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Modelling and simulation in the pharmaceutical industry

Modelling and simulation in the pharmaceutical industry. Reflections from a statistician’s and engineer’s perspective. Carl-Fredrik Burman, PhD, Assoc Prof Senior Principal Scientist AstraZeneca R&D Mölndal. Agenda. Seven theses about good modelling It is about making better decisions

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Modelling and simulation in the pharmaceutical industry

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  1. Modelling and simulation in the pharmaceutical industry Reflections from a statistician’s and engineer’s perspective Carl-Fredrik Burman, PhD, Assoc Prof Senior Principal Scientist AstraZeneca R&D Mölndal

  2. Agenda • Seven theses about good modelling • It is about making better decisions • It is driven by the underlying question • It is based on applied sciences • It uses a diversity of information sources • It is not made unnecessarily complicated • It is a continuous process • It facilitates communication • Some thoughts on simulation • Concluding remarks Global Medicines Development | Biometrics & Information Science

  3. Seven theses about good modelling • Based on Burman & Wiklund (Pharm Stat 2011) • The seven theses are partly overlapping • The intention is rather prescriptive than descriptive Global Medicines Development | Biometrics & Information Science

  4. Are the theses just saying the obvious? Global Medicines Development | Biometrics & Information Science

  5. 1. Good modellingis about making better decisions

  6. Don’t model unless you see which decision could be improved by your model Global Medicines Development | Biometrics & Information Science

  7. Value of Modelling (Cf. Value of Information) • Data, information, models may have a larger or smaller value depending on the situation • X available data • D decision • M “modelling” • V value (in e.g. Swiss franc, or total patient benefit) • Value of Modelling = VoM = E[ V( D(X,M) ) ]  E[ V( D(X) ) ] • Value only(?) through changing the decision Global Medicines Development | Biometrics & Information Science

  8. Value of Modelling A simple example • Value of Modelling = VoM = E[ V( D(X,M) ) ]  E[ V( D(X) ) ] • Say that we have a pure go / no go (dichotomous!) phase III investment decision • If it’s pretty obvious that we should “go”, modelling doesn’t help • However, if this is a tough decision, modelling (e.g. predicting through biomarker-clinical endpoint relation, extrapolating over time and population) may be very valuable. • Frontload: Start modelling ph III before ph II investment Global Medicines Development | Biometrics & Information Science

  9. Value of Modelling Example (cont’d) • Value of Modelling = VoM = E[ V( D(X,M) ) ]  E[ V( D(X) ) ] • Say that we face a phase III investment decision that is not purely dichotomous, but concerns • Go / No Go • Dose selection • Population • Sample size • Then, all these may add more or less to the overall value • Highly dependent on specific situation Global Medicines Development | Biometrics & Information Science

  10. Decision focus Don’t necessarily have to be one single decision • Useful to update model continuously (Thesis 6) • Series of decisions • Adaptive Programmes • Cross-over to new projects • Obvious for same indication • But trial data for one drug can sometimes help to give useful background information for completely different indications (variability, disease progression) Global Medicines Development | Biometrics & Information Science

  11. “Soft” but important? • (Too) many modellers have been vague about the aim of their work • Describe the system • Improve understanding • Write scientific papers • ... • Modelling can be used for summarising information, predicting, gaining insights, etc. • However, the benefits of e.g. a ‘gained insight’ will be realised when the insight is reflected in an actual decision. Global Medicines Development | Biometrics & Information Science

  12. Industry vs. Academia • I think the luxury of “non-purpose” modelling should sometimes be allowed • Cf. pure mathematics • but more often in academia Global Medicines Development | Biometrics & Information Science

  13. 2. Good modellingis driven by the underlying question

  14. “All models are wrong, some are useful” George Box Global Medicines Development | Biometrics & Information Science

  15. Don’t search for the ultimate model • “All models are wrong ...” A model cannot incorporate all available information and be capable of answering all relevant project questions. • “... some are useful” The usefulness depends on the purpose of modelling, on which decision we set out to support. • Fit for purpose The model should thus be tailored to the concrete project question (Thesis 5). Global Medicines Development | Biometrics & Information Science

  16. Different objectives  different models needed • Example 1: Testing overall placebo-controlled efficacy • Example 2: Is the drug less efficacious than a competitor drug in elderly? If so, where’s the cut-off? • Example 3: Dose adjustment possible based on age or pharmacokinetic exposure (that correlates with age) Global Medicines Development | Biometrics & Information Science

  17. Need to understand the real question • Common consultancy experience: • Clients may ask the wrong question • The modeller should try to understand the overall context Global Medicines Development | Biometrics & Information Science

  18. 3. Good modellingis based on applied sciences

  19. Be a scientist, not a narrow-minded statistician! Global Medicines Development | Biometrics & Information Science

  20. Modelling “Reality” Mathematics To me, modelling is about translating from the real problem to mathematics, and going back from a mathematical solution to a practical solution. Global Medicines Development | Biometrics & Information Science

  21. Note! Modelling in my narrow sense is not about solving the mathematical problem! • Modelling process: • Understand the project problem • Formulate objective • Map reality onto mathematic • Solve mathematical problem • Translate back to give decision support • Check robustness • Communicate Global Medicines Development | Biometrics & Information Science

