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Wildlife Research Wildlife Research Society
Ecology, management and conservation in natural and modified habitats
RESEARCH ARTICLE

Minimising mortalities in capturing wildlife: refinement of helicopter darting of chital deer (Axis axis) in Australia

Jordan O. Hampton https://orcid.org/0000-0003-0472-3241 A E , Matthew Amos B , Anthony Pople B , Michael Brennan B and David M. Forsyth C D
+ Author Affiliations
- Author Affiliations

A Faculty of Veterinary and Agricultural Sciences, University of Melbourne, Parkville, Vic. 3010, Australia.

B Queensland Department of Agriculture and Fisheries, 41 Boggo Road, Dutton Park, Qld 4102, Australia.

C Vertebrate Pest Research Unit, NSW Department of Primary Industries, 1447 Forest Road, Orange, NSW 2800, Australia.

D School of Biological, Earth and Environmental Sciences, University of New South Wales, Sydney, NSW 2052, Australia.

E Corresponding author. Email: jordan.hampton@unimelb.edu.au

Wildlife Research 48(4) 304-313 https://doi.org/10.1071/WR20106
Submitted: 23 June 2020  Accepted: 1 October 2020   Published: 23 December 2020

Abstract

Context: Helicopter darting has been used to capture wild deer, but this method has never been used for chital deer (Axis axis).

Aim: The aims of this study were to develop, assess and refine a helicopter darting technique for wild chital deer in northern Australia by quantifying: (1) reliable pharmacological doses for immobilisation; (2) the efficacy of the technique (including the duration of procedures); and (3) the frequency of adverse animal welfare events.

Methods: The study was conducted in three stages: an initial protocol (n = 25 deer captured) in July−August 2018; a refined second protocol implemented in June 2019 (n = 12 deer captured); and a further refined third protocol implemented in June 2019 (n = 12 deer captured). Parameters to estimate the duration of procedures were measured and the frequency of several adverse animal welfare events during capture were quantified: mortality (at the time of capture and within 14 days of capture), hyperthermia, hypoxaemia, dart inaccuracy and manual restraint. Finally, GPS location collars with a mortality-sensing function were used to monitor post-release mortality.

Results: Mortality within 14 days of capture was 40% for the first stage, 25% for the second stage and 17% for the third stage. Considerable refinement of procedures occurred between stages in consultation with an Animal Ethics Committee. One-third of all 15 mortalities occurred at the time of capture and were attributed to ballistic trauma from dart impact and acute capture myopathy. The majority (n = 10) of mortalities, however, occurred post-release and were only detected by mortality-sensing GPS location collars. These post-release mortalities were attributed to capture myopathy.

Conclusions: Helicopter darting of wild chital deer poses animal welfare risks, but these can be minimised through the selection of the most appropriate pharmacological agents and attempts at preventing factors such as hyperthermia and hypoxaemia that contribute to the development of capture myopathy. Further research into capture protocols is needed for helicopter-based immobilisation of chital deer. Fitting animals with GPS location collars enabled post-release mortality, which was significant, to be evaluated.

Keywords: invasive species, mortality, stress, radio telemetry, wildlife management.


References

Amos, M., and Pople, A. (2016). Preliminary investigation into chital deer (Axis axis) home range and habitat preferences near Charters Towers, Queensland. In ‘Proceedings of the 5th Queensland Pest Animal Symposium, 7–10 November 2016, Townsville’. pp. 20–23. (Weed Society of Queensland: Townsville, Australia.)

Andryk, T. A., Irby, L. R., Hook, D. L., McCarthy, J. J., and Olson, G. (1983). Comparison of mountain sheep capture techniques: helicopter darting versus net-gunning. Wildlife Society Bulletin 11, 184–187.

