The relevance of larval biology on spatiotemporal patterns of pathogen connectivity among open-marine salmon farms

Cantrell, Danielle L.; Filgueira, Ramón; Revie, Crawford W.; Rees, Erin E.; Vanderstichel, Raphaël; Guo, Ming; Foreman, Michael; Wan, Di; Grant, Jon E.

doi:10.1139/cjfas-2019-0040

Cited by 14 publications

(8 citation statements)

References 67 publications

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“…Our simulations lack any influence of salinity on mortality (Bricknell et al 2006), or vertical movement of lice from the surface layers (Crosbie et al 2019) or the impacts of vertical diffusion (Visser 1997, Ross & Sharples 2004. These factors, and their interactions, have been found in some other studies to be important in determining the outcome of dispersal events (Johnsen et al 2016, Cantrell et al 2020, and are obvious candidates for future refinements to the dispersal model used here.…”

Section: Discussionmentioning

confidence: 72%

“…In order to characterise the spatial distribution of lice in the coastal environment, many studies have implemented biophysical models to describe the dispersal process. This research has been carried out over many years in all major salmon producing areas (Murray & Gillibrand 2006, Amundrud & Murray 2009, Stucchi et al 2010, Salama & Rabe 2013, Kragesteen et al 2018, Myksvoll et al 2018, Cantrell et al 2020, and has led to suggestions on approaches to managing aquaculture operations at local and regional scales (Adams et al 2015, Samsing et al 2019.…”

Section: Introductionmentioning

confidence: 99%

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Validating a biophysical parasite model with fish farm pen and plankton trawl data

Adams

Marshall²,

Brown³

et al. 2021

Aquacult. Environ. Interact.

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Biophysical models of parasite dispersal are being increasingly used as a method for screening marine aquaculture developments, whether in establishment of new sites or expansion of existing sites, or planning of farmed fish health management strategies on local or regional spatial scales. How well these models reflect reality, however, is often brought into question, due to the difficulties in validating their outputs. Larval parasitic sea lice can spend up to around 14 d in the water column, as a result potentially travelling several 10s of km between farms. Lice distribution in the water column is typically patchy and low density. Furthermore, infection can occur from lice carried by wild fish. Combined with rapid population turnover and larval exchange between farms, this causes difficulties in attributing links between juvenile lice and their sources. We sought to validate a biophysical model of sea lice dispersal using plankton trawl abundance data and farm site juvenile lice counts. Unusually high farm lice abundances over the study period allowed model predictions of larval density to be compared with trawled samples, in addition to mapping the link between parent and offspring lice counts found on farm sites. We compared the prediction of the larval dispersal model with a site neighbourhood-based metric of infection pressure. Our results validate the ability of the model to predict variation in larval density over time and space and suggest an exponential relationship between estimated infection pressure and observed site juvenile count.

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Section: Discussionmentioning

confidence: 72%

Section: Introductionmentioning

confidence: 99%

Validating a biophysical parasite model with fish farm pen and plankton trawl data

Adams

Marshall²,

Brown³

et al. 2021

Aquacult. Environ. Interact.

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“…In order to use the next-generation matrix to calculate patch contribution or persistence we are assuming that our system is autonomous, and that the demographic rates do not change with time. In reality for most systems, including sea lice on salmon farms, environmental variables will fluctuate over time, potentially changing the demographic rates of the population [68]. In our case temperature and salinity change over the course of the spring, but we calculate the next-generation matrix using the mean temperature and salinity that sea lice experience during the particle tracking simulation window.…”

Section: Discussionmentioning

confidence: 99%

Next-generation matrices for marine metapopulations: the case of sea lice on salmon farms^*

