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This presentation discusses the use of a novel longitudinal model-based approach for efficacy assessments in biosimilars for rheumatoid arthritis. It covers the simulation models, statistical methodology, and preliminary results. The goal is to optimize the choice of analysis methodology to potentially reduce the size of Phase III studies.
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EFPSI-BBS Meeting on M&S, Basel 13 September 2012 Using M&S to develop a novel longitudinal model-based approach for efficacy assessments, with an application to biosimilars in rheumatoid arthritis D Renard1, B Bieth1, F Mentré2, G Heimann1, I Demin1, B Hamrén1, S Balser3 1Modeling and Simulation, Novartis, Basel (Switzerland), 2 UMR 738, INSERM and Universite Paris Diderot, Paris (France), 3 Sandoz Biopharmaceuticals, Holzkirchen (Germany)
Outline • Background • M&S approach • Simulation models • Statistical methodology • Some results • Next steps | EFPSI-BBS meeting | D Renard | 13 Sep 2012 | Longitudinal model-based approach for efficacy assessments
Problem that we attempt to address • Question • Can the size of a Phase III study be reduced by optimizing the choice of analysis methodology, as compared to using the standard approach (end-point analysis) ? • An innovative model-based approach was developed • Aim to maintain strict regulatory standards for phase III • Sound statistical properties • Fully pre-specified analysis • Note: this is NOT how pharmacometric (M&S) analyses are routinely applied in drug development! | EFPSI-BBS meeting | D Renard | 13 Sep 2012 | Longitudinal model-based approach for efficacy assessments
Application: Biosimilars in rheumatoid arthritis (RA) • In RA studies, standard efficacy assessments rely on the ACR20 after 24 weeks of treatment (ACR20=American College of Rheumatology 20% response criterion) • Objective is to demonstrate similar efficacy between the reference and biosimilar products • Formally achieved through statistical equivalence testing • Standard method: • Based on response rates (#ACR20 responders/#patients) • Only uses data collected at Week 24 • Equivalence is inferred when the 95% confidence interval (CI) for the treatment effect is included within the equivalence margins | EFPSI-BBS meeting | D Renard | 13 Sep 2012 | Longitudinal model-based approach for efficacy assessments
M&S approach • Step 1. Establish simulation models • Requirement: simulate realistic study outcomes for ACR20 (including compound specific characteristics) • Simulation models were built using a mix of literature (summary level) and internal (patient level) data • Models components: time course of response, different sources of variability, and dropout characteristics • Step 2: Development of statistical methodology • Longitudinal model-based approach for equivalence testing • Rooted to nonlinear mixed effect (NLME) modeling, entails pre-specifying different candidate models and relies on model averaging techniques • Step 3. Simulations and assessment of performance • An extensive simulation program was conducted to assess performance of the longitudinal model-based approach • More is needed! | EFPSI-BBS meeting | D Renard | 13 Sep 2012 | Longitudinal model-based approach for efficacy assessments
Longitudinal model-based meta-analysis as basis for setting up realistic simulation models • 9 anti-TNF agents, 37 studies • ACR20 responses • to methotrexate (MTX) • Symbols = study results (size proportional to # patients) • Solid lines connect points from each study • Broken lines = smooth curves for each patient population Demin et al, Clin Pharmacol Ther (2012) | EFPSI-BBS meeting | D Renard | 13 Sep 2012 | Longitudinal model-based approach for efficacy assessments
Simulation models • Different simulation models were considered to ensure robustness of the conclusions • Models were set up to mimick different compounds based on meta-analytic characterization • Internal data were used to inform variability parameters in the models • An example of model is given on slide 10 | EFPSI-BBS meeting | D Renard | 13 Sep 2012 | Longitudinal model-based approach for efficacy assessments
Literature database was used to build assumptions about dropout • Assumptions • Dropout increases proportionally over time to reach 15% at week 24 • Patients not responding at the previous visit were twice more likely to drop out compared to patients who were responders • Dropout for non responders assumed to be due to lack of efficacy | EFPSI-BBS meeting | D Renard | 13 Sep 2012 | Longitudinal model-based approach for efficacy assessments
Longitudinal model-based testing (1) NLME models are pre-specified to describe transition probabilities based on the Markov assumption linking the entire longitudinal data. Pre-specified candidate models Lacroix BD et al, Clin Pharmacol Ther 2009, 86: 387-395. ACR20 Model averaging The response rate at week 24 is a function of transition probabilities: Equivalence testing 1 Pr10 Pr01 Pr10 0 0 2 4 20 24 Visits (week) | EFPSI-BBS meeting | D Renard | 13 Sep 2012 | Longitudinal model-based approach for efficacy assessments
