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Food, fibre and pharmaceuticals from animals
REVIEW

Euthanasia of laying hens: an overview

Ellen C. Jongman https://orcid.org/0000-0002-7504-0280 A B and Andrew D. Fisher A
+ Author Affiliations
- Author Affiliations

A Animal Welfare Science Centre, Faculty of Veterinary and Agricultural Sciences, Corner Flemington Road and Park Drive, Level 3, University of Melbourne, Parkville, Vic. 3010, Australia.

B Corresponding author. Email: EJongman@unimelb.edu.au

Animal Production Science 61(10) 1042-1047 https://doi.org/10.1071/AN20224
Submitted: 8 April 2020  Accepted: 28 January 2021   Published: 3 March 2021

Abstract

Euthanasia of an animal requires that its death occurs in as humane a manner as possible. There are three key scenarios for euthanasia in the egg industry: the humane destruction of day-old male chicks, euthanasia of individual birds, and the depopulation of flocks for disease control or because conventional transport and slaughter is uneconomic. For day-old chicks, instant mechanical maceration, although conditionally humane, presents a public perception problem. Submerging in CO2 gas is less confronting but is thought to be aversive to animals unless more expensive and harder to manage inert gases are incorporated. Future technologies involving pre-hatching sex determination or sex selection may largely solve the problem when fully developed. For the euthanasia of individual birds within the flock, manual cervical dislocation has been shown to be humane when performed by trained personnel who are willing to perform the procedure. Penetrating and non-penetrating mechanical devices that cause irreversible brain trauma are becoming more available and represent a humane alternative to cervical dislocation when properly placed and maintained. These devices may be less confronting for some staff to use than is cervical dislocation. For whole-flock euthanasia, the overwhelming requirements of disease control and public safety may override considerations of euthanasia. Whole-shed CO2 (or other gas combinations) and foam-based alternatives can be used, but have challenges in commercial settings. Modified atmosphere killing units or low atmospheric stunning systems are alternatives that overcome some of these practical problems, but do require birds to be handled.

Keywords: euthanasia, laying hens, day-old chicks, depopulation, CO2.


References

Alphin RL, Rankin MK, Johnson KJ, Benson ER (2010) Comparison of water-based foam and inert-gas mass emergency depopulation methods. Avian Diseases 54, 757–762.
Comparison of water-based foam and inert-gas mass emergency depopulation methods.Crossref | GoogleScholarGoogle Scholar | 20521728PubMed |

AVMA (2020) Poultry. In ‘AVMA guidelines for the euthanasia of animals: 2020 edition’. Report of the AVMA Panel on Euthanasia. pp. 76–78.

Bader S, Meyer-Kühling B, Günther R, Breithaupt A, Rautenschlein S, Gruber AD (2014) Anatomical and histologic pathology induced by cervical dislocation following blunt head trauma for on-farm euthanasia of poultry. Journal of Applied Poultry Research 23, 546–556.
Anatomical and histologic pathology induced by cervical dislocation following blunt head trauma for on-farm euthanasia of poultry.Crossref | GoogleScholarGoogle Scholar |

Baker BI, Torrey S, Widowski TM, Turner PV, Knezacek TD, Nicholds J, Schwean-Lardner K (2019) Evaluation of carbon dioxide induction methods for the euthanasia of day-old cull broiler chicks. Poultry Science 98, 2043–2053.
Evaluation of carbon dioxide induction methods for the euthanasia of day-old cull broiler chicks.Crossref | GoogleScholarGoogle Scholar | 30624707PubMed |

Baker BI, Torrey S, Widowski TM, Turner PV, Knezacek TD, Nicholds J, Schwean-Lardner K (2020) Defining characteristics of immersion carbon dioxide gas for successful euthanasia of neonatal and young broilers. Poultry Science 99, 4408–4416.
Defining characteristics of immersion carbon dioxide gas for successful euthanasia of neonatal and young broilers.Crossref | GoogleScholarGoogle Scholar | 32867984PubMed |

Bandara RMAS, Torrey S, Turner PV, Schwean-Lardner K, Widowski TM (2019) Anatomical pathology, and behavioral and physiological responses induced by application of non-penetrating captive bolt devices in layer chickens. Frontiers in Veterinary Science 6, 89
Anatomical pathology, and behavioral and physiological responses induced by application of non-penetrating captive bolt devices in layer chickens.Crossref | GoogleScholarGoogle Scholar | 30984770PubMed |

