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Road transport of pigs over a long distance: some aspects of behaviour, temperature and humidity during transport and some effects of the last two factors

Published online by Cambridge University Press:  02 September 2010

E. Lambooy
E. Lambooy
Affiliation:
Research Institute for Animal Production, Schoonoord, PO Box 501, 3700 AM Zeist, The Netherlands
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Abstract

During the transportation of pigs over a long distance, the environment in individual compartments may be related to the climate outside the trailer and may affect the animals. During three international and six experimental transport trials over long distances the relationships between outside and inside temperature and humidity were determined. During the experimental journey pig behaviour was studied and the effect of the environment on meat quality was also measured subsequently.

During the three international journeys the correlation coefficients between the outside and inside temperatures of the trailer were 0·88, 0·81 and 0·54, respectively, whereas there were low positive or negative correlations for relative humidity. The live-weight losses were 60, 80 and 60 g/kg, respectively, and the mortality averaged 0·3%.

The live-weight loss averaged 40 (s.d. 6) g/kg during each 25-h experimental journey, while the mortality was 1·4%. During the course of the journey, a majority of pigs was sitting or lying. During the night and at stops in transit most pigs were lying down.

The correlation coefficients between the outside and inside temperature averaged 0·94 in the artificially, and 0·95 in the naturally, ventilated compartments, while the coefficients for the humidity were 0·66 and 0·77, respectively. Pigs ventilated artificially showed a lower rigor mortis and lower temperatures of the m. longissimus dorsi (LD) and m. semimembranosus (SM) muscles post mortem compared with those ventilated naturally.

A higher temperature in the compartment was related to a lower temperature in the LD and SM muscles at 24 h (P ≤ 0·05) and a higher pH of the SM muscle in the carcass (P ