4.7 Article

Mechanistic PK-PD model of alendronate treatment of postmenopausal osteoporosis predicts bone site-specific response

Journal

Publisher

FRONTIERS MEDIA SA
DOI: 10.3389/fbioe.2022.940620

Keywords

alendronate; bone remodeling; bone cell population model; postmenopausal osteoporosis; pharmacokinetics; pharmacodynamics

Funding

  1. Australian Research Council (ARC ITTC)
  2. [PID2019-106969R]
  3. [MCIN/AEI/10.13039/501100011033]

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In this study, a pharmacokinetic (PK) model and pharmacokinetic-pharmacodynamic (PK-PD) model were developed for alendronate to predict bone density gain (BDG) in the treatment of postmenopausal osteoporosis (PMO). The results showed that at least three compartments are required to simulate the effect of alendronate in both short and long-term treatments. Clinical data reproduced by the PK-PD model demonstrated site-specific bone response, with 7% BDG at the hip and 4% BDG at the lumbar spine. Differences in BDG between sites were attributed to variations in bone-specific surface and porosity.
Alendronate is the most widely used drug for postmenopausal osteoporosis (PMO). It inhibits bone resorption, affecting osteoclasts. Pharmacokinetics (PK) and pharmacodynamics (PD) of alendronate have been widely studied, but few mathematical models exist to simulate its effect. In this work, we have developed a PK model for alendronate, valid for short- and long-term treatments, and a mechanistic PK-PD model for the treatment of PMO to predict bone density gain (BDG) at the hip and lumbar spine. According to our results, at least three compartments are required in the PK model to predict the effect of alendronate in both the short and long terms. Clinical data of a 2-year treatment of alendronate, reproduced by our PK-PD model, demonstrate that bone response is site specific (hip: 7% BDG, lumbar spine: 4% BDG). We identified that this BDG is mainly due to an increase in tissue mineralization and a decrease in porosity. The difference in BDG between sites is linked to the different loading and dependence of the released alendronate on the bone-specific surface and porosity. Osteoclast population diminishes quickly within the first month of alendronate treatment. Osteoblast population lags behind but also falls due to coupling of resorption and formation. Two dosing regimens were studied (70 mg weekly and 10 mg daily), and both showed very similar BDG evolution, indicating that alendronate accumulates quickly in bone and saturates. The proposed PK-PD model could provide a valuable tool to analyze the effect of alendronate and to design patient-specific treatments, including drug combinations.

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