Modelling the effects of past and future climate on the risk of bluetongue emergence in Europe

Guis, Hélène; Caminade, Cyril; Calvete, C.; Morse, Andrew P.; Tran, Annelise; Baylis, Matthew

doi:10.1098/rsif.2011.0255

Cited by 150 publications

(149 citation statements)

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Section: Mosquito Spatio-temporal Changes and Associated Health Issuesmentioning

confidence: 99%

“…Paull & Johnson (2013) summarize the complex physiological, range-shift, biotic-interaction and evolutionary challenges of predicting and attributing climate-driven changes to disease dynamics. However, a substantial body of publications and health-agency reports highlights the significance of climate change on vector-borne diseases (Kurane, 2010;Eastwood et al, 2011;Guis et al, 2012;Gallana et al, change. In the context of mosquito research, many zoos have the potential to provide valuable mosquito-monitoring and research opportunities This is largely due to the combination of novel species assemblages that zoos and similar facilities maintain, and the diverse range of microhabitats and shelters suitable for mosquito breeding and overwintering (Adler et al, 2011;Nelder, 2007;Tuten, 2011a;Tuten 2011b;Tuten et al, 2012).…”

Section: Mosquito Spatio-temporal Changes and Associated Health Issuesmentioning

confidence: 99%

“…The unintentional assistance provided by human activities combined with the great adaptability of many mosquito species has enabled extensive colonization outside of their natural range areas. A. albopictus exemplifies how extensive such range expansions can be (Benedict et al, 2007;Roiz et al, 2011;Caminade et al, 2012).Anthropogenic climate change (IPCC, 2013) presents a wide range of direct and indirect health impact issues (World Health Organization, 2003, 2009 Patz et al, 2005;Confalonieri et al, 2007; Costello et al, 2009 Costello et al, , 2011. The many indirect health issues include vector-borne disease impacts (Sutherst, 2004;Epstein & Mills, 2005;Kurane, 2010;Moore et al, 2012).…”

mentioning

confidence: 99%

“…Paull & Johnson (2013) summarize the complex physiological, range-shift, biotic-interaction and evolutionary challenges of predicting and attributing climate-driven changes to disease dynamics. However, a substantial body of publications and health-agency reports highlights the significance of climate change on vector-borne diseases (Kurane, 2010;Eastwood et al, 2011;Guis et al, 2012;Gallana et al, 2013; World Health Organization, 2013b), including actual and projected spatio-temporal changes to mosquito distribution and associated disease issues (Patz et al, 2005;Confalonieri et al, 2007;Paaijmans et al, 2010;Garamszegi, 2011;Roiz et al, 2011;Hongoh et al, 2012;Loiseau et al, 2012;Altizer et al, 2013;Fischer et al, 2013;Gallana et al, 2013;Hueffer et al, 2013; World Health Organization, 2013c). …”

mentioning

confidence: 99%

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Project MOSI: rationale and pilot‐study results of an initiative to help protect zoo animals from mosquito‐transmitted pathogens and contribute data on mosquito spatio–temporal distribution change

Pastorino

Albertini

Carlsen

et al. 2015

International Zoo Yearbook

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Mosquito-borne pathogens pose major threats to both wildlife and human health and, largely as a result of unintentional human-aided dispersal of their vector species, their cumulative threat is on the rise. Anthropogenic climate change is expected to be an increasingly significant driver of mosquito dispersal and associated disease spread. The potential health implications of changes in the spatio-temporal distribution of mosquitoes highlight the importance of ongoing surveillance and, where necessary, vector control and other health-management measures. The World Association of Zoos and Aquariums initiative, Project MOSI, was established to help protect vulnerable wildlife species in zoological facilities from mosquito-transmitted pathogens by establishing a zoo-based network of fixed mosquito monitoring sites to assist wildlife health management and contribute data on mosquito spatio-temporal distribution changes. A pilot study for Project MOSI is described here, including project rationale and results that confirm the feasibility of conducting basic standardized year-round mosquito trapping and monitoring in a zoo environment.Key-words: attractants; climate change; monitoring; mosquitoes; Project MOSI; surveillance; spatio-temporal distribution; wildlife health; zoological networks. MOSQUITO-RELATED HEALTH ISSUES FOR ZOOS AND SIMILAR FACILITIESMosquitoes are the principal vectors of a wide range of diseases, including human and avian malaria, dengue, West Nile encephalitis and filariasis (Becker et al., 2010; Kilpatrick & Randolph, 2012; World Health Organization, 2013a). A range of species has been recorded as succumbing to mosquito-transmitted pathogens in zoos and theme parks. Documented cases include African black-footed penguins Spheniscus demersus with avian malaria (Grim et al., 2004) and eastern equine encephalitis virus (Tuttle et al., 2005), Great gray owls Strix nebulosa with Usutu virus (Weissenböck et al., 2002), Humbolt penguins Spheiniscus humboldti with heartworms Dirofilaria immitis (Sano et al., 2005), and a Polar bear Ursus maritimus (Dutton et al., 2009) and two OrcasOrcinus orca with West Nile virus infection (Jett & Ventre, 2013).Blood-feeding mosquitoes have the ability to track airborne chemicals produced by the vertebrate host to locate them in order to have a blood meal, which is essential for viable egg production in most species (Dekker & Cardé, 2011). The combination of odours varies amongst species and mosquitoes can be more or less attracted to them depending on their feeding preference, even if, at close range, proximity to the host is likely to be more important than species identity (Takken & Verhulst, 2013). Several mosquito species are true 'generalists' as far as host species preference is concerned.Understanding distribution, population abundance, activity periods and other behaviours of mosquito species helps optimize protection efforts for human, domestic-animal and wildlife 3 populations (Becker et al., 2010; World Health Organization, 2013a). Monitoring an...