Arnemo, J., Moe, S., and Søli, N. (1993). Xylazine-induced sedation in axis deer (Axis axis) and its reversal by atipamezole. Veterinary Research Communications 17, 123–128.
Xylazine-induced sedation in axis deer (Axis axis) and its reversal by atipamezole.Crossref | GoogleScholarGoogle Scholar | 8105603PubMed |

Arnemo, J., Negard, T., and Søli, N. (1994). Chemical capture of free-ranging red deer (Cervus elaphus) with medetomidine–ketamine. Rangifer 14, 123–127.
Chemical capture of free-ranging red deer (Cervus elaphus) with medetomidine–ketamine.Crossref | GoogleScholarGoogle Scholar |

Arnemo, J. M., Storaas, T., Khadka, C. B., and Wegge, P. (2005). Use of medetomidine–ketamine and atipamezole for reversible immobilization of free-ranging hog deer (Axis porcinus) captured in drive nets. Journal of Wildlife Diseases 41, 467–470.
Use of medetomidine–ketamine and atipamezole for reversible immobilization of free-ranging hog deer (Axis porcinus) captured in drive nets.Crossref | GoogleScholarGoogle Scholar | 16107687PubMed |

Arnemo, J. M., Ahlqvist, P., Andersen, R., Berntsen, F., Ericsson, G., Odden, J., Brunberg, S., Segerström, P., and Swenson, J. E. (2006). Risk of capture-related mortality in large free-ranging mammals: experiences from Scandinavia. Wildlife Biology 12, 109–113.
Risk of capture-related mortality in large free-ranging mammals: experiences from Scandinavia.Crossref | GoogleScholarGoogle Scholar |

Arnemo, J. M., Evans, A. L., Miller, A. L., and Os, Ø. (2011). Effective immobilizing doses of medetomidine–ketamine in free-ranging, wild Norwegian reindeer (Rangifer tarandus tarandus). Journal of Wildlife Diseases 47, 755–758.
Effective immobilizing doses of medetomidine–ketamine in free-ranging, wild Norwegian reindeer (Rangifer tarandus tarandus).Crossref | GoogleScholarGoogle Scholar | 21719847PubMed |

Arnemo, J. M., Evans, A. L., Fahlman, A., and Caulkett, N. (2014). Field emergencies and complications. In ‘Zoo Animal and Wildlife Immobilization and Anesthesia’. (Eds G. West, D. Heard and N. Caulkett.) pp. 139–147. (Wiley and Sons: Hoboken, NJ, USA.)

Becciolini, V., Lanini, F., and Ponzetta, M. P. (2019). Impact of capture and chemical immobilization on the spatial behaviour of red deer Cervus elaphus hinds. Wildlife Biology 2019, 1–8.

Bishop, C. J., Freddy, D. J., White, G. C., Stephenson, T. R., Wolfe, L. L., and Watkins, B. E. (2007). Using vaginal implant transmitters to aid in capture of mule deer neonates. The Journal of Wildlife Management 71, 945–954.
Using vaginal implant transmitters to aid in capture of mule deer neonates.Crossref | GoogleScholarGoogle Scholar |

Boardman, W. S., Lethbridge, M. R., Hampton, J. O., Smith, I., Woolnough, A. P., McEwen, M.-M., Miller, G. W., and Caraguel, C. G. (2014). Evaluation of medetomidine–ketamine and medetomidine–ketamine–butorphanol for the field anesthesia of free-ranging dromedary camels (Camelus dromedarius) in Australia. Journal of Wildlife Diseases 50, 873–882.
Evaluation of medetomidine–ketamine and medetomidine–ketamine–butorphanol for the field anesthesia of free-ranging dromedary camels (Camelus dromedarius) in Australia.Crossref | GoogleScholarGoogle Scholar | 25105812PubMed |

Bowman, J. L., and Jacobson, H. A. (1998). An improved vaginal-implant transmitter for locating white-tailed deer birth sites and fawns. Wildlife Society Bulletin 26, 295–298.