Benson ER, Alphin RL, Rankin MK, Caputo MP, Hougentogler DP, Johnson AL (2012) Mass emergency water-based foam depopulation of poultry. Avian Diseases 56, 891–896.
Mass emergency water-based foam depopulation of poultry.Crossref | GoogleScholarGoogle Scholar | 23402109PubMed |

Benson E, Weiher J, Alphin R, Farnell M, Hougentogler D (2018) Evaluation of two compressed air foam systems for culling caged layer hens. Animals 8, 61
Evaluation of two compressed air foam systems for culling caged layer hens.Crossref | GoogleScholarGoogle Scholar |

Bruijnis MRN, Blok V, Stassen EN, Gremmen HGJ (2015) Moral ‘Lock-In’ in responsible innovation: the ethical and social aspects of killing day-old chicks and its alternatives. Journal of Agricultural & Environmental Ethics 28, 939–960.
Moral ‘Lock-In’ in responsible innovation: the ethical and social aspects of killing day-old chicks and its alternatives.Crossref | GoogleScholarGoogle Scholar |

EFSA Panel on Animal Health and Welfare (AHAW), Nielsen SS, Alvarez J, Bicout DJ, Calistri P, Depner K, Drewe JA, Garin‐Bastuji B, Rojas JLG, Gortázar Schmidt C, Chueca MÁM, Roberts HC, Sihvonen LH, Spoolder H, Stahl K, Calvo AV, Viltrop A, Winckler C, Candiani D, Fabris C, Van der Stede Y, Michel V (2019) Killing for purposes other than slaughter: poultry. EFSA Journal 17, e05850

Galli R, Preusse G, Uckermann O, Bartels T, Krautwald-Junghanns ME, Koch E, Steiner G (2017) In ovo sexing of chicken eggs by fluorescence spectroscopy. Analytical and Bioanalytical Chemistry 409, 1185–1194.
In ovo sexing of chicken eggs by fluorescence spectroscopy.Crossref | GoogleScholarGoogle Scholar | 27966169PubMed |

Gent TC, Gebhardt-Henrich S, Schild SLA, Rahman AA, Toscano MJ (2020) Evaluation of poultry stunning with low atmospheric pressure, carbon dioxide or nitrogen using a single aversion testing paradigm. Animals 10, 1308
Evaluation of poultry stunning with low atmospheric pressure, carbon dioxide or nitrogen using a single aversion testing paradigm.Crossref | GoogleScholarGoogle Scholar |

Gerritzen MA, Lambooij E, Stegeman A, Spruijt BM (2006) Killing of poultry during the 2003 avian influenza epidemic in The Netherlands. The Veterinary Record 159, 39–42.
Killing of poultry during the 2003 avian influenza epidemic in The Netherlands.Crossref | GoogleScholarGoogle Scholar | 16829597PubMed |

Göhler D, Fischer B, Meissner S (2017) In-ovo sexing of 14-day-old chicken embryos by pattern analysis in hyperspectral images (VIS/NIR spectra): a non-destructive method for layer lines with gender-specific down feather color. Poultry Science 96, 1–4.
In-ovo sexing of 14-day-old chicken embryos by pattern analysis in hyperspectral images (VIS/NIR spectra): a non-destructive method for layer lines with gender-specific down feather color.Crossref | GoogleScholarGoogle Scholar | 27591278PubMed |

Gregory NG, Wilkins LJ (1989) Broken bones in domestic fowl: handling and processing damage in end‐of‐lay battery hens. British Poultry Science 30, 555–562.
Broken bones in domestic fowl: handling and processing damage in end‐of‐lay battery hens.Crossref | GoogleScholarGoogle Scholar | 2819499PubMed |

Gregory NG, Wotton SB (1990) Comparison of neck dislocation and percussion of the head on visual evoked responses in the chicken’s brain. The Veterinary Record 126, 570–572.

