2022 journal article

Multiple species animal movements: network properties, disease dynamics and the impact of targeted control actions

VETERINARY RESEARCH, 53(1).

By: N. Cardenas n, A. Sykes n, F. Lopes* & G. Machado n

co-author countries: Brazil 🇧🇷 United States of America 🇺🇸
MeSH headings : Animal Husbandry / methods; Animals; Cattle; Cattle Diseases / epidemiology; Cattle Diseases / prevention & control; Epidemics / veterinary; Farms; Livestock; Swine; Swine Diseases / epidemiology; Transportation
Source: Web Of Science
Added: March 7, 2022

Infectious diseases in livestock are well-known to infect multiple hosts and persist through a combination of within- and between-host transmission pathways. Uncertainty remains about the epidemic dynamics of diseases being introduced on farms with more than one susceptible host species. Here, we describe multi-host contact networks and elucidate the potential of disease spread through farms with multiple hosts. Four years of between-farm animal movement among all farms of a Brazilian state were described through a static and monthly snapshot of network representations. We developed a stochastic multilevel model to simulate scenarios in which infection was seeded into single host and multi-host farms to quantify disease spread potential, and simulate network-based control actions used to evaluate the reduction of secondarily infected farms. We showed that the swine network was more connected than cattle and small ruminants in both the static and monthly snapshots. The small ruminant network was highly fragmented, however, contributed to interconnecting farms, with other hosts acting as intermediaries throughout the networks. When a single host was initially infected, secondary infections were observed across farms with all other species. Our stochastic multi-host model demonstrated that targeting the top 3.25% of the farms ranked by degree reduced the number of secondarily infected farms. The results of the simulation highlight the importance of considering multi-host dynamics and contact networks while designing surveillance and preparedness control strategies against pathogens known to infect multiple species.