Connected networks of sea lice populations : dynamics and implications for control

This work was supported by a grant from the European Fisheries Fund (European Union). Date of Acceptance: 14/04/2015 In studies of the population dynamics of parasitic sea lice and the implications of outbreaks for salmon farms, several types of mathematical models have been implemented. Delay diffe...

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Bibliographic Details
Published in:Aquaculture Environment Interactions
Main Authors: Adams, Thomas P., Proud, Roland, Black, Kenneth D.
Other Authors: University of St Andrews. School of Biology, University of St Andrews. Pelagic Ecology Research Group, University of St Andrews. Scottish Oceans Institute
Format: Article in Journal/Newspaper
Language:English
Published: 2015
Subjects:
Metapopulation
Spatial dynamics
Dispersal
Population connectivity
Sea lice management
Salmon salmo-salar
Farmed Atlantic salmon
Louse lepeophtheirus-salmonis
Mathematical-model
Scotland
Hardangerfjord
Dispersion
Infection
Growth
Trout
QH301 Biology
QL Zoology
QH301
QL
Atlantic salmon
Salmo salar
Online Access:http://hdl.handle.net/10023/7148
https://doi.org/10.3354/aei00133
Description
Summary:This work was supported by a grant from the European Fisheries Fund (European Union). Date of Acceptance: 14/04/2015 In studies of the population dynamics of parasitic sea lice and the implications of outbreaks for salmon farms, several types of mathematical models have been implemented. Delay differential equation models describe the temporal dynamics of average adult lice densities over many farm sites. In contrast, larval transport models consider the relative densities of lice at farm sites by modelling larval movements between them but do not account for temporal dynamics or feedbacks created by reproduction. Finally, several recent studies have investigated spatiotemporal variation in site lice abundances using statistical models and distance-based proxies for connectivity. We developed a model which integrates connectivity estimates from larval transport models into the delay differential equation framework. This allows representation of sea lice developmental stages, dispersal between sites, and the impact of management actions. Even with identical external infection rates, lice abundances differ dramatically between farms over a production cycle (dependent on oceanographic conditions and resulting between-farm connectivity). Once infected, lice dynamics are dominated by site reproduction and subsequent dispersal. Lice control decreases actual lice abundances and also reduces variation in abundance between sites (within each simulation) and between simulation runs. Control at sites with the highest magnitude of incoming connections, computed directly from connectivity modelling, had the greatest impact on lice abundances across all sites. Connectivity metrics may therefore be a reasonable approximation of the effectiveness of management practices at particular sites. However, the model also provides new opportunities for investigation and prediction of lice abundances in interconnected systems with spatially varying infection and management. Publisher PDF Peer reviewed

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