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Head-only electrical stunning and bleeding of African catfish (Clarias gariepinus): assessment of loss of consciousness

Published online by Cambridge University Press:  11 January 2023

E Lambooij*
Affiliation:
Animal Science Group, Wageningen UR, Division of Nutrition and Food, PO Box 6S, 8200 AB Lelystad, The Netherlands
RJ Kloosterboer
Affiliation:
Animal Science Group, Wageningen UR, Netherlands Institute for Fisheries Research (RIVO), PO Box 68, 1970 AB Ijmuiden, The Netherlands
MA Gerritzen
Affiliation:
Animal Science Group, Wageningen UR, Division of Nutrition and Food, PO Box 6S, 8200 AB Lelystad, The Netherlands
JW van de Vis
Affiliation:
Animal Science Group, Wageningen UR, Netherlands Institute for Fisheries Research (RIVO), PO Box 68, 1970 AB Ijmuiden, The Netherlands
*
* Correspondence: [email protected]
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Abstract

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The objective was to evaluate the welfare implications of electrical stunning prior to gill-cutting of farmed African catfish as an alternative to live chilling in combination with gutting. Electroencephalogram (EEG) and electrocardiogram (ECG) recordings, in combination with observation of behaviour and responses to noxious stimuli, were used to assess brain and cardiac function in African catfish (body-weight 1571 ± 362 g [mean ± standard deviation], 32 males and 26 females). In the first experiment, the minimum electrical current required to induce a general epileptiform insult by head-only stunning was determined. The individual catfish were fixed in a specially designed restrainer, and applied voltages of 150 V, 200 V, 250 V, 300 V or 350 V (50 Hz AC) were delivered via scissor-model stunning tongs for approximately I s. A general epileptiform insult was observed in 31 fish, for which a successful EEG recording was obtained using 362 ± 32 V, 629 ± 180 mA for 1.2 s. The durations of the tonic, the clonic and the exhaustion phases were 8 ± 3 s, 12 ± 7 s and 7 ± 5 s as measured by EEG, respectively; a distinct exhaustion phase was not clear in II fish. The total duration of the insult was 23 ± 8 s. After the insult the fish recovered. The heart rate was 63 ± 29 beats min I prior to stunning. After stunning, the ECG revealed extrasystole and was irregular. By using an average current of 629 ± 180 mA (at approximately 360 V, 50 Hz AC), at least 91% of fish are effectively stunned with a confidence level of 95%. In the second experiment, the behaviour of 10 individual catfish, which were able to move freely in water, was observed following head-only stunning (370 V). The durations of the tonic, clonic and exhaustion phases in free-swimming fish were II ± 8 s, 20 ± 5 s and 23 ± 20 s, respectively. All fish recovered. In the third experiment, a group of seven catfish was head-only stunned followed by gill-cutting to kill them as a second procedure (ie after recovery from head-only stunning). No brain activity was seen on the EEG 12 ± 5 s after stunning. However, two fish showed responses to noxious stimuli after 2 min and 5 min. A second group of seven catfish was gill-cut only. They responded to noxious stimuli for at least 15 min. The blood loss was 1.2% and I.0% of live weight for the first and second group, respectively. It may be concluded from our results that African catfish are effectively stunned for 23 ± 8 s with a current of 629 ± 180 mA for 1.2 s, after which they recover. Since evoked responses may remain for at least 5 min after stunning and gill-cutting, we recommended that the stunning and killing procedure should be optimised.

Type
Research Article
Copyright
© 2004 Universities Federation for Animal Welfare

