Development of a Multicompartment Permeability‐Limited Lung PBPK Model and Its Application in Predicting Pulmonary Pharmacokinetics of Antituberculosis Drugs

Gaohua, Lu; Wedagedera, J. R.; Small, Ben G; Almond, Lisa; Romero, Klaus; Hermann, David; Hanna, Debra; Jamei, Masoud; Gardner, Iain

doi:10.1002/psp4.12034

Cited by 67 publications

(82 citation statements)

References 48 publications

(115 reference statements)

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“…In the model, the lung compartment is connected to the venous compartment and returns to the arterial compartment (Fig. 2), as suggested previously in physiologically based pharmacokinetic models (24)(25)(26). Initially, lung data were modeled as a single compartment, but this approach resulted in a poor fit.…”

Section: Poppk Of Ciprofloxacin In Biofilm Pneumoniamentioning

confidence: 99%

Population Pharmacokinetic Modeling as a Tool To Characterize the Decrease in Ciprofloxacin Free Interstitial Levels Caused by Pseudomonas aeruginosa Biofilm Lung Infection in Wistar Rats

Torres

Helfer

Bernardes

et al. 2017

Antimicrob Agents Chemother

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Biofilm formation plays an important role in the persistence of pulmonary infections, for example, in cystic fibrosis patients. So far, little is known about the antimicrobial lung disposition in biofilm-associated pneumonia. This study aimed to evaluate, by microdialysis, ciprofloxacin (CIP) penetration into the lungs of healthy and Pseudomonas aeruginosa biofilm-infected rats and to develop a comprehensive model to describe the CIP disposition under both conditions. P. aeruginosa was immobilized into alginate beads and intratracheally inoculated 14 days before CIP administration (20 mg/kg of body weight). Plasma and microdialysate were sampled from different animal groups, and the observations were evaluated by noncompartmental analysis (NCA) and population pharmacokinetic (popPK) analysis. The final model that successfully described all data consisted of an arterial and a venous central compartment and two peripheral distribution compartments, and the disposition in the lung was modeled as a two-compartment model structure linked to the venous compartment. Plasma clearance was approximately 32% lower in infected animals, leading to a significantly higher level of plasma CIP exposure (area under the concentration-time curve from time zero to infinity, 27.3 Ϯ 12.1 g · h/ml and 13.3 Ϯ 3.5 g · h/ml in infected and healthy rats, respectively). Despite the plasma exposure, infected animals showed a four times lower tissue concentration/plasma concentration ratio (lung penetration factor ϭ 0.44 and 1.69 in infected and healthy rats, respectively), and lung clearance (CL lung ) was added to the model for these animals (CL lung ϭ 0.643 liters/h/kg) to explain the lower tissue concentrations. Our results indicate that P. aeruginosa biofilm infection reduces the CIP free interstitial lung concentrations and increases plasma exposure, suggesting that plasma concentrations alone are not a good surrogate of lung concentrations.

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Section: Poppk Of Ciprofloxacin In Biofilm Pneumoniamentioning

confidence: 99%

Population Pharmacokinetic Modeling as a Tool To Characterize the Decrease in Ciprofloxacin Free Interstitial Levels Caused by Pseudomonas aeruginosa Biofilm Lung Infection in Wistar Rats

Torres

Helfer

Bernardes

et al. 2017

Antimicrob Agents Chemother

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“…Because these compounds are basic, they may accumulate in the acidic compartments of phagocytes within AM cells . Supporting this assumption, a previously published PBPK model used sensitivity analysis to show that decreasing the pH in ELF may account for the underprediction of basic macrolide drugs in ELF . The presence of drug transporters, such as P‐gp, in the lung epithelial cells has also been postulated to cause increased distribution of macrolides into intrapulmonary fluid .…”

