Free Standard AU & NZ Shipping For All Book Orders Over $80!
Register      Login
Wildlife Research Wildlife Research Society
Ecology, management and conservation in natural and modified habitats
RESEARCH ARTICLE (Open Access)

Is the Felixer cat control device safe for marsupial carnivores?

Holly Rickards https://orcid.org/0000-0002-7545-1629 A B * , John L. Read C , Chris N. Johnson A , Menna E. Jones A , Matthew D. Pauza B , Joss Bentley D , Andry Sculthorpe E , Morgan Humphrey A and Rowena Hamer https://orcid.org/0000-0002-9063-5426 A F
+ Author Affiliations
- Author Affiliations

A University of Tasmania, Hobart, Tas., Australia.

B Department of Natural Resource and Environment Tasmania, Hobart, Tas., Australia.

C University of Adelaide, Adelaide, SA, Australia.

D NSW Office of Environment and Heritage, Ecosystems and Threatened Species Queanbeyan, Queanbeyan, NSW, Australia.

E Tasmanian Aboriginal Centre Inc, Hobart, Tas., Australia.

F Tasmanian Land Conservancy, Hobart, Tas., Australia.

* Correspondence to: holly.rickards@utas.edu.au

Handling Editor: Penny Fisher

Wildlife Research 50(5) 356-365 https://doi.org/10.1071/WR21175
Submitted: 9 December 2021  Accepted: 21 May 2022   Published: 10 August 2022

© 2023 The Author(s) (or their employer(s)). Published by CSIRO Publishing. This is an open access article distributed under the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License (CC BY-NC-ND)

Abstract

Context: The Felixer grooming device (‘Felixer’) is a lethal method of feral cat control designed to be cost-effective and target specific.

Aims: This study aims to test the target specificity of the Felixer in Tasmania, with a particular focus on Tasmanian devil and quoll species due to the overlap in size, habitats and behaviour between these native carnivores and feral cats.

Methods: Our study deployed Felixer devices set in a non-lethal mode in nine field sites in Tasmania, one field site in New South Wales and two Tasmanian wildlife sanctuaries.

Key results: Our study recorded 4376 passes by identifiable vertebrate species including 528 Tasmanian devil passes, 507 spotted-tailed quoll passes and 154 eastern quoll passes. Our data showed that the Felixer can successfully differentiate quoll species from feral cats with spotted-tailed quolls and eastern quolls targeted in 0.19% and 0% of passes, respectively. However, Tasmanian devils and common wombats were targeted in 23.10% and 12% of passes, respectively, although sample size was low for common wombats (n = 25).

Conclusions: The Felixer could not reliably identify Tasmanian devils and possibly common wombats as non-target species. Further data is needed to confirm the potential for impacts on the common wombat and other potential non-target species in Tasmania, and the likelihood of the toxin being ingested by falsely targeted individuals.

Implications: Our study suggest that the Felixer device is safe for use in the presence of two species of conservation concern, the eastern and spotted-tailed quoll. It also supports evidence from previous studies that the Felixer is unlikely to impact bettongs and potoroos. Use of Felixer devices across much of Tasmania would have to balance the conservation or economic benefits of cat control against potential impacts on Tasmanian devils. We suggest that active Felixer deployments be preceded by surveys to establish the range of species present at the control site, and the season of control considered carefully to minimise potential impacts on more susceptible juvenile animals. In addition, modifications to the Felixer device such as the proposed incorporation of AI technology should be tested against the Tasmanian devil and other non-target species.

Keywords: feline control, Felis catus, feral cats, grooming trap, lethal control, management, Sarcophilus harrishii, target specificity, Tasmanian carnivores.


References

Algar, D, Angus, GJ, Williams, MR, and Mellican, AE (2007a). Influence of bait type, weather and prey abundance on bait uptake by feral cats (Felis catus) on Peron Peninsula, Western Australia. Conservation Science Western Australia 6, 109–149.

