Deep Learning-Based Culture-Free Bacteria Detection in Urine Using Large-Volume Microscopy

Rafael Iriya; Brandyn Braswell; Manni Mo; Fenni Zhang; Shelley E. Haydel; Shaopeng Wang

doi:10.3390/bios14020089

Deep Learning-Based Culture-Free Bacteria Detection in Urine Using Large-Volume Microscopy

Rafael Iriya, Brandyn Braswell, Manni Mo, Fenni Zhang, Shelley E. Haydel, Shaopeng Wang

Research output: Contribution to journal › Article › peer-review

Abstract

Bacterial infections, increasingly resistant to common antibiotics, pose a global health challenge. Traditional diagnostics often depend on slow cell culturing, leading to empirical treatments that accelerate antibiotic resistance. We present a novel large-volume microscopy (LVM) system for rapid, point-of-care bacterial detection. This system, using low magnification (1–2×), visualizes sufficient sample volumes, eliminating the need for culture-based enrichment. Employing deep neural networks, our model demonstrates superior accuracy in detecting uropathogenic Escherichia coli compared to traditional machine learning methods. Future endeavors will focus on enriching our datasets with mixed samples and a broader spectrum of uropathogens, aiming to extend the applicability of our model to clinical samples.

Original language	English (US)
Article number	89
Journal	Biosensors
Volume	14
Issue number	2
DOIs	https://doi.org/10.3390/bios14020089
State	Published - Feb 2024

Keywords

CNN
LVM
UTI diagnostics
bacteria detection
deep learning
light scattering microscopy

ASJC Scopus subject areas

Analytical Chemistry
Biotechnology
Biomedical Engineering
Instrumentation
Engineering (miscellaneous)
Clinical Biochemistry

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10.3390/bios14020089

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title = "Deep Learning-Based Culture-Free Bacteria Detection in Urine Using Large-Volume Microscopy",

abstract = "Bacterial infections, increasingly resistant to common antibiotics, pose a global health challenge. Traditional diagnostics often depend on slow cell culturing, leading to empirical treatments that accelerate antibiotic resistance. We present a novel large-volume microscopy (LVM) system for rapid, point-of-care bacterial detection. This system, using low magnification (1–2×), visualizes sufficient sample volumes, eliminating the need for culture-based enrichment. Employing deep neural networks, our model demonstrates superior accuracy in detecting uropathogenic Escherichia coli compared to traditional machine learning methods. Future endeavors will focus on enriching our datasets with mixed samples and a broader spectrum of uropathogens, aiming to extend the applicability of our model to clinical samples.",

keywords = "CNN, LVM, UTI diagnostics, bacteria detection, deep learning, light scattering microscopy",

author = "Rafael Iriya and Brandyn Braswell and Manni Mo and Fenni Zhang and Haydel, {Shelley E.} and Shaopeng Wang",

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T1 - Deep Learning-Based Culture-Free Bacteria Detection in Urine Using Large-Volume Microscopy

AU - Iriya, Rafael

AU - Braswell, Brandyn

AU - Mo, Manni

AU - Zhang, Fenni

AU - Haydel, Shelley E.

AU - Wang, Shaopeng

PY - 2024/2

Y1 - 2024/2

N2 - Bacterial infections, increasingly resistant to common antibiotics, pose a global health challenge. Traditional diagnostics often depend on slow cell culturing, leading to empirical treatments that accelerate antibiotic resistance. We present a novel large-volume microscopy (LVM) system for rapid, point-of-care bacterial detection. This system, using low magnification (1–2×), visualizes sufficient sample volumes, eliminating the need for culture-based enrichment. Employing deep neural networks, our model demonstrates superior accuracy in detecting uropathogenic Escherichia coli compared to traditional machine learning methods. Future endeavors will focus on enriching our datasets with mixed samples and a broader spectrum of uropathogens, aiming to extend the applicability of our model to clinical samples.

AB - Bacterial infections, increasingly resistant to common antibiotics, pose a global health challenge. Traditional diagnostics often depend on slow cell culturing, leading to empirical treatments that accelerate antibiotic resistance. We present a novel large-volume microscopy (LVM) system for rapid, point-of-care bacterial detection. This system, using low magnification (1–2×), visualizes sufficient sample volumes, eliminating the need for culture-based enrichment. Employing deep neural networks, our model demonstrates superior accuracy in detecting uropathogenic Escherichia coli compared to traditional machine learning methods. Future endeavors will focus on enriching our datasets with mixed samples and a broader spectrum of uropathogens, aiming to extend the applicability of our model to clinical samples.

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KW - bacteria detection

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KW - light scattering microscopy

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Deep Learning-Based Culture-Free Bacteria Detection in Urine Using Large-Volume Microscopy

Abstract

Keywords

ASJC Scopus subject areas

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