Grist A, Lines JA, Knowles TG, Mason CW, Wotton SB (2018) The use of a mechanical non-penetrating captive bolt device for the euthanasia of neonate lambs. Animals 8, 49
The use of a mechanical non-penetrating captive bolt device for the euthanasia of neonate lambs.Crossref | GoogleScholarGoogle Scholar |

Gurung S, White D, Archer G, Zhao D, Farnell Y, Byrd J, Peebles E, Farnell M (2018a) Evaluation of alternative euthanasia methods of neonatal chickens. Animal 8, 37
Evaluation of alternative euthanasia methods of neonatal chickens.Crossref | GoogleScholarGoogle Scholar |

Gurung S, Hoffman J, Stringfellow K, Abi-Ghanem D, Zhao D, Caldwell D, Lee J, Styles D, Berghman L, Byrd J, Farnell Y (2018b) Depopulation of caged layer hens with a compressed air foam system. Animals 8, 11
Depopulation of caged layer hens with a compressed air foam system.Crossref | GoogleScholarGoogle Scholar |

Gurung S, White D, Archer G, Styles D, Zhao D, Farnell Y, Byrd J, Farnell M (2018c) Carbon dioxide and nitrogen infused compressed air foam for depopulation of caged laying hens. Animals 8, 6
Carbon dioxide and nitrogen infused compressed air foam for depopulation of caged laying hens.Crossref | GoogleScholarGoogle Scholar |

Humane Slaughter Association (2005) Instantaneous mechanical destruction. Available at https://www.hsa.org.uk/downloads/technical-notes/TN9-mechanical-destruction.pdf [Verified 20 August 2009]

Humane Slaughter Association (2006) Gas killing of chicks in hatcheries. Available at https://www.hsa.org.uk/downloads/technical-notes/TN14-gas-killing-of-chicks-in-hatcheries.pdf [Verified 20 August 2019]

Kaleta EF, Redmann T (2008) Approaches to determine the sex prior to and after incubation of chicken eggs and of day-old chicks. World’s Poultry Science Journal 64, 391–399.
Approaches to determine the sex prior to and after incubation of chicken eggs and of day-old chicks.Crossref | GoogleScholarGoogle Scholar |

Krautwald-Junghanns ME, Cramer K, Fischer B, Förster A, Galli R, Kremer F, Mapesa EU, Meissner S, Preisinger R, Preusse G, Schnabel C (2018) Current approaches to avoid the culling of day-old male chicks in the layer industry, with special reference to spectroscopic methods. Poultry Science 97, 749–757.
Current approaches to avoid the culling of day-old male chicks in the layer industry, with special reference to spectroscopic methods.Crossref | GoogleScholarGoogle Scholar | 29294120PubMed |

Leenstra F, Munnichs G, Beekman V, Van den Heuvel-Vromans E, Aramyan L, Woelders H (2011) Killing day-old chicks? Public opinion regarding potential alternatives. Animal Welfare 20, 37.

Mancinelli AC, Dal Bosco A, Mattioli S, Ranucci D, Castellini C (2018) Mobile poultry processing unit as a resource for small poultry farms: planning and economic efficiency, animal welfare, meat quality and sanitary implications. Animals 8, 229
Mobile poultry processing unit as a resource for small poultry farms: planning and economic efficiency, animal welfare, meat quality and sanitary implications.Crossref | GoogleScholarGoogle Scholar |

Martin JE, Christensen K, Vizzier-Thaxton Y, McKeegan DE (2016) Effects of light on responses to low atmospheric pressure stunning in broilers. British Poultry Science 57, 585–600.
Effects of light on responses to low atmospheric pressure stunning in broilers.Crossref | GoogleScholarGoogle Scholar | 27352226PubMed |

Martin JE, Sandercock DA, Sandilands V, Sparrey J, Baker L, Sparks NH, McKeegan DE (2018a) Welfare risks of repeated application of on-farm killing methods for poultry. Animals 8, 39
Welfare risks of repeated application of on-farm killing methods for poultry.Crossref | GoogleScholarGoogle Scholar |

Martin JE, Sandilands V, Sparrey J, Baker L, McKeegan DE (2018b) On farm evaluation of a novel mechanical cervical dislocation device for poultry. Animals 8, 10.

