Optimizing the Timing and Composition of Therapeutic Phage Cocktails: A Control-Theoretic Approach

Overview

Journal Bull Math Biol

Publisher Springer

Specialties Biology
Public Health

Date 2020 Jun 14

PMID 32533350

Citations 10

Authors

Guanlin Li

Chung Yin Leung

Yorai Wardi

Laurent Debarbieux

Joshua S Weitz

Affiliations

Soon will be listed here.

Abstract

Viruses that infect bacteria, i.e., bacteriophage or 'phage,' are increasingly considered as treatment options for the control and clearance of bacterial infections, particularly as compassionate use therapy for multi-drug-resistant infections. In practice, clinical use of phage often involves the application of multiple therapeutic phage, either together or sequentially. However, the selection and timing of therapeutic phage delivery remains largely ad hoc. In this study, we evaluate principles underlying why careful application of multiple phage (i.e., a 'cocktail') might lead to therapeutic success in contrast to the failure of single-strain phage therapy to control an infection. First, we use a nonlinear dynamics model of within-host interactions to show that a combination of fast intra-host phage decay, evolution of phage resistance amongst bacteria, and/or compromised immune response might limit the effectiveness of single-strain phage therapy. To resolve these problems, we combine dynamical modeling of phage, bacteria, and host immune cell populations with control-theoretic principles (via optimal control theory) to devise evolutionarily robust phage cocktails and delivery schedules to control the bacterial populations. Our numerical results suggest that optimal administration of single-strain phage therapy may be sufficient for curative outcomes in immunocompetent patients, but may fail in immunodeficient hosts due to phage resistance. We show that optimized treatment with a two-phage cocktail that includes a counter-resistant phage can restore therapeutic efficacy in immunodeficient hosts.

Citing Articles

Multi-strain phage induced clearance of bacterial infections.

Marchi J, Minh C, Debarbieux L, Weitz J PLoS Comput Biol. 2025; 21(2):e1012793.

PMID: 39903766 PMC: 11828373. DOI: 10.1371/journal.pcbi.1012793.

Multi-strain phage induced clearance of bacterial infections.

Marchi J, Minh C, Debarbieux L, Weitz J bioRxiv. 2024; .

PMID: 39282405 PMC: 11398464. DOI: 10.1101/2024.09.07.611814.

Phages enhance both phytopathogen density control and rhizosphere microbiome suppressiveness.

Wang X, Wang S, Huang M, He Y, Guo S, Yang K mBio. 2024; 15(6):e0301623.

PMID: 38780276 PMC: 11237578. DOI: 10.1128/mbio.03016-23.

The role of rhizosphere phages in soil health.

Wang X, Tang Y, Yue X, Wang S, Yang K, Xu Y FEMS Microbiol Ecol. 2024; 100(5).

PMID: 38678007 PMC: 11065364. DOI: 10.1093/femsec/fiae052.

Phage-host-immune system dynamics in bacteriophage therapy: basic principles and mathematical models.

Chae D Transl Clin Pharmacol. 2024; 31(4):167-190.

PMID: 38196997 PMC: 10772058. DOI: 10.12793/tcp.2023.31.e17.

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