Inferring Bovine Tuberculosis Transmission Between Cattle and Badgers Via the Environment and Risk Mapping

Overview

Journal Front Vet Sci

Specialty Veterinary Medicine

Date 2023 Oct 16

PMID 37841461

Authors

You Chang

Nienke Hartemink

Andrew W Byrne

Eamonn Gormley

Guy McGrath

Jamie A Tratalos

Philip Breslin

Simon J More

Mart C M de Jong

Affiliations

Soon will be listed here.

Abstract

Bovine tuberculosis (bTB), caused by , is one of the most challenging and persistent health issues in many countries worldwide. In several countries, bTB control is complicated due to the presence of wildlife reservoirs of infection, i.e. European badger () in Ireland and the UK, which can transmit infection to cattle. However, a quantitative understanding of the role of cattle and badgers in bTB transmission is elusive, especially where there is spatial variation in relative density between badgers and cattle. Moreover, as these two species have infrequent direct contact, environmental transmission is likely to play a role, but the quantitative importance of the environment has not been assessed. Therefore, the objective of this study is to better understand bTB transmission between cattle and badgers via the environment in a spatially explicit context and to identify high-risk areas. We developed an environmental transmission model that incorporates both within-herd/territory transmission and between-species transmission, with the latter facilitated by badger territories overlapping with herd areas. Model parameters such as transmission rate parameters and the decay rate parameter of were estimated by maximum likelihood estimation using infection data from badgers and cattle collected during a 4-year badger vaccination trial. Our estimation showed that the environment can play an important role in the transmission of bTB, with a half-life of in the environment of around 177 days. Based on the estimated transmission rate parameters, we calculate the basic reproduction ratio (R) within a herd, which reveals how relative badger density dictates transmission. In addition, we simulated transmission in each small local area to generate a first between-herd R map that identifies high-risk areas.

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