Author: Gallo, James M.
Title: Hybrid physiologicallyâ€based pharmacokinetic model for remdesivir: Application to SARSâ€CoVâ€2 Cord-id: uvc0ujdz Document date: 2021_5_1
ID: uvc0ujdz
Snippet: A novel coronavirus, severe acute respiratory syndromeâ€coronavirus 2 (SARSâ€CoVâ€2) or coronavirus disease 2019 (COVIDâ€19), has caused a pandemic that continues to cause catastrophic health and economic carnage and has escalated the identification and development of antiviral agents. Remdesivir (RDV), a prodrug and requires intracellular conversions to the active triphosphate nucleoside (TN) has surfaced as an active antiâ€SARSâ€CoVâ€2 drug. To properly design therapeutic treatment regi
Document: A novel coronavirus, severe acute respiratory syndromeâ€coronavirus 2 (SARSâ€CoVâ€2) or coronavirus disease 2019 (COVIDâ€19), has caused a pandemic that continues to cause catastrophic health and economic carnage and has escalated the identification and development of antiviral agents. Remdesivir (RDV), a prodrug and requires intracellular conversions to the active triphosphate nucleoside (TN) has surfaced as an active antiâ€SARSâ€CoVâ€2 drug. To properly design therapeutic treatment regimens, it is imperative to determine if adequate intracellular TN concentrations are achieved in target tissues, such as the lungs. Because measurement of such concentrations is unrealistic in patients, a physiologicallyâ€based pharmacokinetic (PBPK) model was developed to characterize RDV and TN disposition. Specifically, a hybrid PBPK model was developed based on previously reported data in humans. The model represented each tissue as a twoâ€compartment model—both extracellular and intracellular compartment wherein each intracellular compartment contained a comprehensive metabolic model to the ultimate active metabolite TN. Global sensitivity analyses and Monteâ€Carlo simulations were conducted to assess which parameters and how highly sensitive ones impacted peripheral blood mononuclear cells and intracellular lung TN profiles. Finally, clinical multipleâ€dose regimens indicated that minimum lung intracellular TN concentrations ranged from ~ 9 uM to 4 uM, which suggest current regimens are effective based on in vitro halfâ€maximal effective concentration values. The model can be used to explore tissue drug disposition under various conditions and regimens, and expanded to pharmacodynamic models.
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