The spectral underpinnings of pathogen spread on animal networks.
Nicholas M Fountain-JonesMathew SilkRaima Carol AppawRodrigo HamedeJulie RushmoreKimberly L VanderWaalMeggan E CraftScott CarverMichael CharlestonPublished in: Proceedings. Biological sciences (2023)
Predicting what factors promote or protect populations from infectious disease is a fundamental epidemiological challenge. Social networks, where nodes represent hosts and edges represent direct or indirect contacts between them, are important in quantifying these aspects of infectious disease dynamics. However, how network structure and epidemic parameters interact in empirical networks to promote or protect animal populations from infectious disease remains a challenge. Here we draw on advances in spectral graph theory and machine learning to build predictive models of pathogen spread on a large collection of empirical networks from across the animal kingdom. We show that the spectral features of an animal network are powerful predictors of pathogen spread for a variety of hosts and pathogens and can be a valuable proxy for the vulnerability of animal networks to pathogen spread. We validate our findings using interpretable machine learning techniques and provide a flexible web application for animal health practitioners to assess the vulnerability of a particular network to pathogen spread.
Keyphrases
- infectious diseases
- machine learning
- candida albicans
- optical coherence tomography
- healthcare
- climate change
- mental health
- primary care
- public health
- artificial intelligence
- magnetic resonance imaging
- risk assessment
- magnetic resonance
- antimicrobial resistance
- general practice
- multidrug resistant
- locally advanced
- solid state