Section: Discussionmentioning

confidence: 98%

“…8 Supporting this assumption, a previously published PBPK model used sensitivity analysis to show that decreasing the pH in ELF may account for the underprediction of basic macrolide drugs in ELF. 37 The presence of drug transporters, such as P-gp, in the lung epithelial cells has also been postulated to cause increased distribution of macrolides into intrapulmonary fluid. 38,39 Finally, lysis of AM cells in the collected bronchoalveolar lavage fluid, and other technical errors in the measurement Figure 4 Population simulations for plasma concentrations for the 800 mg on day 1 followed by 400 mg orally daily regimen for the phase I population in healthy adults (a) and the phase II population in patients with community-acquired bacterial pneumonia (b).…”

Section: Discussionmentioning

confidence: 99%

Development of an Adult Physiologically Based Pharmacokinetic Model of Solithromycin in Plasma and Epithelial Lining Fluid

Salerno

Edginton

Cohen‐Wolkowiez

et al. 2017

CPT Pharmacom & Syst Pharma

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Solithromycin is a fluoroketolide antibiotic under investigation for community‐acquired bacterial pneumonia (CABP). We developed a whole‐body physiologically based pharmacokinetic (PBPK) model for solithromycin in adults using PK‐Sim and MoBi version 6.2, which incorporated time‐dependent CYP3A4 auto‐inhibition. The model was developed and evaluated using plasma and epithelial lining fluid (ELF) concentration data from 100 healthy subjects and 22 patients with CABP (1,966 plasma, 30 ELF samples). We performed population simulations and calculated the number of observations falling outside the 90% prediction interval. For the oral regimen (800 mg on day 1 and 400 mg daily on days 2–5) that was evaluated in phase III studies, 11% and 23% of observations from healthy adults fell outside the 90% prediction interval for plasma and ELF, respectively. This regimen should be effective because ≥97% of simulated adults achieved area under the concentration vs. time curve (AUC) to minimum inhibitory concentration ratios associated with a log10 colony forming unit reduction in ELF.

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“…Tissue distribution of antibiotics may be predicted using physiologically-based pharmacokinetic (PBPK) modelling [26,27]. Recently, a PBPK model incorporating a multi-compartment permeability-limited lung model was used to simulate the pharmacokinetics of anti-tuberculosis agents in plasma, lungs and its sub-compartments where the mycobacteria reside in the host [28]. This model also provides a framework for predicting the lung concentrations of novel anti-tuberculosis agents.…”

Section: Pharmacokineticsmentioning

confidence: 99%

Translational PK/PD of anti-infective therapeutics

Rathi

Lee

2016

Drug Discovery Today: Technologies

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Translational PK/PD modeling has emerged as a critical technique for quantitative analysis of the relationship between dose, exposure and response of antibiotics. By combining model components for pharmacokinetics, bacterial growth kinetics and concentration-dependent drug effects, these models are able to quantitatively capture and simulate the complex interplay between antibiotic, bacterium and host organism. Fine-tuning of these basic model structures allows to further account for complicating factors such as resistance development, combination therapy, or host responses. With this tool set at hand, mechanism-based PK/PD modeling and simulation allows to develop optimal dosing regimens for novel and established antibiotics for maximum efficacy and minimal resistance development.

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Development of a Multicompartment Permeability‐Limited Lung PBPK Model and Its Application in Predicting Pulmonary Pharmacokinetics of Antituberculosis Drugs

Cited by 67 publications

References 48 publications

Population Pharmacokinetic Modeling as a Tool To Characterize the Decrease in Ciprofloxacin Free Interstitial Levels Caused by Pseudomonas aeruginosa Biofilm Lung Infection in Wistar Rats

Population Pharmacokinetic Modeling as a Tool To Characterize the Decrease in Ciprofloxacin Free Interstitial Levels Caused by Pseudomonas aeruginosa Biofilm Lung Infection in Wistar Rats

Development of an Adult Physiologically Based Pharmacokinetic Model of Solithromycin in Plasma and Epithelial Lining Fluid

Translational PK/PD of anti-infective therapeutics

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