A Review of Multi‐Compartment Infectious Disease Models

Summary Multi‐compartment models have been playing a central role in modelling infectious disease dynamics since the early 20th century. They are a class of mathematical models widely used for describing the mechanism of an evolving epidemic. Integrated with certain sampling schemes, such mechanistic models can be applied to analyse public health surveillance data, such as assessing the effectiveness of preventive measures (e.g. social distancing and quarantine) and forecasting disease spread patterns. This review begins with a nationwide macromechanistic model and related statistical analyses, including model specification, estimation, inference and prediction. Then, it presents a community‐level micromodel that enables high‐resolution analyses of regional surveillance data to provide current and future risk information useful for local government and residents to make decisions on reopenings of local business and personal travels. r software and scripts are provided whenever appropriate to illustrate the numerical detail of algorithms and calculations. The coronavirus disease 2019 pandemic surveillance data from the state of Michigan are used for the illustration throughout this paper.

[1]  Benjamin J Cowling,et al.  Viral Shedding and Transmission Potential of Asymptomatic and Paucisymptomatic Influenza Virus Infections in the Community , 2016, Clinical infectious diseases : an official publication of the Infectious Diseases Society of America.

[2]  Anna T. Lawniczak,et al.  Individual-based lattice model for spatial spread of epidemics , 2002, nlin/0207048.

[3]  V. Isham,et al.  Modeling infectious disease dynamics in the complex landscape of global health , 2015, Science.

[4]  Shariq Mohammed,et al.  Predictions, role of interventions and effects of a historic national lockdown in India's response to the COVID-19 pandemic: data science call to arms , 2020, medRxiv.

[5]  Tom Britton,et al.  Stochastic epidemic models: a survey. , 2009, Mathematical biosciences.

[6]  C. Czado,et al.  State space mixed models for longitudinal observations with binary and binomial responses , 2008 .

[7]  Xihong Lin,et al.  Association of Public Health Interventions With the Epidemiology of the COVID-19 Outbreak in Wuhan, China. , 2020, JAMA.

[8]  R. Peng Reproducible Research in Computational Science , 2011, Science.

[9]  Marcello Ienca,et al.  On the responsible use of digital data to tackle the COVID-19 pandemic , 2020, Nature Medicine.

[10]  Alfred Ramani,et al.  Epidemic dynamics: discrete-time and cellular automaton models , 2003 .

[11]  Nicholas P. Jewell,et al.  Caution Warranted: Using the Institute for Health Metrics and Evaluation Model for Predicting the Course of the COVID-19 Pandemic , 2020, Annals of Internal Medicine.

[12]  Yiu Chung Lau,et al.  Temporal dynamics in viral shedding and transmissibility of COVID-19 , 2020, Nature Medicine.

[13]  Nino Boccara,et al.  A probabilistic automata network epidemic model with births and deaths exhibiting cyclic behaviour , 1994 .

[14]  H. Andersson,et al.  Stochastic Epidemic Models and Their Statistical Analysis , 2000 .

[15]  M. Lipsitch,et al.  How generation intervals shape the relationship between growth rates and reproductive numbers , 2007, Proceedings of the Royal Society B: Biological Sciences.

[16]  Alexander Grey,et al.  The Mathematical Theory of Infectious Diseases and Its Applications , 1977 .

[17]  Mudassar Imran,et al.  Estimating the basic reproductive ratio for the Ebola outbreak in Liberia and Sierra Leone , 2015, Infectious Diseases of Poverty.

[18]  D. Cummings,et al.  Strategies for mitigating an influenza pandemic , 2006, Nature.

[19]  J. Lambert Numerical Methods for Ordinary Differential Equations , 1991 .

[20]  Jin Zhen,et al.  Cellular automata modelling of SEIRS , 2005 .

[21]  J. Wallinga,et al.  Different Epidemic Curves for Severe Acute Respiratory Syndrome Reveal Similar Impacts of Control Measures , 2004, American journal of epidemiology.

[22]  Rohit Varma,et al.  On Identifying and Mitigating Bias in the Estimation of the COVID-19 Case Fatality Rate , 2020, medRxiv.

[23]  Olivier Gossner,et al.  Group testing against Covid-19 , 2020 .

[24]  John K Kruschke,et al.  Bayesian data analysis. , 2010, Wiley interdisciplinary reviews. Cognitive science.

[25]  A. Kabiri,et al.  Interactive COVID-19 Mobility Impact and Social Distancing Analysis Platform , 2020, medRxiv.

[26]  Lucia Russo,et al.  Mathematical modeling of infectious disease dynamics , 2013, Virulence.

[27]  Ángel Martín del Rey,et al.  Modeling epidemics using cellular automata , 2006, Applied Mathematics and Computation.

[28]  C. Whittaker,et al.  Estimates of the severity of coronavirus disease 2019: a model-based analysis , 2020, The Lancet Infectious Diseases.

