Development of a Dynamic Physiologically Based Mechanistic Kidney Model to Predict Renal Clearance

Huang, Weize; Isoherranen, Nina

doi:10.1002/psp4.12321

Cited by 39 publications

(72 citation statements)

References 44 publications

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“…Colon-derived Caco-2 and other in vitro cell lines differ from heterogeneous epithelial cells constituting the nephron tubule in terms of tight junctions (affecting para-cellular drug permeability), transporter expression, and presence of microvilli. To address the latter, one study used an empirical surface-area scaling factor to recapitulate CL R from in vitro permeability data using a 35-compartment model (Huang and Isoherranen, 2018). No empirical scaling factor was applied in the current study; instead, the IVIVE approach relied on physiologic assumptions, although verification of each of the specific parameter values has not yet been achieved.…”

Section: Discussionmentioning

confidence: 99%

“…In addition, some parameters may exhibit biologic variability that is not controlled or monitored in a typical clinical study; for example, urinary pH can range from 4.5 to 8, but it is generally slightly acidic (i.e., 5.5-7.0) because of metabolic activity (Simerville et al, 2005). Another challenge with such complex models is ensuring the identifiability of parameters as plasma concentration-time data may not always be informative for all model parameters (Hsu et al, 2014;Huang and Isoherranen, 2018), as discussed previously (Tsamandouras et al, 2015;Scotcher et al, 2017;Guo et al, 2018). All the preceding challenges are also applicable in the case of renal elimination, especially when attempting to separate quantitatively the roles of active transport and passive permeability to overall secretion and/or reabsorption (e.g., salicylic acid, creatinine).…”

Section: Introductionmentioning

confidence: 99%

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Towards Further Verification of Physiologically-Based Kidney Models: Predictability of the Effects of Urine-Flow and Urine-pH on Renal Clearance

Matsuzaki¹,

Scotcher²,

Darwich³

et al. 2018

J Pharmacol Exp Ther

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In vitro-in vivo extrapolation (IVIVE) of renal excretory clearance (CL R ) using the physiologically based kidney models can provide mechanistic insight into the interplay of multiple processes occurring in the renal tubule; however, the ability of these models to capture quantitatively the impact of perturbed conditions (e.g., urine flow, urine pH changes) on CL R has not been fully evaluated. In this work, we aimed to assess the predictability of the effect of urine flow and urine pH on CL R and tubular drug concentrations (selected examples). Passive diffusion clearance across the nephron tubule membrane was scaled from in vitro human epithelial cell line Caco-2 permeability data by nephron tubular surface area to predict the fraction reabsorbed and the CL R of caffeine, chloramphenicol, creatinine, dextroamphetamine, nicotine, sulfamethoxazole, and theophylline. CL R values predicted using mechanistic kidney model at a urinary pH of 6.2 and 7.4 resulted in prediction bias of 2.87-and 3.62-fold, respectively. Model simulations captured urine flow-dependent CL R , albeit with minor underprediction of the observed magnitude of change. The relationship between drug solubility, urine flow, and urine pH, illustrated in simulated intratubular concentrations of acyclovir and sulfamethoxazole, agreed with clinical data on tubular precipitation and crystal-induced acute kidney injury. This study represents the first systematic evaluation of the ability of the mechanistic kidney model to capture the impact of urine flow and urine pH on CL R and drug tubular concentrations with the aim of facilitating refinement of IVIVE-based mechanistic prediction of renal excretion.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Towards Further Verification of Physiologically-Based Kidney Models: Predictability of the Effects of Urine-Flow and Urine-pH on Renal Clearance

Matsuzaki¹,

Scotcher²,

Darwich³

et al. 2018

J Pharmacol Exp Ther

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“…In this study, we hypothesized that modeling techniques could be leveraged to understand and predict urine pH effect on drug and metabolite disposition. To test this hypothesis, a recently developed and verified dynamic physiologically-based mechanistic kidney model (Huang and Isoherranen, 2018) was integrated into a parent-metabolite full body physiologically based pharmacokinetic (PBPK) model (Huang and Isoherranen, 2020) to simulate urine pH dependent parent-metabolite systemic disposition and urinary excretion using methamphetamine and amphetamine as model compounds.…”

Section: Downloaded Frommentioning

confidence: 99%

Mechanistic PBPK Modeling of Urine pH Effect on Renal and Systemic Disposition of Methamphetamine and Amphetamine

