Your search keyword '"Roster, Kirstin"' showing total 2 results

1. Forecasting infectious diseases in Brazilian cities: Integrating socio-economic and geographic data from related cities through a machine learning approach.

Author

Lober, Luiza, Roster, Kirstin O., and Rodrigues, Francisco A.

Subjects

*MACHINE learning, *SUPERVISED learning, *CITIES & towns, *HUMAN behavior, *COMMUNICABLE diseases

Abstract

Supervised machine learning models and public surveillance data have been employed for infectious disease forecasting in many settings. These models leverage various data sources capturing drivers of disease spread, such as climate conditions or human behavior. However, few models have incorporated the organizational structure of different geographic locations for forecasting. Traveling waves of seasonal outbreaks have been reported for dengue, influenza, and other infectious diseases, and many of the drivers of infectious disease dynamics may be shared across different cities, either due to their geographic or socioeconomic proximity. In this study, we developed a machine learning model to predict case counts of four infectious diseases across Brazilian cities one week ahead by incorporating information from related cities. We compared selecting related cities using both geographic distance and GDP per capita. Incorporating information from geographically proximate cities improved predictive performance for two of the four diseases, specifically COVID-19 and Zika. We also discuss the impact on forecasts in the presence of anomalous contagion patterns and the limitations of the proposed methodology. • The study explores how geographic and socioeconomic proximities affect disease forecasts. • Incorporating geographically proximate cities improved forecasts for COVID-19 and Zika. • The model predicts infectious disease case counts in Brazilian cities one week ahead. [ABSTRACT FROM AUTHOR]

Published

2024

2. Forecasting new diseases in low-data settings using transfer learning.

Author

Roster, Kirstin, Connaughton, Colm, and Rodrigues, Francisco A.

Subjects

*TRANSFER of training, *DISEASE outbreaks, *COMMUNICABLE diseases, *COVID-19 pandemic, *MACHINE learning, *INFLUENZA, *ARBOVIRUS diseases

Abstract

Recent infectious disease outbreaks, such as the COVID-19 pandemic and the Zika epidemic in Brazil, have demonstrated both the importance and difficulty of accurately forecasting novel infectious diseases. When new diseases first emerge, we have little knowledge of the transmission process, the level and duration of immunity to reinfection, or other parameters required to build realistic epidemiological models. Time series forecasts and machine learning, while less reliant on assumptions about the disease, require large amounts of data that are also not available in early stages of an outbreak. In this study, we examine how knowledge of related diseases can help make predictions of new diseases in data-scarce environments using transfer learning. We implement both an empirical and a synthetic approach. Using data from Brazil, we compare how well different machine learning models transfer knowledge between two different dataset pairs: case counts of (i) dengue and Zika, and (ii) influenza and COVID-19. In the synthetic analysis, we generate data with an SIR model using different transmission and recovery rates, and then compare the effectiveness of different transfer learning methods. We find that transfer learning offers the potential to improve predictions, even beyond a model based on data from the target disease, though the appropriate source disease must be chosen carefully. While imperfect, these models offer an additional input for decision makers for pandemic response. • Comparing transfer learning with random forest & neural networks and instance-based & parameter transfer methods • Predicting Zika and COVID-19 case counts and simulated data from an SIR compartmental model • Transfer learning can help approximate or outperform machine learning models trained on larger dataset of the target disease • NN models performed better for diseases with similar epidemiological parameters, RF for diseases with less similar parameters [ABSTRACT FROM AUTHOR]

Published

2022