Author: McGough, Sarah F.; Johansson, Michael A.; Lipsitch, Marc; Menzies, Nicolas A.
Title: Nowcasting by Bayesian Smoothing: A flexible, generalizable model for real-time epidemic tracking Cord-id: odm1asa9 Document date: 2020_4_6
ID: odm1asa9
Snippet: Achieving accurate, real-time estimates of disease activity is challenged by delays in case reporting. “Nowcast†approaches attempt to estimate the complete case counts for a given reporting date, using a time series of case reports that is known to be incomplete due to reporting delays. Modeling the reporting delay distribution is a common feature of nowcast approaches. However, many nowcast approaches ignore a crucial feature of infectious disease transmission—that future cases are intri
Document: Achieving accurate, real-time estimates of disease activity is challenged by delays in case reporting. “Nowcast†approaches attempt to estimate the complete case counts for a given reporting date, using a time series of case reports that is known to be incomplete due to reporting delays. Modeling the reporting delay distribution is a common feature of nowcast approaches. However, many nowcast approaches ignore a crucial feature of infectious disease transmission—that future cases are intrinsically linked to past reported cases—and are optimized to one or two applications, which may limit generalizability. Here, we present a Bayesian approach, NobBS (Nowcasting by Bayesian Smoothing) capable of producing smooth and accurate nowcasts in multiple disease settings. We test NobBS on dengue in Puerto Rico and influenza-like illness (ILI) in the United States to examine performance and robustness across settings exhibiting a range of common reporting delay characteristics (from stable to time-varying), and compare this approach with a published nowcasting software package while investigating the features of each approach that contribute to good or poor performance. We show that introducing a temporal relationship between cases considerably improves performance when the reporting delay distribution is time-varying, and we identify trade-offs in the role of moving windows to accurately capture changes in the delay. We present software implementing this new approach (R package “NobBSâ€) for widespread application and provide practical guidance on implementation.
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