Andersen, MC, Martin, BJ, and Roemer, GW (2004). Use of matrix population models to estimate the efficacy of euthanasia versus trap-neuter-return for management of free-roaming cats. Journal of the American Veterinary Medical Association 225, 1871–1876.
Use of matrix population models to estimate the efficacy of euthanasia versus trap-neuter-return for management of free-roaming cats.Crossref | GoogleScholarGoogle Scholar |

Andersen, GE, Johnson, CN, and Jones, ME (2016). Sympatric predator odour reveals a competitive relationship in size-structured mammalian carnivores. Behavioral Ecology and Sociobiology 70, 1831–1841.
Sympatric predator odour reveals a competitive relationship in size-structured mammalian carnivores.Crossref | GoogleScholarGoogle Scholar |

Andersen, GE, Johnson, CN, Barmuta, LA, and Jones, ME (2017). Use of anthropogenic linear features by two medium-sized carnivores in reserved and agricultural landscapes. Scientific Reports 7, 11624.
Use of anthropogenic linear features by two medium-sized carnivores in reserved and agricultural landscapes.Crossref | GoogleScholarGoogle Scholar |

Andersen, GE, Johnson, CN, and Jones, ME (2020). Space use and temporal partitioning of sympatric Tasmanian devils and spotted-tailed quolls. Austral Ecology 45, 355–365.
Space use and temporal partitioning of sympatric Tasmanian devils and spotted-tailed quolls.Crossref | GoogleScholarGoogle Scholar |

Australia Co (2015) ‘Threat abatement plan for predation by feral cats.’ (Department of Environment)

Comer, S, Speldewinde, P, Tiller, C, Clausen, L, Pinder, J, Cowen, S, and Algar, D (2018). Evaluating the efficacy of a landscape scale feral cat control program using camera traps and occupancy models. Scientific Reports 8, 5335.
Evaluating the efficacy of a landscape scale feral cat control program using camera traps and occupancy models.Crossref | GoogleScholarGoogle Scholar |

de Tores, PJ, Sutherland, DR, Clarke, JR, Hill, RF, Garretson, SW, Bloomfield, L, Strümpher, L, Glen, AS, and Cruz, J (2011). Assessment of risks to non-target species from an encapsulated toxin in a bait proposed for control of feral cats. Wildlife Research 38, 39–50.
Assessment of risks to non-target species from an encapsulated toxin in a bait proposed for control of feral cats.Crossref | GoogleScholarGoogle Scholar |

Department of Primary Industries, Parks, Water and Environment (2011) ‘1080 poison.’ (Department of Natural Resources and Environment Tasmania: Hobart, Tas., Australia)

Department of Primary Industries and Regional Development (2018) ‘1080 characteristics and use.’ (Department of Primary Industries and Regional Development: Perth, WA, Australia)

Doherty, TS, Bengsen, AJ, and Davis, RA (2014). A critical review of habitat use by feral cats and key directions for future research and management. Wildlife Research 41, 435–446.
A critical review of habitat use by feral cats and key directions for future research and management.Crossref | GoogleScholarGoogle Scholar |

Doherty, TS, Dickman, CR, Johnson, CN, Legge, SM, Ritchie, EG, and Woinarski, JCZ (2017). Impacts and management of feral cats Felis catus in Australia. Mammal Review 47, 83–97.
Impacts and management of feral cats Felis catus in Australia.Crossref | GoogleScholarGoogle Scholar |

Eason, C, Miller, A, Ogilvie, S, and Fairweather, A (2011). An updated review of the toxicology and ecotoxicology of sodium fluoroacetate (1080) in relation to its use as a pest control tool in New Zealand. New Zealand Journal of Ecology 35, 1–20.

