Sequential Population Pharmacokinetic Modeling of Lopinavir and Ritonavir in Healthy Volunteers and Assessment of Different Dosing Strategies

Dickinson, Laura; Boffito, Marta; Back, David; Else, Laura; Hentig, Nils von; Davies, Geraint R.; Khoo, Saye; Pozniak, Anton; Moyle, Graeme; Aarons, Leon

doi:10.1128/aac.00887-10

Cited by 23 publications

(32 citation statements)

References 13 publications

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Section: Discussionsupporting

confidence: 90%

“…RTV disposition was also best described by our one‐compartmental model with first‐order absorption and elimination, consistent with previous studies . Considering the values of k a reported for RTV when coadministered with LPV or darunavir (DRV) and our results, the RTV k a is not likely to be affected by the coadministered PI. However, in the RTV‐boosted ATV regimens in the present study, CL/F RTV was almost half of the value reported for this parameter in RTV‐boosted LPV or DRV regimens, and therefore, plasma concentrations were higher .…”

Section: Discussionsupporting

confidence: 90%

“…Considering the values of k a reported for RTV when coadministered with LPV or darunavir (DRV) and our results, the RTV k a is not likely to be affected by the coadministered PI. However, in the RTV‐boosted ATV regimens in the present study, CL/F RTV was almost half of the value reported for this parameter in RTV‐boosted LPV or DRV regimens, and therefore, plasma concentrations were higher . The difference can probably be attributed to the effect of LPV and DRV as inducers of several CYP isoforms ; ATV, on the other hand, acts only as an inhibitor.…”

Section: Discussionsupporting

confidence: 50%

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Population pharmacokinetic modelling of the changes in atazanavir plasma clearance caused by ritonavir plasma concentrations in HIV‐1 infected patients

Moltó

Estévez

Miranda

et al. 2016

Brit J Clinical Pharma

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AIMSThe aim of the present study was to develop a simultaneous population pharmacokinetic model for atazanavir (ATV) incorporating the effect of ritonavir (RTV) on clearance to predict ATV concentrations under different dosing regimens in HIV-1-infected patients. METHODSA Cross-sectional study was carried out in 83 HIV-1-infected adults taking ATV 400 mg or ATV 300 mg/RTV 100 mg once daily. Demographic and clinical characteristics were registered and blood samples collected to measure drug concentrations. A population pharmacokinetic model was constructed using nonlinear mixed-effects modelling and used to simulate six dosing scenarios. RESULTSThe selected one-compartmental model described the pharmacokinetics of RTV and ATV simultaneously, showing exponential, direct inhibition of ATV clearance according to the RTV plasma concentration, which explained 17.5% of the variability. A mean RTV plasma concentration of 0.63 mg l -1 predicted an 18% decrease in ATV clearance. The percentages of patients with an endof-dose-interval concentration of ATV below or above the minimum and maximum target concentrations of 0.15 mg l -1 and 0.85 mg l -1 favoured the selection of the simulated ATV/RTV once-daily regimens (ATV 400 mg, ATV 300 mg/RTV 100 mg, ATV 300 mg/RTV 50 mg, ATV 200/RTV 100 mg) over the unboosted twice-daily regimens (ATV 300 mg, ATV 200 mg). British Journal of Clinical Pharmacology WHAT IS ALREADY KNOWN ABOUT THIS SUBJECT• The once-daily ATV 300 mg/RTV 100 mg regimen is widely used in highly active antiretroviral therapy.• In some patients, dose adjustments may be necessary to prevent concentrations outside the therapeutic range leading to undesired effects or therapeutic failure.• Population pharmacokinetic modelling enables us to detect and quantify the effect of different patient characteristics associated with variability. WHAT THIS STUDY ADDS• A simultaneous population pharmacokinetic model described the decrease in atazanavir clearance with an exponential function of ritonavir (RTV) concentrations in HIV-1-infected adults.• RTV plasma concentrations explained 17.5% of interindividual variability in ATV clearance.• The model supports further clinical trials of once daily doses of atazanavir (ATV) 300 mg/RTV 50 mg or ATV 200 mg/RTV 100 mg to confirm efficacy and safety.

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Section: Discussionsupporting

confidence: 90%

Section: Discussionsupporting

confidence: 90%

Section: Discussionsupporting

confidence: 50%

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Population pharmacokinetic modelling of the changes in atazanavir plasma clearance caused by ritonavir plasma concentrations in HIV‐1 infected patients

Moltó

Estévez

Miranda

et al. 2016

Brit J Clinical Pharma

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“…Previous studies have reported single compartmental elimination kinetics for ritonavir [8, 20–22]. However, possibly because of the rich sampling schedule used in our study, a two compartment model was more appropriate to describe the kinetics in our data.…”

Section: Discussionmentioning

confidence: 98%

“…higher doses and/or other target populations. However, extrapolation beyond the range of the data should be applied with caution [8, 9].…”

Section: Introductionmentioning

confidence: 99%

Model‐based approach to dose optimization of lopinavir/ritonavir when co‐administered with rifampicin

