Bayesian sequential integration within a preclinical pharmacokinetic and pharmacodynamic modeling framework: Lessons learned

Gamba, Fabiola La; Jacobs, Tom; Geys, Helena; Jaki, Thomas; Serroyen, Jan; Ursino, Moreno; Russu, Alberto; Faes, Christel

doi:10.1002/pst.1941

Cited by 4 publications

(5 citation statements)

References 42 publications

(59 reference statements)

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“…The Food and Drug Administration (FDA) 5 provides guidelines regarding the use of preclinical knowledge to compute the maximum recommended starting dose (MRSD) of the first-in-human (FIH) trial, with healthy volunteers and drug products for which systemic exposure is intended. These guidelines outline an empirical algorithmic approach to compute the FIH dose in four steps; (1) for each animal species used in the in vivo studies, the human equivalent dose (HED) is computed based on the no-observedadverse-effect level (NOAEL) and on the body surface area; (2) the HED corresponding to the most sensitive animal species is selected and (3) used for the calculation of the MRSD by applying a safety factor accounting for the expected variability coming from animal-to-human toxicity extrapolation; and (4) the MRSD is then adjusted based on the predicted pharmacological mechanism. Although this approach is a valuable starting point, it shows several drawbacks.…”

Section: Introductionmentioning

confidence: 99%

“…For example, in the preclinical and clinical context, La Gamba et al. 1 sequentially introduced knowledge in preclinical investigations within a Bayesian PK/PD setting, using the posterior distributions resulting from one trial to build the prior distributions for the following trial. More widely, the Bayesian approach has also been used to use information obtained from one population for the analysis of another population.…”

Section: Introductionmentioning

confidence: 99%

“…When studies are performed sequentially and the endpoints can be linked (via mathematical transformations, for example), the inference can be easily placed under a Bayesian framework that can update posterior knowledge each time new data becomes available. For example, in the preclinical and clinical context, La Gamba et al 1 sequentially introduced knowledge in preclinical investigations within a Bayesian PK/PD setting, using the posterior distributions resulting from one trial to build the prior distributions for the following trial. More widely, the Bayesian approach has also been used to use information obtained from one population for the analysis of another population.…”

Section: Introductionmentioning

confidence: 99%

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Bayesian framework for multi-source data integration-Application to human extrapolation from preclinical studies

Boulet,

Ursino,

Michelet

et al. 2024

Stat Methods Med Res

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In preclinical investigations, for example, in in vitro, in vivo, and in silico studies, the pharmacokinetic, pharmacodynamic, and toxicological characteristics of a drug are evaluated before advancing to first-in-man trial. Usually, each study is analyzed independently and the human dose range does not leverage the knowledge gained from all studies. Taking into account all preclinical data through inferential procedures can be particularly interesting in obtaining a more precise and reliable starting dose and dose range. Our objective is to propose a Bayesian framework for multi-source data integration, customizable, and tailored to the specific research question. We focused on preclinical results extrapolated to humans, which allowed us to predict the quantities of interest (e.g. maximum tolerated dose, etc.) in humans. We build an approach, divided into four steps, based on a sequential parameter estimation for each study, extrapolation to human, commensurability checking between posterior distributions and final information merging to increase the precision of estimation. The new framework is evaluated via an extensive simulation study, based on a real-life example in oncology. Our approach allows us to better use all the information compared to a standard framework, reducing uncertainty in the predictions and potentially leading to a more efficient dose selection.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Bayesian framework for multi-source data integration-Application to human extrapolation from preclinical studies

Boulet,

Ursino,

Michelet

et al. 2024

Stat Methods Med Res

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“…Other researchers have examined bridging models to identify differences between healthy volunteers and patients (Jonsson et al., 2005; Willmann et al., 2021). In the statistical literature, several publications have focused on extrapolation from pharmacokinetic models to clinical data (La Gamba et al., 2019), and increasing attention has been given to the incorporation of historical data (Natanegara et al., 2013; Ghadessi et al., 2020; Burger et al., 2021). The main advantage of these methods is the ability to estimate the treatment effect with precision and increase in study power while limiting, or even reducing (Viele et al., 2014), type I error in cases of consistency between historical and concurrent data.…”