Breed, D., Meyer, L. C., Steyl, J. C., Goddard, A., Burroughs, R., and Kohn, T. A. (2019). Conserving wildlife in a changing world: understanding capture myopathy – a malignant outcome of stress during capture and translocation. Conservation Physiology 7, coz027.
Conserving wildlife in a changing world: understanding capture myopathy – a malignant outcome of stress during capture and translocation.Crossref | GoogleScholarGoogle Scholar | 31304016PubMed |

Brogi, R., Brivio, F., Bertolucci, C., Benazzi, M., Luccarini, S., Cappai, N., Bottero, E., Pedrazzoli, C., Columbano, N., Apollonio, M., and Grignolio, S. (2019). Capture effects in wild boar: a multifaceted behavioural investigation. Wildlife Biology 2019, 1–10.
Capture effects in wild boar: a multifaceted behavioural investigation.Crossref | GoogleScholarGoogle Scholar |

Bryant, B., Pittard, S., Jordan, N. R., and McMahon, C. R. (2019). Chemical capture of wild swamp buffalo (Bubalus bubalis) in tropical northern Australia using thiafentanil, etorphine and azaperone combinations. Australian Veterinary Journal 97, 33–38.
Chemical capture of wild swamp buffalo (Bubalus bubalis) in tropical northern Australia using thiafentanil, etorphine and azaperone combinations.Crossref | GoogleScholarGoogle Scholar | 30693492PubMed |

Chapple, R. S. (1989). The biology and behaviour of chital deer (Axis axis) in captivity. Ph.D. Thesis. University of Sydney, Sydney, Australia.

Davis, N., Bennett, A., Forsyth, D., Bowman, D., Lefroy, E., Wood, S., Woolnough, A., West, P., Hampton, J., and Johnson, C. (2016). A systematic review of the impacts and management of introduced deer (family: Cervidae) in Australia. Wildlife Research 43, 515–532.
A systematic review of the impacts and management of introduced deer (family: Cervidae) in Australia.Crossref | GoogleScholarGoogle Scholar |

Dechen Quinn, A. C., Williams, D. M., Porter, W. F., Fitzgerald, S. D., and Hynes, K. (2014). Effects of capture-related injury on postcapture movement of white-tailed deer. Journal of Wildlife Diseases 50, 250–258.
Effects of capture-related injury on postcapture movement of white-tailed deer.Crossref | GoogleScholarGoogle Scholar | 24484502PubMed |

DelGiudice, G. D., Sampson, B. A., Kuehn, D. W., Powell, M. C., and Fieberg, J. (2005). Understanding margins of safe capture, chemical immobilization, and handling of free-ranging white-tailed deer. Wildlife Society Bulletin 33, 677–687.
Understanding margins of safe capture, chemical immobilization, and handling of free-ranging white-tailed deer.Crossref | GoogleScholarGoogle Scholar |

English, A. (1980). Mortality in chital deer (Axis axis). Australian Veterinary Journal 56, 398–399.
Mortality in chital deer (Axis axis).Crossref | GoogleScholarGoogle Scholar | 7436953PubMed |

English, A. W. (1992). Management strategies for farmed chital deer. In ‘The Biology of Deer’. (Ed. R. D. Brown.) pp. 189–196. (Springer-Verlag: New York City, NY, USA.)

Fahlman, Å., Caulkett, N., Arnemo, J. M., Neuhaus, P., and Ruckstuhl, K. E. (2012). Efficacy of a portable oxygen concentrator with pulsed delivery for treatment of hypoxemia during anesthesia of wildlife. Journal of Zoo and Wildlife Medicine 43, 67–76.
Efficacy of a portable oxygen concentrator with pulsed delivery for treatment of hypoxemia during anesthesia of wildlife.Crossref | GoogleScholarGoogle Scholar | 22448511PubMed |

Fahlman, Å., Arnemo, J. M., Pringle, J., and Nyman, G. (2014). Oxygen supplementation in anesthetized brown bears (Ursus arctos) – how low can you go? Journal of Wildlife Diseases 50, 574–581.
Oxygen supplementation in anesthetized brown bears (Ursus arctos) – how low can you go?Crossref | GoogleScholarGoogle Scholar | 24807187PubMed |

