TY - JOUR
T1 - Breaking beta
T2 - Deconstructing the parasite transmission function
AU - McCallum, Hamish
AU - Fenton, Andy
AU - Hudson, Peter J.
AU - Lee, Brian
AU - Levick, Beth
AU - Norman, Rachel
AU - Perkins, Sarah E.
AU - Viney, Mark
AU - Wilson, Anthony J.
AU - Lello, Joanne
N1 - Publisher Copyright:
© 2017 The Authors.
PY - 2017/3/5
Y1 - 2017/3/5
N2 - Transmission is a fundamental step in the life cycle of every parasite but it is also one of the most challenging processes to model and quantify. In most host-parasite models, the transmission process is encapsulated by a single parameter b. Many different biological processes and interactions, acting on both hosts and infectious organisms, are subsumed in this single term. There are, however, at least two undesirable consequences of this high level of abstraction. First, nonlinearities and heterogeneities that can be critical to the dynamic behaviour of infections are poorly represented; second, estimating the transmission coefficient b from field data is often very difficult. In this paper,we present a conceptual model, which breaks the transmission process into its component parts. This deconstruction enables us to identify circumstances that generate nonlinearities in transmission, with potential implications for emergent transmission behaviour at individual and population scales. Such behaviour cannot be explained by the traditional linear transmission frameworks. The deconstruction also provides a clearer link to the empirical estimation of key components of transmission and enables the construction of flexible models that produce a unified understanding of the spread of both micro-and macro-parasite infectious disease agents.
AB - Transmission is a fundamental step in the life cycle of every parasite but it is also one of the most challenging processes to model and quantify. In most host-parasite models, the transmission process is encapsulated by a single parameter b. Many different biological processes and interactions, acting on both hosts and infectious organisms, are subsumed in this single term. There are, however, at least two undesirable consequences of this high level of abstraction. First, nonlinearities and heterogeneities that can be critical to the dynamic behaviour of infections are poorly represented; second, estimating the transmission coefficient b from field data is often very difficult. In this paper,we present a conceptual model, which breaks the transmission process into its component parts. This deconstruction enables us to identify circumstances that generate nonlinearities in transmission, with potential implications for emergent transmission behaviour at individual and population scales. Such behaviour cannot be explained by the traditional linear transmission frameworks. The deconstruction also provides a clearer link to the empirical estimation of key components of transmission and enables the construction of flexible models that produce a unified understanding of the spread of both micro-and macro-parasite infectious disease agents.
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U2 - 10.1098/rstb.2016.0084
DO - 10.1098/rstb.2016.0084
M3 - Article
C2 - 28289252
AN - SCOPUS:85015159197
SN - 0962-8436
VL - 372
JO - Philosophical Transactions of the Royal Society B: Biological Sciences
JF - Philosophical Transactions of the Royal Society B: Biological Sciences
IS - 1719
M1 - 20160084
ER -