Zhang

Denti

Decloedt

et al. 2012

Brit J Clinical Pharma

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WHAT IS ALREADY KNOWN ABOUT THIS SUBJECT• Doubling the dose of lopinavir/ritonavir overcomes the effect of rifampicin on lopinavir concentrations. However, lopinavir concentrations are highly variable and side effects occur commonly. Hence optimized dosing could limit the number of patients exposed to high lopinavir concentrations while maintaining adequate lopinavir concentrations. WHAT THIS STUDY ADDS• We built an integrated population pharmacokinetic model of lopinavir and ritonavir, describing the drug-drug interactions between lopinavir, ritonavir and rifampicin. Based on this model, we have predicted that lower doses of lopinavir/ritonavir can be used in patients weighing less than 50 kg. Also, diurnal variations on lopinavir and ritonavir were investigated for both bioavailability and clearance. AIMSRifampicin, a key component of antitubercular treatment, profoundly reduces lopinavir concentrations. The aim of this study was to develop an integrated population pharmacokinetic model accounting for the drug-drug interactions between lopinavir, ritonavir and rifampicin, and to evaluate optimal doses of lopinavir/ritonavir when co-administered with rifampicin. METHODSSteady-state pharmacokinetics of lopinavir and ritonavir were sequentially evaluated after the introduction of rifampicin and gradually escalating the dose in a cohort of 21 HIV-infected adults. Intensive pharmacokinetic sampling was performed after each dose adjustment following a morning dose administered after fasting overnight. A population pharmacokinetic analysis was conducted using NONMEM 7. RESULTSA simultaneous integrated model was built. Rifampicin reduced the oral bioavailability of lopinavir and ritonavir by 20% and 45% respectively, and it increased their clearance by 71% and 36% respectively. With increasing concentrations of ritonavir, clearance of lopinavir decreased in an Emax relationship. Bioavailability was 42% and 45% higher for evening doses compared with morning doses for lopinavir and ritonavir, respectively, while oral clearance of both drugs was 33% lower overnight. Simulations predicted that 99.5% of our patients receiving doubled doses of lopinavir/ritonavir achieve morning trough concentrations of lopinavir > 1 mg l -1 during rifampicin co-administration, and 95% of those weighing less than 50 kg achieve this target already with 600/150 mg doses of lopinavir/ritonavir. CONCLUSIONSThe model describes the drug-drug interactions between lopinavir, ritonavir and rifampicin in adults. The higher trough concentrations observed in the morning were explained by both higher bioavailability with the evening meal and lower clearance overnight.

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Population Pharmacokinetics of Lopinavir/Ritonavir: Changes Across Formulations and Human Development From Infancy Through Adulthood

Yang

Nikanjam

Best

et al. 2018

The Journal of Clinical Pharma

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Lopinavir/ritonavir (LPV/r) is recommended by the World Health Organization (WHO) as first-line treatment for HIV-infected infants and young children. We performed a composite population pharmacokinetic (PK) analysis on LPV plasma concentration data from six pediatric and adult studies to determine maturation and formulation effects from infancy to adulthood. Intensive PK data were available for infants, children, adolescents, and adults (297 intensive profiles/1662 LPV concentrations). LPV PK data included 1 adult, 1 combined pediatric-adult, and 4 pediatric studies (age 6 weeks to 63 years) with 3 formulations (gel-capsule, liquid, melt-extrusion tablets). LPV concentrations were modeled using nonlinear mixed effects modeling (NONMEM v. 7.3) with a one compartment semi-physiologic model. Lopinavir clearance was described by hepatic plasma flow (QHP) times hepatic extraction (EH), with EH estimated from the PK data. Volume was scaled by linear weight (WT/70)1.0. Bioavailability was assessed separately as a function of hepatic extraction (FH) and the fraction absorbed from the GI tract (FABS). The absorption component of bioavailability increased with age and tablet formulation. Monte Carlo simulations of the final model using current WHO weight band dosing recommendations demonstrated that participants younger than 6 months of age had lower AUC (94.8 vs >107.4 mcg•hr/mL) and Cmin (5.0 vs > 7.1 mcg/mL) values compared to older children and adults. Although WHO dosing recommendations include a larger dosage (mg/m2) in infants to account for higher apparent clearance (CL/F), they still result in low LPV concentrations in many infants younger than 6 months of age receiving the liquid formulation.

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Sequential Population Pharmacokinetic Modeling of Lopinavir and Ritonavir in Healthy Volunteers and Assessment of Different Dosing Strategies

Cited by 23 publications

References 13 publications

Population pharmacokinetic modelling of the changes in atazanavir plasma clearance caused by ritonavir plasma concentrations in HIV‐1 infected patients

Population pharmacokinetic modelling of the changes in atazanavir plasma clearance caused by ritonavir plasma concentrations in HIV‐1 infected patients

Model‐based approach to dose optimization of lopinavir/ritonavir when co‐administered with rifampicin

Population Pharmacokinetics of Lopinavir/Ritonavir: Changes Across Formulations and Human Development From Infancy Through Adulthood

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