Fernández-Morán, J., Palomeque, J., and Peinado, V. (2000). Medetomidine/tiletamine/zolazepam and xylazine/tiletamine/zolazepam combinations for immobilization of fallow deer (Cervus dama). Journal of Zoo and Wildlife Medicine 31, 62–64.
Medetomidine/tiletamine/zolazepam and xylazine/tiletamine/zolazepam combinations for immobilization of fallow deer (Cervus dama).Crossref | GoogleScholarGoogle Scholar | 10884126PubMed |

Forsyth, D. M., Pople, T., Page, B., Moriarty, A., Ramsey, D., Parkes, J., Wiebkin, A., and Lane, C. (Eds.) (2017). 2016 National Wild Deer Management Workshop Proceedings, Adelaide, 17−18 November 2016. (Invasive Animals Cooperative Research Centre: Canberra, Australia.)

Forsyth, D. M., Pople, A., Woodford, L., Brennan, M., Amos, M., Moloney, P. D., Fanson, B., and Story, G. (2019). Landscape-scale effects of homesteads, water, and dingoes on invading chital deer in Australia’s dry tropics. Journal of Mammalogy 100, 1954–1965.
Landscape-scale effects of homesteads, water, and dingoes on invading chital deer in Australia’s dry tropics.Crossref | GoogleScholarGoogle Scholar |

Hampton, J., Robertson, H., Adams, P., Hyndman, T., and Collins, T. (2016a). An animal welfare assessment framework for helicopter darting: a case study with a newly developed method for feral horses. Wildlife Research 43, 429–437.
An animal welfare assessment framework for helicopter darting: a case study with a newly developed method for feral horses.Crossref | GoogleScholarGoogle Scholar |

Hampton, J., Skroblin, A., De Ridder, T. R., and Perry, A. L. (2016b). Chemical immobilisation and rangeland species: assessment of a helicopter darting method for Australian cattle. The Rangeland Journal 38, 533–540.
Chemical immobilisation and rangeland species: assessment of a helicopter darting method for Australian cattle.Crossref | GoogleScholarGoogle Scholar |

Hampton, J. O., Hyndman, T. H., Laurence, M., Perry, A. L., Adams, P., and Collins, T. (2016c). Animal welfare and the use of procedural documents: limitations and refinement. Wildlife Research 43, 599–603.
Animal welfare and the use of procedural documents: limitations and refinement.Crossref | GoogleScholarGoogle Scholar |

Hampton, J. O., Skroblin, A., Perry, A. L., and De Ridder, T. R. (2016d). Remote chemical immobilisation method for capturing free-ranging Australian cattle. Australian Veterinary Journal 94, 438–444.
Remote chemical immobilisation method for capturing free-ranging Australian cattle.Crossref | GoogleScholarGoogle Scholar | 27891593PubMed |

Hampton, J. O., Finch, N. A., Watter, K., Amos, M., Pople, T., Moriarty, A., Jacotine, A., Panther, D., McGhie, C., Davies, C., Mitchell, J., and Forsyth, D. M. (2019a). A review of methods used to capture and restrain introduced wild deer in Australia. Australian Mammalogy 41, 1–11.
A review of methods used to capture and restrain introduced wild deer in Australia.Crossref | GoogleScholarGoogle Scholar |

Hampton, J. O., MacKenzie, D. I., and Forsyth, D. M. (2019b). How many to sample? Statistical guidelines for monitoring animal welfare outcomes. PLoS One 14, e0211417.
How many to sample? Statistical guidelines for monitoring animal welfare outcomes.Crossref | GoogleScholarGoogle Scholar | 30699193PubMed |

Harms, N. J., Jung, T. S., Hallock, M., and Egli, K. (2018). Efficacy of a butorphanol, azaperone, and medetomidine combination for helicopter-based immobilization of bison (Bison bison). Journal of Wildlife Diseases 54, 819–824.
Efficacy of a butorphanol, azaperone, and medetomidine combination for helicopter-based immobilization of bison (Bison bison).Crossref | GoogleScholarGoogle Scholar | 29863971PubMed |

