P21 Development of deep learning models for Sub-Cellular Fluctuation Imaging (SCFI): a 30 min antibiotic susceptibility test for urinary tract infections

Author:

Rama S1,Antognozzi M2,Szeremeta W2,Phonrat K2,Eley A2,Bermingham C2,Kyriakides M1,Newman H1,Bonney-Bhandal K1,Preece J1,Dorh N1,Dorh J1

Affiliation:

1. FluoretiQ Limited, Unit DX , St Philips Central, Albert Road, Bristol BS2 0XJ , UK

2. School of Physics, University of Bristol , Tyndall Avenue, Bristol, BS8 1TL , UK

Abstract

Abstract Background We have developed a phenotypic and label-free antibiotic susceptibility test (AST) termed Sub-Cellular Fluctuation Imaging (SCFI) to address rising rates of antimicrobial resistance.1 SCFI is an advanced machine-learning enabled microscope that monitors real-time fluctuations of bacterial cell membrane in response to antibiotics. By quantifying changes in magnitude and location of light scattering caused by subcellular movement, we can detect metabolic changes that occur when bacteria are challenged with antibiotics.2–5 Here, we show that improvements to SCFI’s deep-learning models can correctly classify metabolic cell states for Escherichia coli (exponential, stationary, dead) and determine cell states for UTI-related species (E. coli, Klebsiella pneumoniae and Proteus mirabilis) with front-line antibiotics (trimethoprim and nitrofurantoin). Methods A total of 100 μL per sample is introduced to microfluidic flow chambers and immobilized using a species-specific antibody coating for 10 min. The bacterial suspension is removed, washed (to minimize non-bound cells) and incubated with 100 μL of MHB broth containing either a treated (with antibiotic) or untreated (without antibiotic) condition for 30 min. Images are captured at a laser intensity of 20 Hz for 20 s, for ≥50 individual bacterial cells per test. Convolutional neural networks (CNN) were developed to enable classifications of bacteriostatic antibiotics (trimethoprim and methicillin) on E. coli, K. pneumoniae and P. mirabilis species to determine their respective performance metrics (sensitivity, specificity, PPV and NPV). Results CNN models were developed to successfully classify treated, untreated, resistant and susceptible bacterial conditions. All conditions were tested in triplicate (n=150 cells) and demonstrated high accuracy (sensitivity 88%–98%, specificity 88%–99%, PPV 88%–99% and NPV 88%–98%) when compared with known MICs. Conclusions In these experiments we successfully demonstrated rapid (30 min) and accurate (≥90%) classification of bacterial resistance states by deep learning techniques. These data also continue to support existing literature that SCFI is an AST that is agnostic to the antibiotic class and bacterial species used. This system is undergoing product development and will be translated into a bespoke hardware system for clinical and antibiotic research applications.

Publisher

Oxford University Press (OUP)

Subject

Microbiology (medical),Infectious Diseases,Immunology and Allergy,Microbiology,Immunology

Reference5 articles.

1. Global burden of antimicrobial resistance in 2019: a systematic analysis;Antimicrobial Resistance Collaborators;Lancet,2022

2. Imaging of sub-cellular fluctuations provides a rapid way to observe bacterial viability and response to antibiotics;Bermingham;bioRxiv,2018

3. Towards a fully automated scanning probe microscope for biomedical applications;Szeremeta;Sensors,2021

4. Rapid detection of bacterial resistance to antibiotics using AFM cantilevers as nanomechanical sensors;Longo;Nat Nanotechnol,2013

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