Neha
Qi, Yuxuan
Liu, Tairan
Mani, Sridhar
Ozcan, Aydogan
Computer Vision and Pattern Recognition
Machine Learning
Applied Physics
Medical Physics
Distinguishing between swarming and swimming, the two principal forms of bacterial movement, holds significant conceptual and clinical relevance. This is because bacteria that exhibit swarming capabilities often possess unique properties crucial to the pathogenesis of infectious diseases and may also have therapeutic potential. Here, we report a deep learning-based swarming classifier that rapidly and autonomously predicts swarming probability using a single blurry image. Compared with traditional video-based, manually-processed approaches, our method is particularly suited for high-throughput environments and provides objective, quantitative assessments of swarming probability. The swarming classifier demonstrated in our work was trained on Enterobacter sp. SM3 and showed good performance when blindly tested on new swarming (positive) and swimming (negative) test images of SM3, achieving a sensitivity of 97.44% and a specificity of 100%. Furthermore, this classifier demonstrated robust external generalization capabilities when applied to unseen bacterial species, such as Serratia marcescens DB10 and Citrobacter koseri H6. It blindly achieved a sensitivity of 97.92% and a specificity of 96.77% for DB10, and a sensitivity of 100% and a specificity of 97.22% for H6. This competitive performance indicates the potential to adapt our approach for diagnostic applications through portable devices or even smartphones. This adaptation would facilitate rapid, objective, on-site screening for bacterial swarming motility, potentially enhancing the early detection and treatment assessment of various diseases, including inflammatory bowel diseases (IBD) and urinary tract infections (UTI).
title Deep Learning-based Detection of Bacterial Swarm Motion Using a Single Image
topic Computer Vision and Pattern Recognition
Machine Learning
Applied Physics
Medical Physics
url https://arxiv.org/abs/2410.15229