Hennig, J. D., Scasta, J. D., Beck, J. L., Schoenecker, K. A., and King, S. R. B. (2020). Systematic review of equids and telemetry collars: implications for deployment and reporting. Wildlife Research 47, 361–371.
Systematic review of equids and telemetry collars: implications for deployment and reporting.Crossref | GoogleScholarGoogle Scholar |

Johns, J., Caulkett, N., Chandy, G., Alexander, J., Venugopal, S. K., Surendran, S., and Sreedharannair, A. (2020). Oral haloperidol premedication to reduce capture stress prior to xylazine–ketamine anesthesia in captive spotted deer (Axis axis). Journal of Zoo and Wildlife Medicine 51, 88–95.
Oral haloperidol premedication to reduce capture stress prior to xylazine–ketamine anesthesia in captive spotted deer (Axis axis).Crossref | GoogleScholarGoogle Scholar | 32212550PubMed |

Johnson, B. K., McCoy, T., Kochanny, C. O., and Cook, R. C. (2006). Evaluation of vaginal implant transmitters in elk (Cervus elaphus nelsoni). Journal of Zoo and Wildlife Medicine 37, 301–305.
Evaluation of vaginal implant transmitters in elk (Cervus elaphus nelsoni).Crossref | GoogleScholarGoogle Scholar | 17319128PubMed |

Jung, T. S., Konkolics, S. M., Kukka, P. M., Majchrzak, Y. N., Menzies, A. K., Oakley, M. P., Peers, M. J. L., and Studd, E. K. (2019). Short‐term effect of helicopter‐based capture on movements of a social ungulate. The Journal of Wildlife Management 83, 830–837.
Short‐term effect of helicopter‐based capture on movements of a social ungulate.Crossref | GoogleScholarGoogle Scholar |

Krausman, P. R., Rautenstrauch, K. R., Hervert, J. J., Remington, R., and Ordway, L. L. (1986). Immobilization of desert mule deer with etorphine plus azaperone. The Southwestern Naturalist 31, 411–414.
Immobilization of desert mule deer with etorphine plus azaperone.Crossref | GoogleScholarGoogle Scholar |

Kreeger, T. J., and Arnemo, J. M. (2018). ‘Handbook of Wildlife Chemical Immobilization.’ 5th edn. (Published by authors.)

Latham, A. D. M., Davidson, B., Warburton, B., Yockney, I., and Hampton, J. O. (2020). Efficacy and animal welfare impacts of novel capture methods for two species of invasive wild mammals in New Zealand. Animals (Basel) 10, 44.
Efficacy and animal welfare impacts of novel capture methods for two species of invasive wild mammals in New Zealand.Crossref | GoogleScholarGoogle Scholar |

Lian, M., Evans, A., Beckmen, K., Caulkett, N., and Arnemo, J. (2017). Restraint and immobilization. In ‘Reindeer and Caribou. Health and Disease’. (Eds M. Tryland and S. Kutz.) pp. 466–491. (Taylor and Francis: Boca Raton, FL, USA.)

Linklater, W. L., and Cameron, E. Z. (2002). Escape behaviour of feral horses during a helicopter count. Wildlife Research 29, 221–224.
Escape behaviour of feral horses during a helicopter count.Crossref | GoogleScholarGoogle Scholar |

Long, J. L. (2003). ‘Introduced Mammals of the World.’ (CSIRO Publishing: Melbourne, Vic., Australia.)

Mattioli, S. (2011). Family Cervidae (deer). In ‘Handbook of the Mammals of the World’. (Eds D. Wilson and R. Mittermeier.) pp. 350–443. (Lynx Edicions: Barcelona, Spain.)

