Abstract
BackgroundSimple phenomenological growth models can be useful for estimating transmission parameters and forecasting epidemic trajectories. However, most existing phenomenological growth models only support single-peak outbreak dynamics whereas real epidemics often display more complex transmission trajectories.MethodsWe develop and apply a novel sub-epidemic modeling framework that supports a diversity of epidemic trajectories including stable incidence patterns with sustained or damped oscillations to better understand and forecast epidemic outbreaks. We describe how to forecast an epidemic based on the premise that the observed coarse-scale incidence can be decomposed into overlapping sub-epidemics at finer scales. We evaluate our modeling framework using three outbreak datasets: Severe Acute Respiratory Syndrome (SARS) in Singapore, plague in Madagascar, and the ongoing Ebola outbreak in the Democratic Republic of Congo (DRC) and four performance metrics.ResultsThe sub-epidemic wave model outperforms simpler growth models in short-term forecasts based on performance metrics that account for the uncertainty of the predictions namely the mean interval score (MIS) and the coverage of the 95% prediction interval. For example, we demonstrate how the sub-epidemic wave model successfully captures the 2-peak pattern of the SARS outbreak in Singapore. Moreover, in short-term sequential forecasts, the sub-epidemic model was able to forecast the second surge in case incidence for this outbreak, which was not possible using the simple growth models. Furthermore, our findings support the view that the national incidence curve of the Ebola epidemic in DRC follows a stable incidence pattern with periodic behavior that can be decomposed into overlapping sub-epidemics.ConclusionsOur findings highlight how overlapping sub-epidemics can capture complex epidemic dynamics, including oscillatory behavior in the trajectory of the epidemic wave. This observation has significant implications for interpreting apparent noise in incidence data where the oscillations could be dismissed as a result of overdispersion, rather than an intrinsic part of the epidemic dynamics. Unless the oscillations are appropriately modeled, they could also give a false positive, or negative, impression of the impact from public health interventions. These preliminary results using sub-epidemic models can help guide future efforts to better understand the heterogenous spatial and social factors shaping sub-epidemic patterns for other infectious diseases.
Highlights
The myriad of interrelated, and often unobserved, factors that influence the propagation of pathogens at different spatial and temporal scales create major challenges for predicting the transmission dynamics of infectious disease [1]
The factors influencing infectious disease transmission include the mode of transmission, the individual-level network that captures the dynamics of disease-relevant interactions [2], the natural history of the disease, variations in the risk behavior of individuals, reactive public health interventions, the behavior changes in response to an epidemic, and the background immunity of the population shaped by genetic factors and prior exposure to the disease or vaccination campaigns [3,4,5,6]
Mathematical framework of epidemic waves composed of overlapping sub-epidemics We model each group sub-epidemic by a generalizedlogistic growth model (GLM) which has displayed promising performance for short-term forecasting the trajectory of emerging infectious disease outbreaks [20,21,22]
Summary
The myriad of interrelated, and often unobserved, factors that influence the propagation of pathogens at different spatial and temporal scales create major challenges for predicting the transmission dynamics of infectious disease [1]. Our ability to generate accurate epidemic forecasts is challenged by the sparse data on the individual- and grouplevel heterogeneity that affect the dynamics of infectious disease transmission [7,8,9]. Epidemic incidence data is a valuable epidemiological tool to assess, and forecast, trends and transmission potential in real time [7, 8, 10,11,12,13,14]. The aggregated case data rarely contain the information, such as transmission pathways and other population characteristics, needed to create a realistic model for disease transmission [8]. Most existing phenomenological growth models only support singlepeak outbreak dynamics whereas real epidemics often display more complex transmission trajectories
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