SISMID 2019: Mathematical Models of Infectious Diseases – Drake Lab

Laboratory of Population Dynamics

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SISMID 2019: Mathematical Models of Infectious Diseases

Overview

Program: 11th Annual Summer Institute in Statistical Modeling of Infectious Diseases
Location: University of Washington
Date: July 8-10, 2019
Instructors: Pejman Rohani (rohani@uga.edu) & John M. Drake (jdrake@uga.edu)
Class objectives: Outline
Data for exercises: data.zip

Class topics

Day 1

Outline: Objectives
Lecture: Mathematical models of infectious diseases
Exercise: Deterministic models (Slides) (Code) (Solutions)
Lecture: Equilibrium stability analysis and next generation method
Lecture: Stochastic models
Exercise: Stochastic simulation (Code) (Solutions)

Day 2

Exercise: Stochastic simulation (continued)
Lecture: Parameter estimation
Exercise: Estimation (Code) (Solutions)
Lecture: Infectious disease management
Exercise: Pulsed vaccination (Code) (Solutions), Social distancing (Code) (Solutions)

Day 3

Lecture: Parameter uncertainty
Exercise: Sensitivity analysis of deterministic models through latin hypercube sampling – Ebola example (Code) (Solutions) Sensitivity analysis of deterministic models through latin hypercube sampling – HIV example (Code)
Lecture: Heterogeneities in contact
Exercise: Structured models for host heterogeneities (Code) (Solutions)

Further exercises

Exercise: Introduction to scientific programming in R (Code) (Solutions)
Exercise: Estimating model parameters through maximum likelihood (Code)
Exercise: The distribution of outbreak sizes: Immune escape and transmission of equine influenza (Code)
Exercise: Seasonally forced epidemics (Code)

Suggested reading (case studies)

Anonymous. 1978. Influenza in a boarding school. British Medical Journal 1:587.
Blower, S.M., H. B. Gershengorn, R.M.. 2000. A tale of two futures: HIV and antiretroviral therapy in San Francisco. Science 287:650-654.
Grais, R.F., M.J. Ferrari, C. Dubray, O.N. Bjornstad, B.T. Grenfell, A. Djibo, F. Fermon, P.J. Guerin. 2006. Estimating transmission intensity for a measles epidemic in Niamey, Niger: Lessons for intervention. Transactions of the Royal Society of Tropical Medicine and Hygiene 100:867-873.
Legrand, J., R.F. Grais, P.Y. Boelle, A.J. Valleron, & A. Flahault. 2007. Understanding the dynamics of Ebola epidemics. Epidemiology & Infection 135:610-621.
Park, A.W., J.M. Daly, N.S. Lewis, D.J. Smith, J.L.N. Wood, B.T. Grenfell. 2009. Quantifying the impact of immune escape on transmission dynamics of influenza. Science 326:726-728.
Read, J., Lessler, J., Riley, S., Wang, S., Tan, L.J., Kwok, K.O., et al. 2014. Social mixing patterns in rural and urban areas of southern China. Proceedings of the Royal Society B: Biological Sciences 281:20140268.
Rohani, P., Zhong, X., & King, A. A. 2010. Contact network structure explains the changing epidemiology of pertussis. Science 330:982–985.
Schenzle, D. 1984. An age-structured model of pre- and post-vaccination measles transmissiont . IMA Journal of Mathematics Applied in Medicine and Biology 1:169–191.

Suggested reading (modeling infectious diseases)

Keeling, M.J. & P. Rohani. 2007. Modeling infectious diseases in humans and animals. Princeton University Press.
Vynnyky, E., & R. White. 2010. An introduction to infectious disease modelling. Oxford University Press.
Heesterbeek, J. A. P., & Roberts, M. G. 2007. The type-reproduction number T in models for infectious disease control. Mathematical Biosciences 206(1):3–10.
Diekmann, O., Heesterbeek, J. A. P., & Roberts, M. G. 2009. The construction of next-generation matrices for compartmental epidemic models. Journal of the Royal Society Interface 7:873–885.
Mossong, J. E. L., Hens, N., Jit, M., Beutels, P., Auranen, K., Mikolajczyk, R., et al. 2008. Social contacts and mixing patterns relevant to the spread of infectious diseases. PLoS Medicine 5:e74.

Suggested reading (programming in R)

Crawley, M.J. 2007. The R book. Wiley.
Matloff, N. 2011. The Art of R Programming. No Starch Press.
Venables, W.N., & B.D Ripley. 2002. Modern Applied Statistics with S. 4th edition. Springer.
Jones, O., R. Maillardet, & A. Robinson. 2014. Introduction to scientific programming and simulation with R. Second edition. Chapman & Hall.

Lab Mission

Our lab uses experiments, field data, and quantitative models to characterize and understand the dynamic and stochastic processes that determine fluctuations, spatial distribution, and extinction of biological populations. Our overarching aim is to produce socially responsible and actionable scientific knowledge in the service of human and environmental welfare.

Research areas

Areas of interest include the theory of extinction, the problem of coexistence, emergence and spread of infectious diseases, management of invasive species, and critical phenomena in ecology and epidemiology. Applications of our work include epidemic preparedness and forecasting (in both wildlife and human populations), conservation of rare and endangered species, and management of invasive species.

Contact

John M. Drake
140 E. Green St.
Odum School of Ecology
University of Georgia
Athens, GA 30602-2202
email: jdrake@uga.edu

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