Eason, CT, Ross, J, and Miller, A (2013). Secondary poisoning risks from 1080-poisoned carcasses and risk of trophic transfer—a review. New Zealand Journal of Zoology 40, 217–225.
Secondary poisoning risks from 1080-poisoned carcasses and risk of trophic transfer—a review.Crossref | GoogleScholarGoogle Scholar |

Fancourt, BA (2016). Diagnosing species decline: a contextual review of threats, causes and future directions for management and conservation of the eastern quoll. Wildlife Research 43, 197–211.
Diagnosing species decline: a contextual review of threats, causes and future directions for management and conservation of the eastern quoll.Crossref | GoogleScholarGoogle Scholar |

Fancourt, BA, Augusteyn, J, Cremasco, P, Nolan, B, Richards, S, Speed, J, Wilson, C, and Gentle, MN (2021). Measuring, evaluating and improving the effectiveness of invasive predator control programs: feral cat baiting as a case study. Journal of Environmental Management 280, 111691.
Measuring, evaluating and improving the effectiveness of invasive predator control programs: feral cat baiting as a case study.Crossref | GoogleScholarGoogle Scholar |

Foley, P, Foley, JE, Levy, JK, and Paik, T (2005). Analysis of the impact of trap-neuter-return programs on populations of feral cats. Journal of the American Veterinary Medical Association 227, 1775–1781.
Analysis of the impact of trap-neuter-return programs on populations of feral cats.Crossref | GoogleScholarGoogle Scholar |

Hawkins, CE, Baars, C, Hesterman, H, Hocking, GJ, Jones, ME, Lazenby, B, Mann, D, Mooney, N, Pemberton, D, Pyecroft, S, Restani, M, and Wiersma, J (2006). Emerging disease and population decline of an island endemic, the Tasmanian devil Sarcophilus harrisii. Biological Conservation 131, 307–324.
Emerging disease and population decline of an island endemic, the Tasmanian devil Sarcophilus harrisii.Crossref | GoogleScholarGoogle Scholar |

Jones ME (2003) Convergence in ecomorphology and guild structure among marsupial and placental carnivores. In ‘Predators with pouches: the biology of carnivorous marsupials’. (Eds M Jones, C Dickman, M Archer) pp. 285–296. (CSIRO Publishing: Melbourne)

Jones, ME, and Stoddart, DM (1998). Reconstruction of the predatory behaviour of the extinct marsupial thylacine (Thylacinus cynocephalus). Journal of Zoology 246, 239–246.
Reconstruction of the predatory behaviour of the extinct marsupial thylacine (Thylacinus cynocephalus).Crossref | GoogleScholarGoogle Scholar |

Jones, ME, Cockburn, A, Hamede, R, Hawkins, C, Hesterman, H, Lachish, S, Mann, D, McCallum, H, and Pemberton, D (2008). Life-history change in disease-ravaged Tasmanian devil populations. Proceedings of the National Academy of Sciences of the United States of America 105, 10023–10027.
Life-history change in disease-ravaged Tasmanian devil populations.Crossref | GoogleScholarGoogle Scholar |

Kinnear, JE, Krebs, CJ, Pentland, C, Orell, P, Holme, C, and Karvinen, R (2010). Predator-baiting experiments for the conservation of rock-wallabies in Western Australia: a 25-year review with recent advances. Wildlife Research 37, 57–67.
Predator-baiting experiments for the conservation of rock-wallabies in Western Australia: a 25-year review with recent advances.Crossref | GoogleScholarGoogle Scholar |

Lachish, S, McCallum, H, and Jones, M (2009). Demography, disease and the devil: life-history changes in a disease-affected population of Tasmanian devils (Sarcophilus harrisii). Journal of Animal Ecology 78, 427–436.
Demography, disease and the devil: life-history changes in a disease-affected population of Tasmanian devils (Sarcophilus harrisii).Crossref | GoogleScholarGoogle Scholar |

Legge, S, Murphy, BP, McGregor, H, Woinarski, JCZ, Augusteyn, J, Ballard, G, Baseler, M, Buckmaster, T, Dickman, CR, Doherty, T, Edwards, G, Eyre, T, Fancourt, BA, Ferguson, D, Forsyth, DM, Geary, WL, Gentle, M, Gillespie, G, Greenwood, L, Hohnen, R, Hume, S, Johnson, CN, Maxwell, M, McDonald, PJ, Morris, K, Moseby, K, Newsome, T, Nimmo, D, Paltridge, R, Ramsey, D, Read, J, Rendall, A, Rich, M, Ritchie, E, Rowland, J, Short, J, Stokeld, D, Sutherland, DR, Wayne, AF, Woodford, L, and Zewe, F (2017). Enumerating a continental-scale threat: how many feral cats are in Australia? Biological Conservation 206, 293–303.
Enumerating a continental-scale threat: how many feral cats are in Australia?Crossref | GoogleScholarGoogle Scholar |

