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Ecology, management and conservation in natural and modified habitats
RESEARCH ARTICLE

Effects of bait type and deployment strategy on uptake by free-living badgers

Francesca Cagnacci A B , Giovanna Massei A , David P. Cowan A , Neil Walker A and Richard J. Delahay A
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- Author Affiliations

A Central Science Laboratory, Sand Hutton, York Y041 1 LZ, United Kingdom.

B Corresponding author. Present address: Centre for Alpine Ecology, Viote del Monte Bondone, 38040 Trento, Italy. Email: cagnacci@cealp.it

Wildlife Research 34(6) 454-460 https://doi.org/10.1071/WR07026
Submitted: 27 February 2007  Accepted: 31 August 2007   Published: 2 November 2007

Abstract

Baits are increasingly used in wildlife management to deliver orally administered vaccines and contraceptives. The efficacy and cost-effectiveness of vaccination or fertility-control campaigns can be substantially affected by bait uptake rates. This study assessed whether bait type and deployment strategy affected bait uptake by free-living badgers (Meles meles L.). Six social groups of badgers were presented with three bait types (meat, fruit, cereals) and two deployment strategies (dispersed single baits versus aggregated multiple baits at fixed baiting stations) for six weeks. In each social group, the type of bait and deployment strategy were rotated every week so that by the end of the test every group had experienced all combinations. On three days, biomarkers (ethyl iophenoxic acid, propyl iophenoxic acid and rhodamine B) were added to the baits to determine the proportion of badgers ingesting these baits. The results indicated that both bait type and deployment strategy affected the proportion of baits eaten by badgers and the number of badgers gaining access to baits. Meat and fruit baits were taken significantly more frequently than cereals, and dispersed meat baits had the highest rates of disappearance. Biomarker levels suggested that the proportion of badgers that gained access to all baits was substantially lower when baits were aggregated, although small sample sizes prevented statistical assessment of this effect. The results suggest that dispersed single baits are likely to be consumed in greater proportions by a higher number of individual badgers than multiple baits at fixed stations.


Acknowledgements

This study was funded by the Department for Environment, Food & Rural Affairs (DEFRA), UK. Fieldwork in Woodchester Park was carried out with the kind permission of The National Trust. We thank the Woodchester Park field team and Gavin Western for helping with fieldwork. We are also grateful to Anton de Leeuw, John Woods, Allan Nadian and Roger Quy for useful discussion and advice. Bryony Tolhurst and two anonymous referees provided helpful comments on earlier drafts.


References

Artois, M. , Masson, E. , Barrat, J. , and Aubert, M. F. A. (1993). Efficacy of three oral rabies vaccine-baits in the red fox: a comparison. Veterinary Microbiology 38, 167–172.
Crossref | GoogleScholarGoogle Scholar | PubMed | de Leeuw A. N. S., Smith G. C., and Woods J. A. (2006). Use of iophenoxic acid to assess bait uptake by European badgers. In ‘Vertebrate Pest Management’. (Eds P. D. Cowan and C. J. Feare.) pp. 243–254. (Filander Verlag: Furth.)

Delahay, R. J. , Brown, J. A. , Mallison, P. J. , Spyvee, P. D. , Handoll, D. , Rogers, L. M. , and Cheeseman, C. L. (2000a). The use of marked bait in studies of the territorial organization of the European badger (Meles meles). Mammal Review 30, 73–87.
Crossref | GoogleScholarGoogle Scholar | Genstat (2003). ‘Genstat for Windows.’ 6th edn. (VSN International Ltd: Hemel Hempstead, UK.)

Gentle, M. , Massei, G. , and Saunders, G. (2004). Levamisole can reduce bait monopolisation in wild red foxes, Vulpes vulpes. Mammal Review 34, 325–330.
Crossref | GoogleScholarGoogle Scholar | ISG (2003). Development of vaccines for bovine tuberculosis. Report of the Independent Scientific Group Vaccine Scoping Sub-Committee. (DEFRA: London.)

Jones, A. (1994). High-performance liquid chromatographic determination of iophenoxic acid in serum. Journal of Chromatography. B, Analytical Technologies in the Biomedical and Life Sciences 654, 293–296.
Crossref | GoogleScholarGoogle Scholar | Judd I. (2003). Nailsworth Weather. www.nailsworthweather.co.uk.

Knobel, D. L. , Du Toit, J. T. , and Bingham, J. (2002). Development of a bait and baiting system for delivery of oral rabies vaccine to free-ranging african wild dogs (Lycaon pictus). Journal of Wildlife Diseases 38, 352–362.
PubMed | Krebs J. R. (1997). Bovine Tuberculosis in cattle and badgers. Report to the Rt Hon Dr Jack Cunningham MP. (MAFF: London.)

Kruuk, H. , and Parish, T. (1981). Feeding specialization of the European badger Meles meles in Scotland. Journal of Animal Ecology 50, 773–788.
Crossref | GoogleScholarGoogle Scholar | McCarthy J. (1993). The badger vaccination trial in West Cork: progress report. In ‘The badger’. (Ed. T. J. Hayden.) pp. 189–195. (Royal Irish Academy: Dublin.)

Melis, C. , Cagnacci, F. , and Bargagli, L. (2002). Food habits of the Eurasian badger in a rural Mediterranean area. Zeitschrift für Jagdwissenschaft 48, 236–246.Suppl.
Crossref | GoogleScholarGoogle Scholar | Neal E., and Cheeseman C. L. (1996). ‘Badgers.’ (T. & A.D. Poyser Ltd: London.)

Norbury, G. (2000). The potential for biological control of stoats (Mustela erminea). New Zealand Journal of Zoology 27, 145–163.
Quy R. J., Cowan D. P., and Lambert M. S. (2003). Adapting baiting tactics to match the foraging behaviour of Norway rats: a balance between efficacy and safety. In ‘Rats, Mice and People: Rodent Biology and Management’. (Eds G. R. Singleton, L. A. Hinds, C. J. Krebs and D. M. Spratt.) pp. 451–456. (Australian Center for International Agricultural Research: Canberra.)

The R Development Core Team. (2006). ‘R:© a Language and an Environment.’ Version 2.4.0. (R Foundation for Statistical Computing: Vienna.)’

Rogers, L. M. , Cheeseman, C. L. , and Mallison, P. J. (1997). The demography of a high-density badger (Meles meles) population in the west of England. Journal of Zoology 242, 705–728.
Wandeler A. I. (1991). Oral immunization of wildlife. In ‘The Natural History of Rabies’. (Ed. G. M. Baer.) pp. 485–503. (CRC Press: Boston.)

Wandeler, A. I. , Capt, S. , Kappeler, A. , and Hauser, R. (1988). Oral immunization of wildlife against rabies: concept and first field experiments. Reviews of Infectious Diseases 10, 649–653.Suppl. 4


Whishaw, I. Q. , and Whishaw, G. E. (1996). Conspecific aggression influences food carrying: studies on a wild population of Rattus norvegicus. Aggressive Behavior 22, 47–66.
Crossref | GoogleScholarGoogle Scholar |

Wilkinson, D. , Smith, G. C. , Delahay, R. J. , and Cheeseman, C. L. (2004). A model of bovine tuberculosis in the badger Meles meles: an evaluation of different vaccination strategies. Journal of Applied Ecology 41, 492–501.
Crossref | GoogleScholarGoogle Scholar |