[29]  K. Dietz The estimation of the basic reproduction number for infectious diseases , 1993, Statistical methods in medical research.

[30]  Jing Zhao,et al.  Early Transmission Dynamics in Wuhan, China, of Novel Coronavirus–Infected Pneumonia , 2020, The New England journal of medicine.

[31]  Peter X.-K. Song,et al.  A Spatiotemporal Epidemiological Prediction Model to Inform County-Level COVID-19 Risk in the United States , 2020 .

[32]  P. Kaye Infectious diseases of humans: Dynamics and control , 1993 .

[33]  Behrooz Hassani,et al.  A MULTI-OBJECTIVE STRUCTURAL OPTIMIZATION USING OPTIMALITY CRITERIA AND CELLULAR AUTOMATA , 2007 .

[34]  W. Liang,et al.  Clinical characteristics of 2019 novel coronavirus infection in China , 2020, medRxiv.

[35]  L. Allen An Introduction to Stochastic Epidemic Models , 2008 .

[36]  G. Sirakoulis,et al.  A cellular automaton model for the effects of population movement and vaccination on epidemic propagation , 2000 .

[37]  Herbert W. Hethcote,et al.  The Mathematics of Infectious Diseases , 2000, SIAM Rev..

[38]  Bin Zhu,et al.  Semiparametric Stochastic Modeling of the Rate Function in Longitudinal Studies , 2011, Journal of the American Statistical Association.

[39]  John Samuel,et al.  A simple cellular automaton model for influenza A viral infections. , 2004, Journal of theoretical biology.

[40]  Luís M A Bettencourt,et al.  The estimation of the effective reproductive number from disease outbreak data. , 2009, Mathematical biosciences and engineering : MBE.

[41]  D. Rubin,et al.  Inference from Iterative Simulation Using Multiple Sequences , 1992 .

[42]  R N Thompson,et al.  Improved inference of time-varying reproduction numbers during infectious disease outbreaks , 2019, Epidemics.

[43]  A. M'Kendrick Applications of Mathematics to Medical Problems , 1925, Proceedings of the Edinburgh Mathematical Society.

[44]  Hugues Chaté,et al.  Dynamical phases in a cellular automaton model for epidemic propagation , 1997 .

[45]  Zhen Jin,et al.  Spatial organization and evolution period of the epidemic model using cellular automata. , 2006, Physical review. E, Statistical, nonlinear, and soft matter physics.

[46]  Gerardo Chowell,et al.  Forecasting Epidemics Through Nonparametric Estimation of Time-Dependent Transmission Rates Using the SEIR Model , 2017, Bulletin of Mathematical Biology.

[47]  Cynthia Dwork,et al.  Differential Privacy: A Survey of Results , 2008, TAMC.

[48]  J. Hyman,et al.  Model Parameters and Outbreak Control for SARS , 2004, Emerging infectious diseases.

[49]  Andrew Gelman,et al.  General methods for monitoring convergence of iterative simulations , 1998 .

[50]  Hannah R. Meredith,et al.  The Incubation Period of Coronavirus Disease 2019 (COVID-19) From Publicly Reported Confirmed Cases: Estimation and Application , 2020, Annals of Internal Medicine.

[51]  J. Gani,et al.  Cellular automaton modeling of epidemics , 1990 .

[52]  L Forsberg White,et al.  A likelihood‐based method for real‐time estimation of the serial interval and reproductive number of an epidemic , 2008, Statistics in medicine.

[53]  B. Finkenstädt,et al.  Statistical Inference in a Stochastic Epidemic SEIR Model with Control Intervention: Ebola as a Case Study , 2006, Biometrics.

[54]  David B. Fogel,et al.  An introduction to simulated evolutionary optimization , 1994, IEEE Trans. Neural Networks.

[55]  C. Murray Forecasting COVID-19 impact on hospital bed-days, ICU-days, ventilator-days and deaths by US state in the next 4 months , 2020, medRxiv.

[56]  D. Adam Special report: The simulations driving the world’s response to COVID-19 , 2020, Nature.

[57]  Jia Gu,et al.  Tracking Reproductivity of COVID-19 Epidemic in China with Varying Coefficient SIR Model , 2021 .

[58]  Lei Zhang,et al.  Observed mobility behavior data reveal social distancing inertia , 2020, ArXiv.

[59]  N. Becker,et al.  An estimation procedure for household disease data , 1979 .

[60]  T. Britton,et al.  Statistical studies of infectious disease incidence , 1999 .

[61]  E. Nadaraya On Estimating Regression , 1964 .

[62]  Timothy J. Robinson,et al.  Sequential Monte Carlo Methods in Practice , 2003 .

[63]  Lu Tang,et al.  An epidemiological forecast model and software assessing interventions on COVID-19 epidemic in China , 2020, medRxiv.

