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Structured methods for parameter inference and uncertainty quantification for mechanistic models in the life sciences

Published 4 Mar 2024 in q-bio.QM | (2403.01678v3)

Abstract: Parameter inference and uncertainty quantification are important steps when relating mathematical models to real-world observations, and when estimating uncertainty in model predictions. However, methods for doing this can be computationally expensive, particularly when the number of unknown model parameters is large. The aim of this study is to develop and test an efficient profile likelihood-based method, which takes advantage of the structure of the mathematical model being used. We do this by identifying specific parameters that affect model output in a known way, such as a linear scaling. We illustrate the method by applying it to three caricature models from different areas of the life sciences: (i) a predator-prey model from ecology; (ii) a compartment-based epidemic model from health sciences; and, (iii) an advection-diffusion-reaction model describing transport of dissolved solutes from environmental science. We show that the new method produces results of comparable accuracy to existing profile likelihood methods, but with substantially fewer evaluations of the forward model. We conclude that our method could provide a much more efficient approach to parameter inference for models where a structured approach is feasible. Code to apply the new method to user-supplied models and data is provided via a publicly accessible repository.

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References (39)
  1. Profile likelihood analysis for a stochastic model of diffusion in heterogeneous media. Proceedings of the Royal Society A, 477(2250):20210214, 2021.
  2. Empirical quantification of predictive uncertainty due to model discrepancy by training with an ensemble of experimental designs: an application to ion channel kinetics. Bulletin of Mathematical Biology, 86(1):2, 2024.
  3. Sequential monte carlo without likelihoods. Proceedings of the National Academy of Sciences, 104(6):1760–1765, 2007.
  4. Approximate Bayesian computation scheme for parameter inference and model selection in dynamical systems. Journal of the Royal Society Interface, 6(31):187–202, 2009.
  5. Approximate Bayesian computation. PLoS Computational Biology, 9(1):e1002803, 2013.
  6. Determination of parameter identifiability in nonlinear biophysical models: A bayesian approach. Journal of General Physiology, 143:401–416, 2014.
  7. Mcmc can detect nonidentifiable models. Biophysical Journal, 103:2275–2286, 2012.
  8. Practical parameter identifiability for spatio-temporal models of cell invasion. Journal of the Royal Society Interface, 17(164):20200055, 2020.
  9. Joining forces of bayesian and frequentist methodology: a study for inference in the presence of non-identifiability. Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences, 371:20110544, 2013.
  10. DG Bates DM abd Watts. Nonlinear regression analysis and its applications. Wiley, 1988.
  11. Structural and practical identifiability analysis of partially observed dynamical models by exploiting the profile likelihood. Bioinformatics, 25:1923–1929, 2009.
  12. Profile likelihood in systems biology. The FEBS Journal, 280:2564–2571, 2013.
  13. Likelihood based observability analysis and confidence intervals for predictions of dynamics models. BMC Systems Biology, 6:120, 2013.
  14. Parameter identifiability in pde models of fluorescence recovery after photobleaching. Bulletin of Mathematical Biology, 86:36, 2024.
  15. Profile-wise analysis: A profile likelihood-based workflow for identifiability analysis, estimation, and prediction with mechanistic mathematical models. PLoS Computational Biology, 19(9):e1011515, 2023.
  16. Modelling the impact of the Omicron BA.5 subvariant in New Zealand. Journal of the Royal Society Interface, 20(199):20220698, 2023.
  17. Yudi Pawitan. In all likelihood: Statistical modelling and inference using likelihood. Oxford University Press, 2001.
  18. Patrick Royston. Profile likelihood for estimation and confidence intervals. The Stata Journal, 7:376–387, 2007.
  19. Graphical representation and stability conditions of predator-prey interactions. American Naturalist, 97(895):209–223, 1963.
  20. Alfred James Lotka. Elements of Physical Biology. Williams & Wilkins, 1925.
  21. Vito Volterra. Variazioni e fluttuazioni del numero d’individui in specie animali conviventi. Memoria della Reale Accademia Nazionale dei Lincei, 2:31–113, 1926.
  22. Odo Diekmann and Johan Andre Peter Heesterbeek. Mathematical epidemiology of infectious diseases: model building, analysis and interpretation. Wiley, 5th edition, 2000.
  23. Reconstructing the early global dynamics of under-ascertained COVID-19 cases and infections. BMC Medicine, 18(1):332, 2020.
  24. Estimating the effects of non-pharmaceutical interventions on COVID-19 in Europe. Nature, 584(7820):257–261, 2020.
  25. Coupling of transport and chemical processes in numerical transport models. Geoderma, 44:473–480, 1976.
  26. A Ogata and R B Banks. A solution of the differential equation of longitudinal dispersion in porous media. US Geological Survey, Professional Paper, 411-A, 1961.
  27. Mass transfer studies in sorbing porous media i. analytical solutions. Soil Science Society of America Journal, 40:115–127, 1989.
  28. Implementing measurement error models with mechanistic mathematical models in a likelihood-based framework for estimation and prediction in the life sciences. Journal of the Royal Society Interface, 21:20230402, 2024.
  29. Travelling gradients in interacting morphogen systems. Mathematical Biosciences, 209(1):30–50, 2007.
  30. Models of collective cell motion for cell populations with different aspect ratio: diffusion, proliferation and travelling waves. Physica A: Statistical Mechanics and its Applications, 391(14):3729–3750, 2012.
  31. M Rascle and C Ziti. Finite time blow-up in some models of chemotaxis. Journal of Mathematical Biology, 33:388–414, 1995.
  32. The effect of chemotaxis and chemokinesis on leukocyte locomotion: A new interpretation of experimental results. Mathematical Medicine and Biology: A Journal of the IMA, 15(3):235–256, 1998.
  33. Scale-invariant model of marine population dynamics. Physical Review E, 81(6):061901, 2010.
  34. Ecological drivers of stability and instability in marine ecosystems. Theoretical Ecology, 5:465–480, 2012.
  35. James D Murray. Mathematical Biology: I: An Introduction. Springer, 2003.
  36. Quantifying rates of cell migration and cell proliferation in co-culture barrier assays reveals how skin and melanoma cells interact during melanoma spreading and invasion. Journal of Theoretical Biology, 423:13–25, 2017.
  37. T Cassudy. A continuation technique for maximum likelihood estimators in biological models. Bulletin of Mathematical Biology, 85:90, 2023.
  38. Bayesian workflow. arXiv preprint, 2011.01808, 2020.
  39. Larry Wasserman. All of Statistics: A Concise Course in Statistical Inference. Springer, 2004.
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