References

Blackmore, DK and Delaney, MW 1988 Slaughter of stock. Publication No 118, Veterinary Continuing Education. Massey University: Palmerston North, New ZealandGoogle Scholar
Clark, RE and Squire, LR 1998 Classical conditioning and brain systems: the role of awareness. Science 280: 7781CrossRefGoogle ScholarPubMed
Cook, CJ, Devine, CE, Gilbert, KV, Smith, DD and Maasland, SA 1995 The effect of electrical head-only stun duration on electroencephalographic-measured seizure and brain amino acid neurotransmitter release. Meat Science 40: 137147CrossRefGoogle ScholarPubMed
Cook, CJ, Maasland, SA, Devine, CE, Gilbert, KV and Blackmore, DK 1996 Changes in the release of amino acid neurotransmitters in the brains of calves and sheep after head-only electrical stunning and throat cutting. Research in Veterinary Science 60: 225261CrossRefGoogle ScholarPubMed
Gregory, NG and Wotton, SB 1990 Effect of stunning on spontaneous physical activity and evoked activity in the brain. British Poultry Science 31: 215220CrossRefGoogle ScholarPubMed
Hoar, WS and Randall, DJ 1970 Fish Physiology. Volume IV: The Nervous System, Circulation and Respiration pp 133168. Academic Press: New York, USAGoogle Scholar
Hoenderken, R 1978 Elektrische bedwelming van slachtvarkens. PhD thesis, State University of Utrecht, The Netherlands [Title translation: Electrical stunning of slaughter pigs]Google Scholar
Johnson, NL and Kotz, S 1969 Discrete Distributions. John Wiley: New York, USAGoogle Scholar
Kestin, SC 1994 Pain and Stress in Fish. Royal Society for the Prevention of Cruelty to Animals: Horsham, West Sussex, UKGoogle Scholar
Kestin, SC, Vis, JW van de and Robb, DHF 2002 Protocol for assessing brain function in fish and the effectiveness of method used to stun and kill them. Veterinary Record ISO: 302307CrossRefGoogle Scholar
Kestin, SC, Wotton, SB and Adams, S 1995 The effect of CO2, concussion or electrical stunning of rainbow trout on fish welfare. In: Scheire K, Apselagh L and Jonkeere H (eds) Quality in Aquaculture: Proceedings of the International Conference in Aquaculture Europe 1995, Trondheim, Norway pp 380381Google Scholar
Kooi, KA, Tucker, RP and Marshal, RR 1978 Fundamentals of Electroencephalography, Edn 2. Harper & Row: New York, USAGoogle Scholar
Lambooy, E 1982 Electrical stunning of sheep. Meat Science 6: 123135CrossRefGoogle ScholarPubMed
Lambooy, E and Spanjaard, WJ 1982 Electrical stunning of veal calves. Meat Science 6: 1525CrossRefGoogle ScholarPubMed
Lambooy E, Mens WBJ and Wimerma Greidanus TjB van 1985 Vasopressin and oxytocin in plasma of veal calves, sheep and pigs after high voltage electrical stunning. Meat Science 14: 127138CrossRefGoogle Scholar
Lambooij, E, Pieterse, C, Potgieter, CM, Snyman, JD and Nortjé, GL 1999 Some neural and behavioural aspects of electrical and mechanical stunning in ostriches. Meat Science 52: 339345CrossRefGoogle ScholarPubMed
Lambooij, E, Vis, JW van de, Kloosterboer, RJ and Pieterse, C 2002 Evaluation of head-only and head to tail electrical stunning of farmed eels (Anguilla anguilla, L) for development of a humane slaughter method. Aquaculture Research 33: 323331CrossRefGoogle Scholar
Lopes da Silva, HF 1983 The assessment of consciousness: general principles and practical aspects. In: Eikelenboom, G (ed) Stunning of Animals for Slaughter pp 312. Martinus Nijhoff: The Hague, The NetherlandsGoogle Scholar
Nieuwenhuys, R, ten Donkelaar, HJ and Nicholson, C 1998 The Central Nervous System of Vertebrates. Volume 2: Holosteans and Teleosts pp 759913. Springer Verlag: Heidelberg, GermanyCrossRefGoogle Scholar
Overmier, JB and Hollis, KL 1990 Fish in the think tank: learning, memory and integrated behaviour. In: Kesner, RP and Olson, DS (eds) Neurobiology of Comparative Cognition pp 205236. Lawrence Erlbaum: Hillsdale, NJ, USAGoogle Scholar
Robb, DFH and Kestin, SC 2002 Methods used to kill fish: field observations and literature reviewed. Animal Welfare II: 269282Google Scholar
Rose, JD 2002 The neurobehavioral nature of fishes and the question of awareness and pain. Reviews in Fisheries Science 10: 138CrossRefGoogle Scholar
Skjervold, PO, Fjæra, SV, østby, PB and Einen, O 2001 Live-chilling and crowding stress before slaughter of Atlantic salmon (Salmo salar). Aquaculture 192: 265280CrossRefGoogle Scholar
Sneddon, LU 2002 Anatomical and electrophysiological analysis of the trigeminus nerve in a teleost fish, Oncorhynchus mykiss. Neuroscience Letters 319: 167171CrossRefGoogle Scholar
Spierts, ILY 1999 Swimming and muscle structure in fish. PhD thesis, Wageningen University, The NetherlandsGoogle Scholar
Van de Vis, JW, Kestin, SC, Robb, DFH, Oehlenschläger, J, Lambooij, E, Münkner, W, Kuhlmann, H, Kloosterboer, RJ, Tejada, M, Huidobro, A, Otterå, H, Roth, B, Sørensen, NK, Akse, L, Byrne, H and Nesvadba, P 2003 Is humane slaughter of fish possible for industry? Aquaculture Research 34: 211220CrossRefGoogle Scholar
Verheijen, FJ and Flight, W F G 1997 Decapitation and brining: experimental tests show that after these commercial methods for slaughtering eel Anguilla anguilla (L.), death is not instantaneous. Aquaculture Research 28: 361366CrossRefGoogle Scholar
Wageneder FM and Schuy St 1967 Electro-therapeutic sleep and electro-aneasthesia. Proceedings of the First International Symposium of the Excerpta Medica Foundation, Graz, Austria, 1966. Excerpta Medica Foundation: Amsterdam, The NetherlandsGoogle Scholar
Warriss, PD and Wilkins, LJ 1987 Exsanguination of meat animals. In: Carter, HE and Carter, VR (eds) Pre-Slaughter Stunning of Food Animals pp 150158. Royal Society for the Prevention of Cruelty to Animals: Horsham, Sussex, UKGoogle Scholar
Wiepkema, PR 1997 The emotional vertebrate. In: Dol, M, Kasanmoentalib, S, Lijmbach, S, Rivas, E and van den Bos, R (eds) Animal Consciousness and Animal Ethics pp 93102. Van Gorcum & Comp BV: Assen, The NetherlandsGoogle Scholar