McMahon, C. R., Hindell, M. A., and Harcourt, R. G. (2012). Publish or perish: why it’s important to publicise how, and if, research activities affect animals. Wildlife Research 39, 375–377.
Publish or perish: why it’s important to publicise how, and if, research activities affect animals.Crossref | GoogleScholarGoogle Scholar |

Meyer, L. C., Fick, L., Matthee, A., Mitchell, D., and Fuller, A. (2008). Hyperthermia in captured impala (Aepyceros melampus): a fright not flight response. Journal of Wildlife Diseases 44, 404–416.
Hyperthermia in captured impala (Aepyceros melampus): a fright not flight response.Crossref | GoogleScholarGoogle Scholar | 18436672PubMed |

Miller, B. F., Muller, L. I., Doherty, T., Osborn, D. A., Miller, K. V., and Warren, R. J. (2004). Effectiveness of antagonists for tiletamine–zolazepam/xylazine immobilization in female white-tailed deer. Journal of Wildlife Diseases 40, 533–537.
Effectiveness of antagonists for tiletamine–zolazepam/xylazine immobilization in female white-tailed deer.Crossref | GoogleScholarGoogle Scholar | 15465721PubMed |

Mishra, H. R. (1982). Ecology and behaviour of chital (Axis axis) in the Royal Chitwan National Park, Nepal (with comparative studies of hog deer (Axis porcinus), sambar (Cervus unicolor) and barking deer (Muntiacus muntjak). Ph.D. Thesis, University of Edinburgh, Edinburgh, Scotland.

Montané, J., Marco, I., López-Olvera, J., Perpinan, D., Manteca, X., and Lavin, S. (2003). Effects of acepromazine on capture stress in roe deer (Capreolus capreolus). Journal of Wildlife Diseases 39, 375–386.
Effects of acepromazine on capture stress in roe deer (Capreolus capreolus).Crossref | GoogleScholarGoogle Scholar | 12910765PubMed |

Murray, D. L., and Fuller, M. R. (2000). A critical review of the effects of marking on the biology of vertebrates. In ‘Research Techniques in Animal Ecology: Controversies and Consequences’. (Eds L. Boitani and T. K. Fuller.) pp. 15–64. (Columbia University Press: New York City, NY, USA.)

Northrup, J. M., Anderson, C. R., and Wittemyer, G. (2014). Effects of helicopter capture and handling on movement behavior of mule deer. The Journal of Wildlife Management 78, 731–738.
Effects of helicopter capture and handling on movement behavior of mule deer.Crossref | GoogleScholarGoogle Scholar |

Osofsky, S. A., and Hirsch, K. J. (2000). Chemical restraint of endangered mammals for conservation purposes: a practical primer. Oryx 34, 27–33.
Chemical restraint of endangered mammals for conservation purposes: a practical primer.Crossref | GoogleScholarGoogle Scholar |

Read, M. R., Caulkett, N. A., Symington, A., and Shury, T. K. (2001). Treatment of hypoxemia during xylazine–tiletamine–zolazepam immobilization of wapiti. The Canadian Veterinary Journal. La Revue Veterinaire Canadienne 42, 861–864.
| 11708204PubMed |

Sawicka, J., Fuller, A., Fick, L. G., Hetem, R. S., and Meyer, L. C. (2015). Efficacy of different cooling methods for capture-induced hyperthermia in antelope. South African Journal of Wildlife Research 45, 100–110.
Efficacy of different cooling methods for capture-induced hyperthermia in antelope.Crossref | GoogleScholarGoogle Scholar |

Semjonov, A., Andrianov, V., Raath, J. P., Orro, T., Laubscher, L., Pfitzer, S., and Tiirats, T. (2018). Evaluation of butorphanol–azaperone–medetomidine (BAM) in captive blesbok immobilization (Damaliscus pygargus phillipsi). Veterinary Anaesthesia and Analgesia 45, 496–501.
Evaluation of butorphanol–azaperone–medetomidine (BAM) in captive blesbok immobilization (Damaliscus pygargus phillipsi).Crossref | GoogleScholarGoogle Scholar | 29853414PubMed |