[64]  Dave Higdon,et al.  Forecasting seasonal influenza with a state-space SIR model. , 2017, The annals of applied statistics.

[65]  Etienne Joly,et al.  Faculty Opinions recommendation of Temperature and Latitude Analysis to Predict Potential Spread and Seasonality for COVID-19. , 2020 .

[66]  Nicholas G. Polson,et al.  Tracking Epidemics With Google Flu Trends Data and a State-Space SEIR Model , 2012, Journal of the American Statistical Association.

[67]  Xin Gao,et al.  Composite Likelihood EM Algorithm with Applications to Multivariate Hidden Markov Model , 2009 .

[68]  Tom Britton,et al.  Stochastic Epidemic Models with Inference , 2019, Lecture Notes in Mathematics.

[69]  N. Reid,et al.  AN OVERVIEW OF COMPOSITE LIKELIHOOD METHODS , 2011 .

[70]  Kendrick,et al.  Applications of Mathematics to Medical Problems , 1925, Proceedings of the Edinburgh Mathematical Society.

[71]  J. Murray,et al.  On the spatial spread of rabies among foxes. , 1992, Proceedings of the Royal Society of London. Series B, Biological sciences.

[72]  H. Agiza,et al.  On modeling epidemics. Including latency, incubation and variable susceptibility , 1998 .

[73]  Charles F. F. Karney Algorithms for geodesics , 2011, Journal of Geodesy.

[74]  Yuan Ji,et al.  Semiparametric Bayesian inference for the transmission dynamics of COVID-19 with a state-space model , 2020, Contemporary Clinical Trials.

[75]  Marcelo N. Kuperman,et al.  Cellular automata and epidemiological models with spatial dependence , 1999 .

[76]  Spiros Denaxas,et al.  Estimating excess 1-year mortality associated with the COVID-19 pandemic according to underlying conditions and age: a population-based cohort study , 2020, The Lancet.

[77]  G Katriel,et al.  Mathematical modelling and prediction in infectious disease epidemiology. , 2013, Clinical microbiology and infection : the official publication of the European Society of Clinical Microbiology and Infectious Diseases.

[78]  W. Rida,et al.  Asymptotic Properties of Some Estimators for the Infection Rate in the General Stochastic Epidemic Model , 1991 .

[79]  John von Neumann,et al.  Theory Of Self Reproducing Automata , 1967 .

[80]  J. Rocklöv,et al.  The reproductive number of COVID-19 is higher compared to SARS coronavirus , 2020, Journal of travel medicine.

[81]  C. Fraser,et al.  A New Framework and Software to Estimate Time-Varying Reproduction Numbers During Epidemics , 2013, American journal of epidemiology.

[82]  N. Shephard,et al.  The simulation smoother for time series models , 1995 .

[83]  D Mollison,et al.  Dependence of epidemic and population velocities on basic parameters. , 1991, Mathematical biosciences.

[84]  N G Becker,et al.  On a general stochastic epidemic model. , 1977, Theoretical population biology.

[85]  G. S. Watson,et al.  Smooth regression analysis , 1964 .

[86]  Bradley P. Carlin,et al.  Bayesian measures of model complexity and fit , 2002 .

[87]  W. O. Kermack,et al.  A contribution to the mathematical theory of epidemics , 1927 .

[88]  Parham Habibzadeh,et al.  Temperature, Humidity and Latitude Analysis to Predict Potential Spread and Seasonality for COVID-19. , 2020, SSRN.

[89]  W. Cleveland,et al.  Locally Weighted Regression: An Approach to Regression Analysis by Local Fitting , 1988 .

[90]  Zhen Jin,et al.  Phase transition in spatial epidemics using cellular automata with noise , 2011, Ecological Research.

[91]  Jay P Shimshack,et al.  Absolute humidity, temperature, and influenza mortality: 30 years of county-level evidence from the United States. , 2012, American journal of epidemiology.

[92]  Matthias Cavassini,et al.  [Infectious diseases]. , 2014, Revue medicale suisse.

[93]  Pierre-Yves Boëlle,et al.  The R0 package: a toolbox to estimate reproduction numbers for epidemic outbreaks , 2012, BMC Medical Informatics and Decision Making.

[94]  K. Dietz,et al.  The Incidence of Infectious Diseases under the Influence of Seasonal Fluctuations , 1976 .

[95]  K. Chan,et al.  Monte Carlo EM Estimation for Time Series Models Involving Counts , 1995 .

[96]  L. Bettencourt,et al.  Real Time Bayesian Estimation of the Epidemic Potential of Emerging Infectious Diseases , 2008, PloS one.

[97]  A. Lloyd,et al.  Nine challenges for deterministic epidemic models , 2014, Epidemics.

[98]  Nicholas G. Polson,et al.  A Monte Carlo Approach to Nonnormal and Nonlinear State-Space Modeling , 1992 .