Simulation-Based Exploration of Quorum Sensing Triggered Resistance of Biofilms to Antibiotics

Maryam Ghasemi; Burkhard A. Hense; Hermann J. Eberl; Christina Kuttler

doi:10.1007/s11538-018-0433-3

Simulation-Based Exploration of Quorum Sensing Triggered Resistance of Biofilms to Antibiotics

Maryam Ghasemi, Burkhard A. Hense, Hermann J. Eberl, Christina Kuttler

Associate Professorship of Mathematics in Life Sciences

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

24 Scopus citations

Abstract

We present a mathematical model of biofilm response to antibiotics, controlled by a quorum sensing system that confers increased resistance. The model is a highly nonlinear system of partial differential equations that we investigate in computer simulations. Our results suggest that an adaptive, quorum sensing-controlled, mechanism to switch between modes of fast growth with little protection and protective modes of slow growth may confer benefits to biofilm populations. It enhances the formation of micro-niches in the inner regions of the biofilm in which bacteria are not easily reached by antibiotics. Whereas quorum sensing inhibitors can delay the onset of increased resistance, their advantage is lost after up-regulation. This emphasizes the importance of timing for treatment of biofilms with antibiotics.

Original language	English
Pages (from-to)	1736-1775
Number of pages	40
Journal	Bulletin of Mathematical Biology
Volume	80
Issue number	7
DOIs	https://doi.org/10.1007/s11538-018-0433-3
State	Published - 1 Jul 2018

Keywords

Antibiotics
Biofilm
Mathematical model
Nonlinear diffusion
Quorum sensing
Simulation

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10.1007/s11538-018-0433-3

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title = "Simulation-Based Exploration of Quorum Sensing Triggered Resistance of Biofilms to Antibiotics",

abstract = "We present a mathematical model of biofilm response to antibiotics, controlled by a quorum sensing system that confers increased resistance. The model is a highly nonlinear system of partial differential equations that we investigate in computer simulations. Our results suggest that an adaptive, quorum sensing-controlled, mechanism to switch between modes of fast growth with little protection and protective modes of slow growth may confer benefits to biofilm populations. It enhances the formation of micro-niches in the inner regions of the biofilm in which bacteria are not easily reached by antibiotics. Whereas quorum sensing inhibitors can delay the onset of increased resistance, their advantage is lost after up-regulation. This emphasizes the importance of timing for treatment of biofilms with antibiotics.",

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AU - Hense, Burkhard A.

AU - Eberl, Hermann J.

AU - Kuttler, Christina

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AB - We present a mathematical model of biofilm response to antibiotics, controlled by a quorum sensing system that confers increased resistance. The model is a highly nonlinear system of partial differential equations that we investigate in computer simulations. Our results suggest that an adaptive, quorum sensing-controlled, mechanism to switch between modes of fast growth with little protection and protective modes of slow growth may confer benefits to biofilm populations. It enhances the formation of micro-niches in the inner regions of the biofilm in which bacteria are not easily reached by antibiotics. Whereas quorum sensing inhibitors can delay the onset of increased resistance, their advantage is lost after up-regulation. This emphasizes the importance of timing for treatment of biofilms with antibiotics.

KW - Antibiotics

KW - Biofilm

KW - Mathematical model

KW - Nonlinear diffusion

KW - Quorum sensing

KW - Simulation

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Simulation-Based Exploration of Quorum Sensing Triggered Resistance of Biofilms to Antibiotics

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