The pharmacodynamic inoculum effect from the perspective of bacterial population modeling

Baeder, Desiree Y.; Rr, Regoes

doi:10.1101/550368

Cited by 3 publications

(5 citation statements)

References 50 publications

(193 reference statements)

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“…It is interesting to note that considerations extremely similar to those presented here, regarding a drug-target binding equilibrium and a threshold number of bound drug molecules per cell to cause killing or growth inhibition, have been demonstrated to be valid also for the IE of traditional antibiotics (e.g., oxacillin, ciprofloxacin, or gentamicin), including ionophores such as vancomycin (14,15,87). In addition, a plateau for the MIC values for inocula lower than 10 5 to 10 6 CFU/mL has been observed also for traditional antibiotics, irrespective of their mode of action (14,91,92), and this limiting value has by some authors been termed the single-cell MIC (91,92).…”

Section: Discussionmentioning

confidence: 56%

Inoculum effect of antimicrobial peptides

Loffredo

Savini

Bobone

et al. 2021

Proc. Natl. Acad. Sci. U.S.A.

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The activity of many antibiotics depends on the initial density of cells used in bacterial growth inhibition assays. This phenomenon, termed the inoculum effect, can have important consequences for the therapeutic efficacy of the drugs, because bacterial loads vary by several orders of magnitude in clinically relevant infections. Antimicrobial peptides are a promising class of molecules in the fight against drug-resistant bacteria because they act mainly by perturbing the cell membranes rather than by inhibiting intracellular targets. Here, we report a systematic characterization of the inoculum effect for this class of antibacterial compounds. Minimum inhibitory concentration values were measured for 13 peptides (including all-D enantiomers) and peptidomimetics, covering more than seven orders of magnitude in inoculated cell density. In most cases, the inoculum effect was significant for cell densities above the standard inoculum of 5 × 105 cells/mL, while for lower densities the active concentrations remained essentially constant, with values in the micromolar range. In the case of membrane-active peptides, these data can be rationalized by considering a simple model, taking into account peptide–cell association, and hypothesizing that a threshold number of cell-bound peptide molecules is required in order to cause bacterial killing. The observed effect questions the clinical utility of activity and selectivity determinations performed at a fixed, standardized cell density. A routine evaluation of the dependence of the activity of antimicrobial peptides and peptidomimetics on the inoculum should be considered.

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Section: Discussionmentioning

confidence: 56%

Inoculum effect of antimicrobial peptides

Loffredo

Savini

Bobone

et al. 2021

Proc. Natl. Acad. Sci. U.S.A.

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“…Furthermore, the susceptibility of a pathogen population to antimicrobials can depend on the number of bacterial cells [159–161]. For both ABs [162] and AMPs [89, 159, 163–165], the efficacy of an antimicrobial decreases with increasing bacterial starting inoculum (called the ‘inoculum effect’), meaning that a higher number of bacterial cells increases the probability of survival and the potential for resistance evolution (, see Text S3 for details). The inoculum effect can, for example, be caused by the uptake of AB molecules into bacterial cells, which depletes them extracellularly [159].…”

Section: Phenotypic Resistancementioning

confidence: 99%

The pharmacokinetic–pharmacodynamic modelling framework as a tool to predict drug resistance evolution

et al. 2023

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Pharmacokinetic–pharmacodynamic (PKPD) models, which describe how drug concentrations change over time and how that affects pathogen growth, have proven highly valuable in designing optimal drug treatments aimed at bacterial eradication. However, the fast rise of antimicrobial resistance calls for increased focus on an additional treatment optimization criterion: avoidance of resistance evolution. We demonstrate here how coupling PKPD and population genetics models can be used to determine treatment regimens that minimize the potential for antimicrobial resistance evolution. Importantly, the resulting modelling framework enables the assessment of resistance evolution in response to dynamic selection pressures, including changes in antimicrobial concentration and the emergence of adaptive phenotypes. Using antibiotics and antimicrobial peptides as an example, we discuss the empirical evidence and intuition behind individual model parameters. We further suggest several extensions of this framework that allow a more comprehensive and realistic prediction of bacterial escape from antimicrobials through various phenotypic and genetic mechanisms.

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“…One explanation for this effect relates to the fact that the change in the drug availability after binding can be a function of the drug affinity. This effect can be explained by a kinetic model of binding-intuitively, drug molecules that are already bound to their targets cannot kill more bacteria [6,8].…”

Section: Inoculum Effectmentioning

confidence: 99%

“…Increased initial bacterial concentration can imply decreased antibiotic efficacy [6,8,43,44] Heterogeneous population The bacterial population can be heterogeneous, i.e. with different values in: [6]…”

Section: Conflict Of Interestmentioning

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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The pharmacodynamic inoculum effect from the perspective of bacterial population modeling

Cited by 3 publications

References 50 publications

Inoculum effect of antimicrobial peptides

Inoculum effect of antimicrobial peptides

The pharmacokinetic–pharmacodynamic modelling framework as a tool to predict drug resistance evolution

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

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