  22. Good modelling requires the utilisation of several scientific areas, not only statistics • Statisticians often have excellent skill-sets for modelling work. • However, we may need to transcend traditional roles and eagerly seek to understand the essence of the project’s problem. • Think and act as scientists in a wider sense, focussed on providing useful decision support, irrespectively of what kind of methods that are needed. • Avoid “He that is skilled with a hammer tends to think everything’s a nail” • Collaborate! Global Medicines Development | Biometrics & Information Science

  23. 4. Good modellinguses a diversity of information sources

  24. Combining different information sources Several pieces to the puzzle • Often, we need several components, e.g. • Dose-response • Time dependence • Biomarker – clinical endpoint • Variability (between patients, over time, day-to-day, measure-to-measure) • to build a useful model • Information needed will often come from different sources Global Medicines Development | Biometrics & Information Science

  25. Different information sources • In-house randomised clinical trials • Pre-clinical data • Competitor data • Observational studies • Literature information • Expert knowledge • ... Global Medicines Development | Biometrics & Information Science

  26. Combining different information sources … to estimate a common parameter • Scientific insights needed to see the relevance of information • In principle, the Bayesian framework is readily applicable as it treats all types of uncertainties in the same way. • In-house design decisions can be guided by Bayesian decision theory, even if regulators and other costumers require frequentist analyses Global Medicines Development | Biometrics & Information Science

  27. 5. Good modellingis not made overly complicated

  28. Not overly complicated Ockham’s razor: “Pluralitas non est ponenda sine neccesitate” (“Entities should not be multiplied unnecessarily'‘) William of Ockham, 1285–1347/49 “A model should be as simple as possible and yet no simpler” Albert Einstein, 1879-1955 Global Medicines Development | Biometrics & Information Science

  29. Efficiency of modelling work • Don’t spend time on modelling that likely have ignorable impact on the decision problem. • The first question to ask is whether modelling is worthwhile, i.e. to assess whether the net ‘Value of Modelling’ is positive. Global Medicines Development | Biometrics & Information Science

  30. Marginal Value of Modelling • How much effort to put into modelling? • Engineering: Quick and dirty! • Value of Modelling VoM = E[ V( D(X,M) ) ]  E[ V( D(X) ) ] Global Medicines Development | Biometrics & Information Science

  31. Example • Pharmacokinetics / pharmacodynamics (PK/PD) modelling can give great benefits. • However, if it’s clear that one single dose is sought, the PK component will typically not be important. • Why estimate f(PK(d)), when you only need f(d)? Global Medicines Development | Biometrics & Information Science

  32. 6. Good modellingis a continuous process

  33. Continuous learning • A model made for one decision point can often be re-used, updated and applied to a later decision. • The ‘Learning Loop’ provides a description of the continuous modelling process and the interaction with (design) optimisations and information retrieval. • The greatest benefits will likely be achieved with ’model-based drug development’, where modelling is fully integrated in the process. Global Medicines Development | Biometrics & Information Science

  34. 7. Good modellingfacilitates communication

  35. Transparency • Modelling is not a concern only for the quantitative scientists. • Modelling is not replacing the decision-makers, but supporting them. Global Medicines Development | Biometrics & Information Science

  36. Decision support • Present not only the optimal solution, but also • Assumptions • Robustness checks. • The ideal is that the decision-makers can challenge assumptions and interactively study the consequences of altering them. • Successful modelling processes provide major benefits in transparency within the teams regarding underlying assumptions, and facilitate communication with governance bodies and decision-makers. Global Medicines Development | Biometrics & Information Science

  37. Some thoughts about simulation

  38. Simulation A piece of cake? • We are considering “simple” clinical trial simulation, not e.g. MCMC • For most statisticians, it is trivial to simulate a simple clinical trials, with sufficient precision • However, many modelling problems are more complicated, including • a range of scenarios • multidimensional optimisation. • In our experience, simulation studies are often ineffective, leading to inadequate precision in results. Global Medicines Development | Biometrics & Information Science

  39. Give confidence intervals for simulation results! Global Medicines Development | Biometrics & Information Science

  40. Simulation Alternatives • Consider alternatives to simulation • analytic solutions • Numerical analysis • Approximations • In many cases, parts of the problem can be solved by such means, leaving a much simpler problem to stochastic simulations. Global Medicines Development | Biometrics & Information Science

  41. Simulation Simplify • Don’t make your simulation model overly complicated! • Simulate sufficient statistics, not individual data • Approximate. E.g. central limit theorem. Global Medicines Development | Biometrics & Information Science

  42. Simulation Reduce simulation variability • Simulations are often applied to compare the efficiency of competing designs, e.g. of a dose-finding trial. • Two designs with different doses can effectively be compared by using the same simulated residuals for both designs. • This can greatly reduce the variance of a difference of estimates. • A similar trick can be used when the doses are the same but different allocations (e.g. larger placebo group) are considered. Global Medicines Development | Biometrics & Information Science

  43. Remember: Confidence intervals! Global Medicines Development | Biometrics & Information Science

  44. Concluding remarks

  45. The role of the pharma statistician • An arguably conservative attitude has served us well • Appropriate in the traditional core area: the analysis of (confirmatory) clinical trial data. • However, time they are a-changing. • An increasing importance on complex issues in programme design and decision support • To more effectively add value, statisticians need to adopt a more flexible mindset and be willing to embrace new, useful methodology. Global Medicines Development | Biometrics & Information Science

  46. Which designs are possible? Alternative designs What do we know already? Where do we want to go? Optimise design, based on model & objectives Modelling Objectives Simulations / Computations

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