Modelling wildlife rabies: Transmission, economics, and conservation

Sterner, Ray T.; Smith, Graham C.

doi:10.1016/j.biocon.2006.05.004

Cited by 62 publications

(60 citation statements)

References 96 publications

(198 reference statements)

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“…The minimal effect of density on mange is supported by the observation that mange persists at low fox densities [20], because frequency-dependent diseases can be sustained at lower host densities than density-dependent diseases [26]. The contrast between our results and those of assessments of mange transmission in chamois, a species that does not show complex group structuring, and for which density-dependent transmission of mange was well supported [12], emphasizes the role of sociality in mediating disease dynamics within a population [1,2,5,19]. Further work is needed to examine how transmission mechanisms vary across different species affected by the same disease.…”

Section: Discussioncontrasting

confidence: 56%

“…Previous mange models have only considered direct, density-dependent transmission [12,17] but off-host mite survival [9] and low inter-group contact in foxes [18] suggest that indirect transmission is likely. Moreover, the social nature of foxes suggests that the traditional assumptions of density-and frequency-dependent disease transmission might be complicated [19]. We developed a model of mange spread and fitted it to a long-term dataset.…”

Section: Introductionmentioning

confidence: 99%

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Demonstrating frequency-dependent transmission of sarcoptic mange in red foxes

et al. 2014

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Understanding the relationship between disease transmission and host density is essential for predicting disease spread and control. Using long-term data on sarcoptic mange in a red fox Vulpes vulpes population, we tested long-held assumptions of density-and frequency-dependent direct disease transmission. We also assessed the role of indirect transmission. Contrary to assumptions typical of epidemiological models, mange dynamics are better explained by frequency-dependent disease transmission than by density-dependent transmission in this canid. We found no support for indirect transmission. We present the first estimates of R 0 and age-specific transmission coefficients for mange in foxes. These parameters are important for managing this poorly understood but highly contagious and economically damaging disease.

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Section: Discussioncontrasting

confidence: 56%

Section: Introductionmentioning

confidence: 99%

Demonstrating frequency-dependent transmission of sarcoptic mange in red foxes

et al. 2014

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“…Estimates of carnivore abundance are also important in assessing disease risks and the consequences of disease outbreaks (Sterner and Smith 2006). Diseases such as sarcoptic mange (Gortázar et al 1998) and rabies (Roboly 1985) can cause population declines which need to be quantified for management or for conservation purposes.…”

Section: Introductionmentioning

confidence: 99%

Carnivore population trends in Spanish agrosystems after the reduction in food availability due to rabbit decline by rabbit haemorrhagic disease and improved waste management

Sobrino

Acevedo

Escudero³

et al. 2008

Eur J Wildl Res

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We conducted spotlight counts from 1992 to 2006 in 59 localities to describe carnivore presence, distribution and relative abundance in open agriculture lands in Aragon, northeastern Spain. During the study period, urban waste and carcases of domestic livestock became less available to wild animals, and rabbit (Oryctolagus cuniculus) abundance was low after rabbit haemorragic disease. We calculated a kilometric abundance index (KAI, individuals seen per 100 km surveyed) and the ratio between the number of positive localities in which a species was detected and the total of localities surveyed in a year. Indices to abundance and presence included: red fox (Vulpes vulpes), KAI per 100 km 10.70 and 100.0% localities per year; stray dog (Canis familiaris), KAI 0.48 and 22.6% localities; wildcat (Felis silvestris), KAI 0.10 and 19.1% localities; domestic cat (Felis catus), KAI 0.21 and 20.6% localities; polecat (Mustela putorius), KAI 0.02 and 2.0% localities; badger (Meles meles), KAI 0.16 and 23.6% localities; stone marten (Martes foina), KAI 0.11 and 19.6% localities; weasel (Mustela nivalis), KAI 0.002 and 0.6% localities; and genet (Genetta genetta), KAI 0.06 and 10.0% localities. Indices of badger abundance increased significantly, whereas indices of stray dogs decreased significantly over the study period. Abundance indices of red fox, the most important predator of small game, were stable throughout the study period. No significant trend was observed to other studied species. This study concludes that Aragon region maintains a diverse and rather stable carnivore community and shows that large scale data may help to identify trends of the more abundant wild and feral carnivores.