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Section: Mosquito Spatio-temporal Changes and Associated Health Issuesmentioning

confidence: 99%

Section: Mosquito Spatio-temporal Changes and Associated Health Issuesmentioning

confidence: 99%

mentioning

confidence: 99%

“…Paull & Johnson (2013) summarize the complex physiological, range-shift, biotic-interaction and evolutionary challenges of predicting and attributing climate-driven changes to disease dynamics. However, a substantial body of publications and health-agency reports highlights the significance of climate change on vector-borne diseases (Kurane, 2010;Eastwood et al, 2011;Guis et al, 2012;Gallana et al, 2013; World Health Organization, 2013b), including actual and projected spatio-temporal changes to mosquito distribution and associated disease issues (Patz et al, 2005;Confalonieri et al, 2007;Paaijmans et al, 2010;Garamszegi, 2011;Roiz et al, 2011;Hongoh et al, 2012;Loiseau et al, 2012;Altizer et al, 2013;Fischer et al, 2013;Gallana et al, 2013;Hueffer et al, 2013; World Health Organization, 2013c). …”

mentioning

confidence: 99%

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Project MOSI: rationale and pilot‐study results of an initiative to help protect zoo animals from mosquito‐transmitted pathogens and contribute data on mosquito spatio–temporal distribution change

Pastorino

Albertini

Carlsen

et al. 2015

International Zoo Yearbook

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“…At constant temperature, R 0 can be determined from the rates of midge life processes at that temperature. This approach has been used to define temperature-dependent R 0 values for BTV in the non-spatial context [34], the spatial context [42] and in order to assess the possible impact of climate change [43]. However, strong daily fluctuations in temperature, as are commonly observed in northern Europe, challenge the validity of this approach for BTV.…”

Section: Introductionmentioning

confidence: 99%

The impact of temperature changes on vector-borne disease transmission: Culicoides midges and bluetongue virus

Brand

Keeling

2017

J. R. Soc. Interface.

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It is a long recognized fact that climatic variations, especially temperature, affect the life history of biting insects. This is particularly important when considering vector-borne diseases, especially in temperate regions where climatic fluctuations are large. In general, it has been found that most biological processes occur at a faster rate at higher temperatures, although not all processes change in the same manner. This differential response to temperature, often considered as a trade-off between onward transmission and vector life expectancy, leads to the total transmission potential of an infected vector being maximized at intermediate temperatures. Here we go beyond the concept of a static optimal temperature, and mathematically model how realistic temperature variation impacts transmission dynamics. We use bluetongue virus (BTV), under UK temperatures and transmitted by Culicoides midges, as a well-studied example where temperature fluctuations play a major role. We first consider an optimal temperature profile that maximizes transmission, and show that this is characterized by a warm day to maximize biting followed by cooler weather to maximize vector life expectancy. This understanding can then be related to recorded representative temperature patterns for England, the UK region which has experienced BTV cases, allowing us to infer historical transmissibility of BTV, as well as using forecasts of climate change to predict future transmissibility. Our results show that when BTV first invaded northern Europe in 2006 the cumulative transmission intensity was higher than any point in the last 50 years, although with climate change such high risks are the expected norm by 2050. Such predictions would indicate that regular BTV epizootics should be expected in the UK in the future.

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2018

Veterinary Epidemiology

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Modelling the effects of past and future climate on the risk of bluetongue emergence in Europe

Cited by 150 publications

References 44 publications

Project MOSI: rationale and pilot‐study results of an initiative to help protect zoo animals from mosquito‐transmitted pathogens and contribute data on mosquito spatio–temporal distribution change

Project MOSI: rationale and pilot‐study results of an initiative to help protect zoo animals from mosquito‐transmitted pathogens and contribute data on mosquito spatio–temporal distribution change

The impact of temperature changes on vector-borne disease transmission: Culicoides midges and bluetongue virus

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