Section: Introductionmentioning

confidence: 99%

Incorporation of healthy volunteers data on receptor occupancy into a phase II proof‐of‐concept trial using a Bayesian dynamic borrowing design

Di Stefano,

Rodrigues,

Galtier

et al. 2023

Biometrical J

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Receptor occupancy in targeted tissues measures the proportion of receptors occupied by a drug at equilibrium and is sometimes used as a surrogate of drug efficacy to inform dose selection in clinical trials. We propose to incorporate data on receptor occupancy from a phase I study in healthy volunteers into a phase II proof‐of‐concept study in patients, with the objective of using all the available evidence to make informed decisions. A minimal physiologically based pharmacokinetic modeling is used to model receptor occupancy in healthy volunteers and to predict it in the patients of a phase II proof‐of‐concept study, taking into account the variability of the population parameters and the specific differences arising from the pathological condition compared to healthy volunteers. Then, given an estimated relationship between receptor occupancy and the clinical endpoint, an informative prior distribution is derived for the clinical endpoint in both the treatment and control arms of the phase II study. These distributions are incorporated into a Bayesian dynamic borrowing design to supplement concurrent phase II trial data. A simulation study in immuno‐inflammation demonstrates that the proposed design increases the power of the study while maintaining a type I error at acceptable levels for realistic values of the clinical endpoint.

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“…A recent study describing a Bayesian meta-analytic approach applied by Zheng et al suggests how to use preclinical data to inform the design and prior distributions [ 53 ]. Indeed, the Bayesian approach has also been recognized as a powerful and flexible method in the pharmacometric field [ 54 , 55 ] and has been applied in sequential preclinical trials [ 56 ] to build informative prior distributions in human PK analysis using preclinical information [ 57 ] or using information from adult clinical studies to design pediatric trials [ 58 ].…”

Section: Introductionmentioning

confidence: 99%

The Use of Translational Modelling and Simulation to Develop Immunomodulatory Therapy as an Adjunct to Antibiotic Treatment in the Context of Pneumonia

et al. 2021

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The treatment of respiratory tract infections is threatened by the emergence of bacterial resistance. Immunomodulatory drugs, which enhance airway innate immune defenses, may improve therapeutic outcome. In this concept paper, we aim to highlight the utility of pharmacometrics and Bayesian inference in the development of immunomodulatory therapeutic agents as an adjunct to antibiotics in the context of pneumonia. For this, two case studies of translational modelling and simulation frameworks are introduced for these types of drugs up to clinical use. First, we evaluate the pharmacokinetic/pharmacodynamic relationship of an experimental combination of amoxicillin and a TLR4 agonist, monophosphoryl lipid A, by developing a pharmacometric model accounting for interaction and potential translation to humans. Capitalizing on this knowledge and associating clinical trial extrapolation and statistical modelling approaches, we then investigate the TLR5 agonist flagellin. The resulting workflow combines expert and prior knowledge on the compound with the in vitro and in vivo data generated during exploratory studies in order to construct high-dimensional models considering the pharmacokinetics and pharmacodynamics of the compound. This workflow can be used to refine preclinical experiments, estimate the best doses for human studies, and create an adaptive knowledge-based design for the next phases of clinical development.

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Bayesian sequential integration within a preclinical pharmacokinetic and pharmacodynamic modeling framework: Lessons learned

Cited by 4 publications

References 42 publications

Bayesian framework for multi-source data integration-Application to human extrapolation from preclinical studies

Bayesian framework for multi-source data integration-Application to human extrapolation from preclinical studies

Incorporation of healthy volunteers data on receptor occupancy into a phase II proof‐of‐concept trial using a Bayesian dynamic borrowing design

The Use of Translational Modelling and Simulation to Develop Immunomodulatory Therapy as an Adjunct to Antibiotic Treatment in the Context of Pneumonia

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