Minimizing treatment-induced emergence of antibiotic resistance in bacterial infections

Mathew Stracy; Olga Snitser; Idan Yelin; Yara Amer; Miriam Parizade; Rachel Katz; Galit Rimler; Tamar Wolf; Esma Herzel; Gideon Koren; Jacob Kuint; Betsy Foxman; Gabriel Chodick; Varda Shalev; Roy Kishony

doi:10.1126/science.abg9868

Minimizing treatment-induced emergence of antibiotic resistance in bacterial infections

Mathew Stracy, Olga Snitser, Idan Yelin, Yara Amer, Miriam Parizade, Rachel Katz, Galit Rimler, Tamar Wolf, Esma Herzel, Gideon Koren, Jacob Kuint, Betsy Foxman, Gabriel Chodick, Varda Shalev, Roy Kishony

Biology

Technion - Israel Institute of Technology

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

Abstract

Treatment of bacterial infections currently focuses on choosing an antibiotic that matches a pathogen’s susceptibility, with less attention paid to the risk that even susceptibility-matched treatments can fail as a result of resistance emerging in response to treatment. Combining whole-genome sequencing of 1113 pre- and posttreatment bacterial isolates with machine-learning analysis of 140,349 urinary tract infections and 7365 wound infections, we found that treatment-induced emergence of resistance could be predicted and minimized at the individual-patient level. Emergence of resistance was common and driven not by de novo resistance evolution but by rapid reinfection with a different strain resistant to the prescribed antibiotic. As most infections are seeded from a patient’s own microbiota, these resistance-gaining recurrences can be predicted using the patient’s past infection history and minimized by machine learning–personalized antibiotic recommendations, offering a means to reduce the emergence and spread of resistant pathogens.

Original language	English
Pages (from-to)	889-+
Number of pages	6
Journal	Science
Volume	375
Issue number	6583
DOIs	https://doi.org/10.1126/science.abg9868
State	Published - 25 Feb 2022

Keywords

Algorithms
Anti-Bacterial Agents/therapeutic use
Bacteria/drug effects
Bacterial Infections/drug therapy
Drug Resistance, Bacterial
Escherichia coli Infections/drug therapy
Female
Humans
Machine Learning
Male
Microbial Sensitivity Tests
Microbiota
Mutation
Reinfection/microbiology
Urinary Tract Infections/drug therapy
Whole Genome Sequencing
Wound Infection/drug therapy

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10.1126/science.abg9868

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title = "Minimizing treatment-induced emergence of antibiotic resistance in bacterial infections",

abstract = "Treatment of bacterial infections currently focuses on choosing an antibiotic that matches a pathogen{\textquoteright}s susceptibility, with less attention paid to the risk that even susceptibility-matched treatments can fail as a result of resistance emerging in response to treatment. Combining whole-genome sequencing of 1113 pre- and posttreatment bacterial isolates with machine-learning analysis of 140,349 urinary tract infections and 7365 wound infections, we found that treatment-induced emergence of resistance could be predicted and minimized at the individual-patient level. Emergence of resistance was common and driven not by de novo resistance evolution but by rapid reinfection with a different strain resistant to the prescribed antibiotic. As most infections are seeded from a patient{\textquoteright}s own microbiota, these resistance-gaining recurrences can be predicted using the patient{\textquoteright}s past infection history and minimized by machine learning–personalized antibiotic recommendations, offering a means to reduce the emergence and spread of resistant pathogens.",

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AU - Stracy, Mathew

AU - Snitser, Olga

AU - Yelin, Idan

AU - Amer, Yara

AU - Parizade, Miriam

AU - Katz, Rachel

AU - Rimler, Galit

AU - Wolf, Tamar

AU - Herzel, Esma

AU - Koren, Gideon

AU - Kuint, Jacob

AU - Foxman, Betsy

AU - Chodick, Gabriel

AU - Shalev, Varda

AU - Kishony, Roy

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AB - Treatment of bacterial infections currently focuses on choosing an antibiotic that matches a pathogen’s susceptibility, with less attention paid to the risk that even susceptibility-matched treatments can fail as a result of resistance emerging in response to treatment. Combining whole-genome sequencing of 1113 pre- and posttreatment bacterial isolates with machine-learning analysis of 140,349 urinary tract infections and 7365 wound infections, we found that treatment-induced emergence of resistance could be predicted and minimized at the individual-patient level. Emergence of resistance was common and driven not by de novo resistance evolution but by rapid reinfection with a different strain resistant to the prescribed antibiotic. As most infections are seeded from a patient’s own microbiota, these resistance-gaining recurrences can be predicted using the patient’s past infection history and minimized by machine learning–personalized antibiotic recommendations, offering a means to reduce the emergence and spread of resistant pathogens.

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KW - Humans

KW - Machine Learning

KW - Male

KW - Microbial Sensitivity Tests

KW - Microbiota

KW - Mutation

KW - Reinfection/microbiology

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KW - Whole Genome Sequencing

KW - Wound Infection/drug therapy

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M3 - مقالة

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JF - Science

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ER -

Minimizing treatment-induced emergence of antibiotic resistance in bacterial infections

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Keywords

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