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“…monitoring programs help to determine the distribution of non-native species, which is necessary in order to 55 assess the impact of non-native species in terms of disease risks, economic damage and negative effects on 56 native species and the environment, and plan management actions to reduce these impacts (Engeman et al 2006; 57 Sterner and Smith 2006; Yokomizo et al 2009). Monitoring programs for terrestrial mammals are usually based 58 on the collation of ad-hoc records (Roy et al 2014a), systematic surveys of abundance (such as road-kill surveys,…”

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confidence: 99%

Assessing and predicting the spread of non-native raccoons in Germany using hunting bag data and dispersal weighted models

et al. 2015

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34As the second largest cause of biodiversity loss worldwide, there is an urgent need to study the dynamics of 35 biological invasions and identify factors limiting the distribution of invasive alien species. In the present study 36 we analyze national-scale hunting bag data from Germany to predict the dispersal of raccoons in the largest non-37 native population of the species. Our focus is (1) to document changes in the distribution and abundance of 38 raccoons, (2) to identify the species-environment relationship and predict which areas will be suitable for future 39 colonization and (3) to apply a dispersal model to predict how fast the raccoon will spread to these areas. The 49 Introduction 50Worldwide, Invasive Alien Species (IAS) are associated with significant damage to the economy and public 51 health, and are considered to be one of the major threats to native biodiversity (Mack et al. 2000; Pimentel et al. 54monitoring programs help to determine the distribution of non-native species, which is necessary in order to 55 assess the impact of non-native species in terms of disease risks, economic damage and negative effects on 56 native species and the environment, and plan management actions to reduce these impacts (Engeman et al. 2006; 57 Sterner and Smith 2006; Yokomizo et al. 2009). Monitoring programs for terrestrial mammals are usually based 58 on the collation of ad-hoc records (Roy et al. 2014a), systematic surveys of abundance (such as road-kill surveys, 59tracking plots, spotlighting, pellet counts along fixed routes), or more cost intensive and logistically complicated 60 methods such as radio-tracking, mark-recapture, camera trapping, aerial surveys and DNA genotyping 61 (Woodroffe et al. 1990; Bartel et al. 2012; Engeman et al. 2013). Hunting bag data are routinely collected for 62 3 game species, and these offer an additional monitoring strategy as they can be used as a general index of long 63 term trends, population and distribution change and a proxy of abundance across time (Cattadori et al. 2003; 64 Kitson 2004; Carlsson et al. 2010). 65These abundance or presence/absence data are used in species distribution models (SDMs) to identify 66 suitable or unsuitable areas for a species based on a set of environmental covariates, and these SDMs can be used 67 to predict where a non-native species will spread to. Generally SDMs assume that the species being modelled is 68 at equilibrium with the environment (Guisan and Thuiller 2005), which means unoccupied areas are considered 69 as unsuitable for the species. However non-native species are often spreading from a few release sites and are 70therefore not at equilibrium with their environment, so absences may be due to dispersal limitation as well as 71 unsuitable environmental conditions (Václavík and Meentemeyer 2012). One approach to address this is to 72 model the dispersal process, and then weight the species distribution model by the predicted probability of 73 different areas being dispersed to (Sullivan et al. 2012 ...

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Modelling wildlife rabies: Transmission, economics, and conservation

Cited by 62 publications

References 96 publications

Demonstrating frequency-dependent transmission of sarcoptic mange in red foxes

Demonstrating frequency-dependent transmission of sarcoptic mange in red foxes

Carnivore population trends in Spanish agrosystems after the reduction in food availability due to rabbit decline by rabbit haemorrhagic disease and improved waste management

Assessing and predicting the spread of non-native raccoons in Germany using hunting bag data and dispersal weighted models

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