Legge, S, Taggart, PL, Dickman, CR, Read, JL, and Woinarski, JCZ (2020a). Cat-dependent diseases cost Australia AU$6 billion per year through impacts on human health and livestock production. Wildlife Research 47, 731–746.
Cat-dependent diseases cost Australia AU$6 billion per year through impacts on human health and livestock production.Crossref | GoogleScholarGoogle Scholar |

Legge, S, Woinarski, JCZ, Dickman, CR, Doherty, TS, McGregor, H, and Murphy, BP (2020b). Cat ecology, impacts and management in Australia. Wildlife Research 47, i–vi.
Cat ecology, impacts and management in Australia.Crossref | GoogleScholarGoogle Scholar |

Leo, BT, Anderson, JJ, Ha, J, Phillips, RB, and Ha, RR (2018). Modeling impacts of hunting on control of an insular feral cat population. Pacific Science 72, 57–67.
Modeling impacts of hunting on control of an insular feral cat population.Crossref | GoogleScholarGoogle Scholar |

Littin, KE, Gregory, NG, Airey, AT, Eason, CT, and Mellor, DJ (2009). Behaviour and time to unconsciousness of brushtail possums (Trichosurus vulpecula) after a lethal or sublethal dose of 1080. Wildlife Research 36, 709–720.
Behaviour and time to unconsciousness of brushtail possums (Trichosurus vulpecula) after a lethal or sublethal dose of 1080.Crossref | GoogleScholarGoogle Scholar |

Lohr, CA, Cox, LJ, and Lepczyk, CA (2013). Costs and benefits of trap-neuter-release and euthanasia for removal of urban cats in Oahu, Hawaii. Conservation Biology 27, 64–73.
Costs and benefits of trap-neuter-release and euthanasia for removal of urban cats in Oahu, Hawaii.Crossref | GoogleScholarGoogle Scholar |

Mcilroy, JC (1984). The sensitivity of Australian animals to 1080 poison Vii. Native and introduced birds. Wildlife Research 11, 373–385.
The sensitivity of Australian animals to 1080 poison Vii. Native and introduced birds.Crossref | GoogleScholarGoogle Scholar |

Mead, RJ, Oliver, AJ, and King, DR (1979). Metabolism and defluorination of fluoroacetate in the brush-tailed possum (Trichosurus vulpecula). Australian Journal of Biological Sciences 32, 15–26.
Metabolism and defluorination of fluoroacetate in the brush-tailed possum (Trichosurus vulpecula).Crossref | GoogleScholarGoogle Scholar |

Moseby, KE, and Hill, BM (2011). The use of poison baits to control feral cats and red foxes in arid South Australia I. Aerial baiting trials. Wildlife Research 38, 338–349.
The use of poison baits to control feral cats and red foxes in arid South Australia I. Aerial baiting trials.Crossref | GoogleScholarGoogle Scholar |

Moseby, KE, and Read, JL (2006). The efficacy of feral cat, fox and rabbit exclusion fence designs for threatened species protection. Biological Conservation 127, 429–437.
The efficacy of feral cat, fox and rabbit exclusion fence designs for threatened species protection.Crossref | GoogleScholarGoogle Scholar |

Moseby, KE, Letnic, M, Blumstein, DT, and West, R (2019). Understanding predator densities for successful co-existence of alien predators and threatened prey. Austral Ecology 44, 409–419.
Understanding predator densities for successful co-existence of alien predators and threatened prey.Crossref | GoogleScholarGoogle Scholar |

Moseby, KE, McGregor, H, and Read, JL (2020). Effectiveness of the Felixer grooming trap for the control of feral cats: a field trial in arid South Australia. Wildlife Research 47, 599–609.
Effectiveness of the Felixer grooming trap for the control of feral cats: a field trial in arid South Australia.Crossref | GoogleScholarGoogle Scholar |

Parkes, J, Fisher, P, Robinson, S, and Aguirre-Muñoz, A (2014). Eradication of feral cats from large islands: an assessment of the effort required for success. New Zealand Journal of Ecology 38, 307–314.