Smith, K. M., Powell, D. M., James, S. B., Calle, P. P., Moore, R. P., Zurawka, H. S., Goscilo, S., and Raphael, B. L. (2006). Anesthesia of male axis deer (Axis axis): evaluation of thiafentanil, medetomidine, and ketamine versus medetomidine and ketamine. Journal of Zoo and Wildlife Medicine 37, 513–517.
Anesthesia of male axis deer (Axis axis): evaluation of thiafentanil, medetomidine, and ketamine versus medetomidine and ketamine.Crossref | GoogleScholarGoogle Scholar | 17315436PubMed |

Swanson, C. C., Jenks, J. A., DePerno, C. S., Klaver, R. W., Osborn, R. G., and Tardiff, J. A. (2008). Does the use of vaginal-implant transmitters affect neonate survival rate of white-tailed deer Odocoileus virginianus? Wildlife Biology 14, 272–279.
Does the use of vaginal-implant transmitters affect neonate survival rate of white-tailed deer Odocoileus virginianus?Crossref | GoogleScholarGoogle Scholar |

Thompson, D. P., Crouse, J. A., McDonough, T. J., Badajos, O. H., Adsem, J., and Barboza, P. S. (2018). Vaginal implant transmitters for continuous body temperature measurement in moose. Wildlife Society Bulletin 42, 321–327.
Vaginal implant transmitters for continuous body temperature measurement in moose.Crossref | GoogleScholarGoogle Scholar |

Thompson, D. P., Crouse, J. A., McDonough, T. J., Barboza, P. S., and Jaques, S. (2020). Acute thermal and stress response in moose to chemical immobilization. The Journal of Wildlife Management 84, 1051–1062.
Acute thermal and stress response in moose to chemical immobilization.Crossref | GoogleScholarGoogle Scholar |

Thomson, P. (1992). Capture of dingoes from a helicopter with tranquilliser darts loaded with ketamine hydrochloride and xylazine hydrochloride. Wildlife Research 19, 601–603.
Capture of dingoes from a helicopter with tranquilliser darts loaded with ketamine hydrochloride and xylazine hydrochloride.Crossref | GoogleScholarGoogle Scholar |

Tracey, J. P., and Fleming, P. J. (2007). Behavioural responses of feral goats (Capra hircus) to helicopters. Applied Animal Behaviour Science 108, 114–128.
Behavioural responses of feral goats (Capra hircus) to helicopters.Crossref | GoogleScholarGoogle Scholar |

Tribe, A., Hanger, J., McDonald, I. J., Loader, J., Nottidge, B. J., McKee, J. J., and Phillips, C. J. (2014). A reproductive management program for an urban population of eastern grey kangaroos (Macropus giganteus). Animals (Basel) 4, 562–582.
A reproductive management program for an urban population of eastern grey kangaroos (Macropus giganteus).Crossref | GoogleScholarGoogle Scholar | 26480325PubMed |

Valkenburg, P., Tobey, R. W., and Kirk, D. (1999). Velocity of tranquilizer darts and capture mortality of caribou calves. Wildlife Society Bulletin 27, 894–896.

Van de Kerk, M., McMillan, B. R., Hersey, K. R., Roug, A., and Larsen, R. T. (2020). Effect of net‐gun capture on survival of mule deer. The Journal of Wildlife Management 84, 813–820.
Effect of net‐gun capture on survival of mule deer.Crossref | GoogleScholarGoogle Scholar |

Watter, K., Baxter, G. S., Pople, T., and Murray, P. J. (2019). Effects of wet season mineral nutrition on chital deer distribution in northern Queensland. Wildlife Research 46, 499–508.
Effects of wet season mineral nutrition on chital deer distribution in northern Queensland.Crossref | GoogleScholarGoogle Scholar |

Woolnough, A., Lethbridge, M., Hampton, J., Boardman, W., Rose, K., Campbell, S., Sharp, T., and Wales, S. (2011). ‘Development of SOPs and a Training Package for the Field Immobilisation of Large Herbivores in Judas Control Programs.’ (Department of Agriculture and Food Western Australia: Perth, Australia.)