Abstract
The spread of a communicable disease is a complex spatio-temporal process shaped by the specific transmission mechanism, and diverse factors including the behavior, socio-economic and demographic properties of the host population. While the key factors shaping transmission of influenza and COVID-19 are beginning to be broadly understood, making precise forecasts on case count and mortality is still difficult. In this study we introduce the concept of a universal geospatial risk phenotype of individual US counties facilitating flu-like transmission mechanisms. We call this the Universal Influenza-like Transmission (UnIT) score, which is computed as an information-theoretic divergence of the local incidence time series from an high-risk process of epidemic initiation, inferred from almost a decade of flu season incidence data gleaned from the diagnostic history of nearly a third of the US population. Despite being computed from the past seasonal flu incidence records, the UnIT score emerges as the dominant factor explaining incidence trends for the COVID-19 pandemic over putative demographic and socio-economic factors. The predictive ability of the UnIT score is further demonstrated via county-specific weekly case count forecasts which consistently outperform the state of the art models throughout the time-line of the COVID-19 pandemic. This study demonstrates that knowledge of past epidemics may be used to chart the course of future ones, if transmission mechanisms are broadly similar, despite distinct disease processes and causative pathogens.
Highlights
We are in the midst of a global pandemic caused by the novel coronavirus SARS-CoV-2, and reliable prediction of the future local and national case count is crucial for crafting effective intervention policies
This study introduces the concept of a universal risk phenotype for US counties that predictably increases the risk of person-to-person transmission of influenza-like illnesses; universal in the sense that it is pathogen-agnostic provided the transmission mechanism is similar to that of seasonal
Universal risk phenotype for transmissible respiratory illnesses new weekly case counts for all weeks up to the current point in time (2021-05-30) for 3094 US counties
Summary
We are in the midst of a global pandemic caused by the novel coronavirus SARS-CoV-2, and reliable prediction of the future local and national case count is crucial for crafting effective intervention policies. The spread of a transmissible virus is shaped by diverse interacting factors that are hard-to-model and respond to [1], including the specific transmission mechanism, the survivability of the pathogen outside the host under harsh environmental conditions, and the ease of access to susceptible hosts—determined in part by the density of the local population, its travel habits [1], and compliance to common-sense social distancing policies. While a broad set of putative factors shaping the spread of communicable viruses such as the seasonal Influenza and COVID-19 are increasingly becoming clear [4,5,6,7,8,9,10,11,12,13,14,15], making precise granular actionable forecasts of the case counts over time is still difficult.
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