Harrington

Cantrell

Lewis

2022

Preprint

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Classifying habitat patches as sources or sinks and determining metapopulation persistence requires coupling connectivity between habitat patches with local demographic rates. In this paper we show how next-generation matrices, originally popularized in epidemiology to calculate new infections after one generation, can be used in an ecological context to couple connectivity with local demography to calculate sources and sinks as well as metapopulation persistence in marine metapopulations. To demonstrate the utility of the method, we construct a next-generation matrix for a network of sea lice populations on salmon farms in the Broughton Archipelago, BC, an intensive salmon farming region on the west coast of Canada where certain salmon farms are currently being removed under an agreement between local First Nations and the provincial government. We identify the salmon farms which are acting as the largest sources of sea lice and show that in this region the most productive sea lice populations are also the most connected. We find that the farms which are the largest sources of sea lice have not yet been removed from the Broughton Archipelago, and that warming temperatures could lead to increased sea louse growth.

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“…The application of different methods to the dataset may reveal variability in the impact of infestation pressures estimated (e.g. Cantrell et al., 2019 ; Kristoffersen et al., 2014 ).…”

Section: Discussionmentioning

confidence: 99%

“…Aldrin et al, 2013Aldrin et al, , 2019Kristoffersen et al, 2013Kristoffersen et al, , 2014Kristoffersen et al, , 2018. Cantrell et al, (2018Cantrell et al, ( , 2019 defined infestation pressure as the density of particles representing sea lice using a biophysical model in the Broughton Archipelago, British Columbia (BC). Sandvik et al, (2016) defined infestation pressure on a scale of low (0-1 louse) to high (>10 lice) resulting from a biophysical model informed from field data.…”

mentioning

confidence: 99%

Estimating the dispersal of Lepeophtheirus salmonis sea lice within and among Atlantic salmon sites of the Bay of Fundy, New Brunswick

Parent

Stryhn

Hammell

et al. 2021

Journal of Fish Diseases

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The objective of this study was to estimate the impact of infestation pressures on the abundance of the parasitic sea louse, Lepeophtheirus salmonis , in the Bay of Fundy, New Brunswick (NB), Canada, using the Fish‐iTrends database for the years 2009–2018. Infestation pressures were calculated as time‐lagged weighted averages of the abundance of adult female (AF) sea lice within a site (internal infestation pressure: IIP) and among sites (external infestation pressure: EIP). The EIP weights were calculated from seaway distances among sites and a Gaussian kernel density for bandwidths of 5 to 60 km. The EIP with a bandwidth of 10 km had the best fit, as determined with Akaike's information criterion, and historical AF sea lice abundance. This estimated dispersal distance of 10 km was similar to previous studies in Norway, Scotland and in New Brunswick. The infestation pressures estimated from empirical AF sea lice abundance within and among sites significantly increased the abundance of AF sea lice ( p < .001). This study concludes that sea lice burdens within Atlantic salmon farms in the Bay of Fundy, NB, are affected by within site management and could be improved by synchronizing treatments between sites.

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The relevance of larval biology on spatiotemporal patterns of pathogen connectivity among open-marine salmon farms

Cited by 14 publications

References 67 publications

Validating a biophysical parasite model with fish farm pen and plankton trawl data

Validating a biophysical parasite model with fish farm pen and plankton trawl data

Next-generation matrices for marine metapopulations: the case of sea lice on salmon farms^*

Estimating the dispersal of Lepeophtheirus salmonis sea lice within and among Atlantic salmon sites of the Bay of Fundy, New Brunswick

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The relevance of larval biology on spatiotemporal patterns of pathogen connectivity among open-marine salmon farms

Cited by 14 publications

References 67 publications

Validating a biophysical parasite model with fish farm pen and plankton trawl data

Validating a biophysical parasite model with fish farm pen and plankton trawl data

Next-generation matrices for marine metapopulations: the case of sea lice on salmon farms*

Estimating the dispersal of Lepeophtheirus salmonis sea lice within and among Atlantic salmon sites of the Bay of Fundy, New Brunswick

Contact Info

Product

Resources

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Next-generation matrices for marine metapopulations: the case of sea lice on salmon farms^*