Article ? AI-assigned paper type based on the abstract. Classification may not be perfect — flag errors using the feedback button. Tier 2 ? Original research — experimental, observational, or case-control study. Direct primary evidence. Food & Water Human Health Effects Policy & Risk Sign in to save

Deep <scp>learning‐enabled</scp> imaging flow cytometry for <scp>high‐speed</scp><i>Cryptosporidium</i> and <i>Giardia</i> detection

Cytometry Part A 2021 29 citations ? Citation count from OpenAlex, updated daily. May differ slightly from the publisher's own count. Score: 50 ? 0–100 AI score estimating relevance to the microplastics field. Papers below 30 are filtered from public browse.

Shaobo Luo, Shaobo Luo, Shaobo Luo, Ahmed Elsayed, Shaobo Luo, Shaobo Luo, Shaobo Luo, Yuzhi Shi, Kim Truc Nguyen, Bình Thị Thanh Nguyễn, Kim Truc Nguyen, Xiaohong Zhou, Xiaohong Zhou, Yuzhi Shi, Bình Thị Thanh Nguyễn, Tarik Bourouina, Tarik Bourouina, Tarik Bourouina, Shilun Feng, Shilun Feng, Yuzhi Shi, Yuzhi Shi, Shilun Feng, Yuzhi Shi, Yuzhi Shi, Tarik Bourouina, Bihan Wen, Tarik Bourouina, Ahmed Elsayed, Ahmed Elsayed, Yi Zhang, Xiaohong Zhou, A. Q. Liu Bình Thị Thanh Nguyễn, Bình Thị Thanh Nguyễn, Giovanni Chierchia, Xiaohong Zhou, Xiaohong Zhou, Tarik Bourouina, Giovanni Chierchia, Shaobo Luo, Bihan Wen, Hugues Talbot, Hugues Talbot, Shaobo Luo, Giovanni Chierchia, Xiaohong Zhou, Bình Thị Thanh Nguyễn, Tarik Bourouina, Tarik Bourouina, Bình Thị Thanh Nguyễn, A. Q. Liu Xudong Jiang, Hugues Talbot, Xudong Jiang, A. Q. Liu Tarik Bourouina, A. Q. Liu Tarik Bourouina, Xudong Jiang, A. Q. Liu

Summary

Researchers developed a deep learning-enabled imaging flow cytometry system that detects Cryptosporidium and Giardia in drinking water with >99.6% classification accuracy and sensitivity of 97.4%, processing 346 frames per second and outperforming existing methods.

Body Systems

Nervous

Study Type Environmental

Imaging flow cytometry has become a popular technology for bioparticle image analysis because of its capability of capturing thousands of images per second. Nevertheless, the vast number of images generated by imaging flow cytometry imposes great challenges for data analysis especially when the species have similar morphologies. In this work, we report a deep learning-enabled high-throughput system for predicting Cryptosporidium and Giardia in drinking water. This system combines imaging flow cytometry and an efficient artificial neural network called MCellNet, which achieves a classification accuracy >99.6%. The system can detect Cryptosporidium and Giardia with a sensitivity of 97.37% and a specificity of 99.95%. The high-speed analysis reaches 346 frames per second, outperforming the state-of-the-art deep learning algorithm MobileNetV2 in speed (251 frames per second) with a comparable classification accuracy. The reported system empowers rapid, accurate, and high throughput bioparticle detection in clinical diagnostics, environmental monitoring and other potential biosensing applications.

Read via DOI Download PDF

Share this paper

Post Share Share Pin Email