Read, J, Gigliotti, F, Darby, S, and Lapidge, S (2014). Dying to be clean: pen trials of novel cat and fox control devices. International Journal of Pest Management 60, 166–172.
Dying to be clean: pen trials of novel cat and fox control devices.Crossref | GoogleScholarGoogle Scholar |

Read, JL, Bowden, T, Hodgens, P, Hess, M, McGregor, H, and Moseby, K (2019). Target specificity of the felixer grooming “trap”. Wildlife Society Bulletin 43, 112–120.
Target specificity of the felixer grooming “trap”.Crossref | GoogleScholarGoogle Scholar |

Read, JL, Dickman, CR, Boardman, WSJ, and Lepczyk, CA (2020). Reply to Wolf et al.: why trap-neuter-return (TNR) is not an ethical solution for stray cat management. Animals 10, 1525.
Reply to Wolf et al.: why trap-neuter-return (TNR) is not an ethical solution for stray cat management.Crossref | GoogleScholarGoogle Scholar |

Robertson, SA (2008). A review of feral cat control. Journal of Feline Medicine and Surgery 10, 366–375.
A review of feral cat control.Crossref | GoogleScholarGoogle Scholar |

Schmidt, PM, Swannack, TM, Lopez, RR, and Slater, MR (2009). Evaluation of euthanasia and trap-neuter-return (TNR) programs in managing free-roaming cat populations. Wildlife Research 36, 117–125.
Evaluation of euthanasia and trap-neuter-return (TNR) programs in managing free-roaming cat populations.Crossref | GoogleScholarGoogle Scholar |

Short, J, Turner, B, Risbey, DA, and Carnamah, R (1997). Control of feral cats for nature conservation. II. Population reduction by poisoning. Wildlife Research 24, 703–714.
Control of feral cats for nature conservation. II. Population reduction by poisoning.Crossref | GoogleScholarGoogle Scholar |

Short, J, Turner, B, and Risbey, D (2002). Control of feral cats for nature conservation. III. Trapping. Wildlife Research 29, 475–487.
Control of feral cats for nature conservation. III. Trapping.Crossref | GoogleScholarGoogle Scholar |

Twigg, LE, Martin, GR, Eastman, AF, King, the late DR, and Kirkpatrick, WE (2003). Sensitivity of some Australian animals to sodium fluoroacetate (1080): additional species and populations, and some ecological considerations. Australian Journal of Zoology 51, 515–531.
Sensitivity of some Australian animals to sodium fluoroacetate (1080): additional species and populations, and some ecological considerations.Crossref | GoogleScholarGoogle Scholar |

Wallach, AD, Bekoff, M, Batavia, C, Nelson, MP, and Ramp, D (2018). Summoning compassion to address the challenges of conservation. Conservation Biology 32, 1255–1265.
Summoning compassion to address the challenges of conservation.Crossref | GoogleScholarGoogle Scholar |

Woinarski, JCZ (2016). National context for the conservation fate of Victoria’s mammal fauna. The Victorian Naturalist 133, 74–78.

Woinarski, JCZ, Burbidge, AA, and Harrison, PL (2015). Ongoing unraveling of a continental fauna: decline and extinction of Australian mammals since European settlement. Proceedings of the National Academy of Sciences of the United States of America 112, 4531–4540.
Ongoing unraveling of a continental fauna: decline and extinction of Australian mammals since European settlement.Crossref | GoogleScholarGoogle Scholar |

Woinarski JCZ, Legge SM, Dickman CR (2019) ‘Cats in Australia: companion and killer.’ (CSIRO Publishing: Melbourne, Vic., Australia)

Wolf, PJ, and Schaffner, JE (2019). The road to TNR: examining trap-neuter-return through the lens of our evolving ethics. Frontiers in Veterinary Science 5, 341.
The road to TNR: examining trap-neuter-return through the lens of our evolving ethics.Crossref | GoogleScholarGoogle Scholar |