Longitudinal model-based test (2) • Markov models are specified for two independent transition probabilities, e.g. • 10 candidate models are pre-specified, which differ through constraints in parameters and function of time • Range of simple up to more complex models • Estimating ACR20 response rates for a given model • Individual response probabilities are derived from the Markov property (previous slide) using modeled transition probabilities • Population response rates are derived by integrating out the random effects (η10, η11) Pre-specified candidate models i= subject k=study visit Model averaging Equivalence testing | EFPSI-BBS meeting | D Renard | 13 Sep 2012 | Longitudinal model-based approach for efficacy assessments
Longitudinal model-based test (3) • Key concept: model averaging • Used to estimate the response rates at week 24 by combining results from the different candidate models • Point estimate = weighted average of the individual model estimates • Weights are functions of a statistical criterion (BIC) • Larger weights are assigned to models that fit the data better. Pre-specified candidate models Model averaging k = treatments m = models Equivalence testing | EFPSI-BBS meeting | D Renard | 13 Sep 2012 | Longitudinal model-based approach for efficacy assessments
Longitudinal model-based test (4) Pre-specified candidate models Example: candidate models 10 candidate models 3 models shown with corresponding weights (w) W=.18 W=.75 W=.00 Model averaging Equivalence testing | EFPSI-BBS meeting | D Renard | 13 Sep 2012 | Longitudinal model-based approach for efficacy assessments
Longitudinal model-based test (5) Pre-specified candidate models Example: model averaging 10 candidate models 3 models shown with corresponding weights (w) Model average estimate (thick black) W=.18 W=.75 W=.00 Model averaging Equivalence testing | EFPSI-BBS meeting | D Renard | 13 Sep 2012 | Longitudinal model-based approach for efficacy assessments
Longitudinal model-based test (6) Pre-specified candidate models • Bootstrap is used to derive a confidence interval for the treatment difference at week 24. • Bootstrap datasets are built by resampling over subjects. • The 95% CI is compared with the equivalence margins for equivalence testing. Model averaging Equivalence testing | EFPSI-BBS meeting | D Renard | 13 Sep 2012 | Longitudinal model-based approach for efficacy assessments
Model-based analysis versus classical test • Model-based approach does not change the nature of the comparability testing and makes it more efficient! Difference in response rates (%) Simulation # Symbols correspond to point estimates and bars to 95% CI 10 simulation runs assuming strict equivalence (n=180/arm) | EFPSI-BBS meeting | D Renard | 13 Sep 2012 | Longitudinal model-based approach for efficacy assessments
Simulation results: Power • 40% reduction in sample size compared to the classical test at power levels of 80 and 90% Power assessed based on 1000 simulations | EFPSI-BBS meeting | D Renard | 13 Sep 2012 | Longitudinal model-based approach for efficacy assessments
Simulation results: Type 1 error • Type I error rate is close to the 2.5% nominal level Assessment based on 1000 simulations (bars represent Monte-Carlo error) | EFPSI-BBS meeting | D Renard | 13 Sep 2012 | Longitudinal model-based approach for efficacy assessments
Summary of methodology • The model-based analysis uses all data collected to derive an estimate and its confidence interval of the treatment effect at the end of the study (week 24) • Model averaging is used to prevent against model misspecification • Number of patients was reduced up to 40% with the longitudinal model-based analysis – confirmed by additional simulation scenarios and sensitivity analyses • Extensions: the principles could be applied to other types of endpoints in RA (e.g. DAS28), other therapeutic areas for biosimilarity assessments, or for efficacy assessments in late stage clinical development of new drugs | EFPSI-BBS meeting | D Renard | 13 Sep 2012 | Longitudinal model-based approach for efficacy assessments
Summary of health authority interactions • Initial project feedback from EMA was negative • Overall encouraging feedback obtained at EMA/EFPIA workshop (Dec 2011) • Absence of theoretical results to justify type I error control appears to be a critical concern deserving careful consideration • How can regulatory acceptance be gained ? • Planned interaction with EMA through Innovation Task Force process • Perform large simulation study to evaluate type 1 error control (ongoing) • Use model-based approach as supportive analysis in future studies • Present and discuss the method with the scientific community | EFPSI-BBS meeting | D Renard | 13 Sep 2012 | Longitudinal model-based approach for efficacy assessments