Using Chemical Reaction Kinetics to Predict Optimal Antibiotic Treatment Strategies

Wiesch, Pia Abel zur; Clarelli, Fabrizio; Cohen, Ted

doi:10.1371/journal.pcbi.1005321

Cited by 18 publications

(20 citation statements)

References 67 publications

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“…Qualitatively, this means that the MIC is linear with KD when keeping all other parameters constant. This is consistent with our previous finding when deriving the MIC from drug-target binding alone in a very simplified model [13].…”

Section: Estimating the Mic Without Data On Binding Ratessupporting

confidence: 93%

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Drug-target binding quantitatively predicts optimal antibiotic dose levels

Clarelli

Palmer

Singh

et al. 2018

Preprint

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Antibiotic treatment may be compromised by the sporadic appearance and selection of drug resistant mutants during therapy. Identifying optimal dosing strategies for treating bacterial infections that minimize the risk of resistance is difficult, and improving dosing guidelines usually requires long and costly in vitro and in vivo experimentation. Previously, we proposed a mathematical model that links bacterial population biology with chemical reaction kinetics and demonstrated that this model had high predictive and explanatory power for antibiotic pharmacodynamics. Here, we extend our model to incorporate several distinct molecular mechanisms of resistance, e.g. altered drug-target affinity or target molecule content, to explore the how these mechanisms affect the risk of acquired resistance during treatment.Our model is based on a system of partial and ordinary differential equations. The central assumption encoded in the model is that bacterial growth declines (and/or bacterial kill rate increases) as the fraction of bound antibiotic target molecules within the bacterium increases. We use experimental data from E. coli exposed to ciprofloxacin and ampicillin to estimate the dependence of bacterial growth and death on the fraction of bound target molecules and to calibrate our model. We then predict how several alternative molecular mechanisms of resistance should affect bacterial growth and compare these predictions with data from experimentallymanipulated bacteria with varying target molecule content. Finally, we use our model to estimate antibiotic susceptibility for different antibiotics that share similar mechanisms of action but differ in their drug-target affinity.Our extended model offers a novel approach for predicting how resistance will evolve during therapy and provides a framework for generating new testable hypotheses about how the risk of resistance depends on the molecular mechanism of resistance.All rights reserved. No reuse allowed without permission.

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Section: Estimating the Mic Without Data On Binding Ratessupporting

confidence: 93%

“…To include this effect in our model, we modify the term of drug-target dissociation. In the equation describing antibiotic concentration, the unbinding rate kr=0, while, in the bacteria equation, we substitute the dissociation rate kr with the deacetylation rate ka, see [13].…”

Section: Description Of Beta-lactam Actionmentioning

confidence: 99%

Drug-target binding quantitatively predicts optimal antibiotic dose levels

Clarelli

Palmer

Singh

et al. 2018

Preprint

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“…Here, the assumption of equivalent receptors (assumption 6 on the list in "Traditional pharmacodynamic models") is invalid, because the same number of bound targets, combined differently, can have different outcomes. [7,34]). However, the modeling approach can be limited due to lack of knowledge on the specific mechanisms.…”

Section: Models Describing Multimer Targetsmentioning

confidence: 99%

“…The unspecific binding rate is denoted as k u,f and the unspecific dissociation rate as k u,r . This model can be expressed as follows [7]:…”

Section: Models Describing Multimer Targetsmentioning

confidence: 99%

“…Over the last 50 years, mathematical models describing drug pharmacokinetics (PK) and pharmacodynamics (PD) developed from the first concepts of simple relationships between drug concentration and its effects in the 1960 s [1][2][3][4][5] to advanced models that substantially improve our comprehension of the drug action mechanisms [6][7][8][9][10]. Advances in computational power and the improved accuracy and availability of experimental data have further fuelled model development.…”

Section: Introductionmentioning

confidence: 99%

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Multi-scale modeling of drug binding kinetics to predict drug efficacy

Clarelli

Liang

Martinecz

et al. 2019

Cell. Mol. Life Sci.

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Optimizing drug therapies for any disease requires a solid understanding of pharmacokinetics (the drug concentration at a given time point in different body compartments) and pharmacodynamics (the effect a drug has at a given concentration). Mathematical models are frequently used to infer drug concentrations over time based on infrequent sampling and/or in inaccessible body compartments. Models are also used to translate drug action from in vitro to in vivo conditions or from animal models to human patients. Recently, mathematical models that incorporate drug-target binding and subsequent downstream responses have been shown to advance our understanding and increase predictive power of drug efficacy predictions. We here discuss current approaches of modeling drug binding kinetics that aim at improving model-based drug development in the future. This in turn might aid in reducing the large number of failed clinical trials.

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