Martin JE, Sandilands V, Sparrey J, Baker L, Dixon LM, McKeegan DE (2019) Welfare assessment of novel on-farm killing methods for poultry. PLoS One 14, e0212872
Welfare assessment of novel on-farm killing methods for poultry.Crossref | GoogleScholarGoogle Scholar | 30794690PubMed |

McKeegan DEF, Sparks NHC, Sandilands V, Demmers TGM, Boulcott P, Wathes CM (2011) Physiological responses of laying hens during whole-house killing with carbon dioxide. British Poultry Science 52, 645–657.
Physiological responses of laying hens during whole-house killing with carbon dioxide.Crossref | GoogleScholarGoogle Scholar |

McKeegan DEF, Reimert HGM, Hindle VA, Boulcott P, Sparrey JM, Wathes CM, Gerritzen MA (2013a) Physiological and behavioral responses of poultry exposed to gas-filled high expansion foam. Poultry Science 92, 1145–1154.

McKeegan DEF, Sandercock DA, Gerritzen MA (2013b) Physiological responses to low atmospheric pressure stunning and the implications for welfare. Poultry Science 92, 858–868.
Physiological responses to low atmospheric pressure stunning and the implications for welfare.Crossref | GoogleScholarGoogle Scholar |

Raj ABM (2004) Stunning and slaughter. In ‘Welfare of laying hens’. pp. 375–389. (CAB International: Oxon, UK)

Raj AB, Whittington PE (1995) Euthanasia of day-old chicks with carbon dioxide and argon. The Veterinary Record 136, 292–294.
Euthanasia of day-old chicks with carbon dioxide and argon.Crossref | GoogleScholarGoogle Scholar | 7793036PubMed |

Raj ABM, Sandilands V, Sparks NHC (2006) Review of gaseous methods of killing poultry on-farm for disease control purposes. The Veterinary Record 159, 229–235.
Review of gaseous methods of killing poultry on-farm for disease control purposes.Crossref | GoogleScholarGoogle Scholar |

Scott P (2015) Development and extension of industry best practice for on-farm euthanasia of spent layer hens. Poultry CRC report.

Sparrey J, Sandercock DA, Sparks NHC, Sandilands V (2014) Current and novel methods for killing poultry individually on-farm. World’s Poultry Science Journal 70, 737–758.
Current and novel methods for killing poultry individually on-farm.Crossref | GoogleScholarGoogle Scholar |

Terlouw C, Bourguet C, Deiss V (2016) Consciousness, unconsciousness and death in the context of slaughter. Part I. Neurobiological mechanisms underlying stunning and killing. Meat Science 118, 133–146.
Consciousness, unconsciousness and death in the context of slaughter. Part I. Neurobiological mechanisms underlying stunning and killing.Crossref | GoogleScholarGoogle Scholar | 27103547PubMed |

Turner PV, Doonan G (2010) Developing on-farm euthanasia plans. The Canadian Veterinary Journal. La Revue Veterinaire Canadienne 51, 1031

Turner PV, Kloeze H, Dam A, Ward D, Leung N, Brown EEL, Whiteman A, Chiappetta ME, Hunter DB (2012) Mass depopulation of laying hens in whole barns with liquid carbon dioxide: evaluation of welfare impact. Poultry Science 91, 1558–1568.
Mass depopulation of laying hens in whole barns with liquid carbon dioxide: evaluation of welfare impact.Crossref | GoogleScholarGoogle Scholar | 22700499PubMed |

Webster AB (2007) ‘Commercial egg tip: depopulation methods for commercial layer flocks, part 2.’

Webster AB, Collett SR (2012) A mobile modified-atmosphere killing system for small-flock depopulation. Journal of Applied Poultry Research 21, 131–144.
A mobile modified-atmosphere killing system for small-flock depopulation.Crossref | GoogleScholarGoogle Scholar |

Weissmann A, Reitemeier S, Hahn A, Gottschalk J, Einspanier A (2013) Sexing domestic chicken before hatch: a new method for in ovo gender identification. Theriogenology 80, 199–205.
Sexing domestic chicken before hatch: a new method for in ovo gender identification.Crossref | GoogleScholarGoogle Scholar | 23726296PubMed |

Woods J, Shearer JK, Hill J (2010) Recommended on-farm euthanasia practices. In ‘Improving animal welfare: a practical approach’. pp. 186–213.

Woolcott CR, Torrey S, Turner PV, Serpa L, Schwean-Lardner K, Widowski TM (2018) Evaluation of two models of non-penetrating captive bolt devices for on-farm euthanasia of turkeys. Animals 8, 42
Evaluation of two models of non-penetrating captive bolt devices for on-farm euthanasia of turkeys.Crossref | GoogleScholarGoogle Scholar |