Huang

Czuba

Isoherranen

2020

J Pharmacol Exp Ther

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AUC, area under the plasma drug concentration versus time curve B/P, blood-to-plasma ratio CL, total plasma clearance CLf, formation clearance of the metabolite CLint, intrinsic clearance for the drug CLint,m, intrinsic clearance for the metabolite CLr, renal clearance CYP2D6, Cytochrome P450 2D6 enzyme DDI, drug-drug interaction fe, fraction elimination of kidney fu,p, unbound fraction in plasma ka, absorption constant Kp, tissue-to-plasma partition coefficient for the drug Kp,m, tissue-to-plasma partition coefficient for the metabolite Meth, S(+)-methamphetamine MDCK, Madin-Darby canine kidney PBPK, physiologically-based pharmacokinetics PET, positron emission tomography PK, pharmacokinetics Vss, volume of distribution at steady state This article has not been copyedited and formatted. The final version may differ from this version.

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“…At present, there are no good static systems to predict renal clearance due to the complex physiology of the kidney and the generation of concentration gradients and pH gradients in the kidneys during passive reabsorption of drugs and water from tubular lumen. Passive permeability measures from Caco‐2 or Manine‐Darby canine kidney (MDCK) cells are generally used to estimate and predict reabsorption clearance in the kidneys and can be used to populate PBPK models . This approach has many weaknesses, and, therefore, better in vitro models that closely mimic the processes observed in the human kidneys are needed to improve the validity of kidney PBPK models and predictions of renal clearance and renal transporter contribution to renal clearance.…”

Section: Use Of Microphysiological Systems To Support Pbpk Modeling Amentioning

confidence: 99%

“…Passive permeability measures from Caco-2 or Manine-Darby canine kidney (MDCK) cells are generally used to estimate and predict reabsorption clearance in the kidneys and can be used to populate PBPK models. 61,62 This approach has many weaknesses, and, therefore, better in vitro models that closely mimic the processes observed in the human kidneys are needed to improve the validity of kidney PBPK models and predictions of renal clearance and renal transporter contribution to renal clearance. The kidney-on-a-chip system that incorporates two fluid flow compartments that mimic the blood and tubular lumen in the kidneys separated by the layer of tubular cells may be the best experimental model to generate appropriate in vitro values for predicting and modeling renal clearance.…”

Section: Excretionmentioning

confidence: 99%

Emerging Role of Organ‐on‐a‐Chip Technologies in Quantitative Clinical Pharmacology Evaluation

Isoherranen

Madabushi

Huang

2019

Clinical Translational Sci

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The recently enacted Prescription Drug User Fee Act ( PDUFA ) VI includes in its performance goals “enhancing regulatory science and expediting drug development.” The key elements in “enhancing regulatory decision tools to support drug development and review” include “advancing model‐informed drug development ( MIDD ).” This paper describes (i) the US Food and Drug Administration ( FDA ) Office of Clinical Pharmacology's continuing efforts in developing quantitative clinical pharmacology models (disease, drug, and clinical trial models) to advance MIDD , (ii) how emerging novel tools, such as organ‐on‐a‐chip technologies or microphysiological systems, can provide new insights into physiology and disease mechanisms, biomarker identification and evaluation, and elucidation of mechanisms of adverse drug reactions, and (iii) how the single organ or linked organ microphysiological systems can provide critical system parameters for improved physiologically‐based pharmacokinetic and pharmacodynamic evaluations. Continuous public‐private partnerships are critical to advance this field and in the application of these new technologies in drug development and regulatory review.

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Development of a Dynamic Physiologically Based Mechanistic Kidney Model to Predict Renal Clearance

Cited by 39 publications

References 44 publications

Towards Further Verification of Physiologically-Based Kidney Models: Predictability of the Effects of Urine-Flow and Urine-pH on Renal Clearance

Towards Further Verification of Physiologically-Based Kidney Models: Predictability of the Effects of Urine-Flow and Urine-pH on Renal Clearance

Mechanistic PBPK Modeling of Urine pH Effect on Renal and Systemic Disposition of Methamphetamine and Amphetamine

Emerging Role of Organ‐on‐a‐Chip Technologies in Quantitative Clinical Pharmacology Evaluation

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