Rapid Species Identification of Pathogenic Bacteria from a Minute Quantity Exploiting Three-dimensional Quantitative Phase Imaging and Artificial Neural Network

Overview

Journal Light Sci Appl

Publisher Springer Nature

Date 2022 Jun 23

PMID 35739098

Authors

Geon Kim

Daewoong Ahn

Minhee Kang

Jinho Park

DongHun Ryu

YoungJu Jo

Jinyeop Song

Jea Sung Ryu

Gunho Choi

Hyun Jung Chung

Kyuseok Kim

Doo Ryeon Chung

In Young Yoo

Hee Jae Huh

Hyun-Seok Min

Nam Yong Lee

YongKeun Park

Affiliations

Soon will be listed here.

Abstract

The healthcare industry is in dire need of rapid microbial identification techniques for treating microbial infections. Microbial infections are a major healthcare issue worldwide, as these widespread diseases often develop into deadly symptoms. While studies have shown that an early appropriate antibiotic treatment significantly reduces the mortality of an infection, this effective treatment is difficult to practice. The main obstacle to early appropriate antibiotic treatments is the long turnaround time of the routine microbial identification, which includes time-consuming sample growth. Here, we propose a microscopy-based framework that identifies the pathogen from single to few cells. Our framework obtains and exploits the morphology of the limited sample by incorporating three-dimensional quantitative phase imaging and an artificial neural network. We demonstrate the identification of 19 bacterial species that cause bloodstream infections, achieving an accuracy of 82.5% from an individual bacterial cell or cluster. This performance, comparable to that of the gold standard mass spectroscopy under a sufficient amount of sample, underpins the effectiveness of our framework in clinical applications. Furthermore, our accuracy increases with multiple measurements, reaching 99.9% with seven different measurements of cells or clusters. We believe that our framework can serve as a beneficial advisory tool for clinicians during the initial treatment of infections.

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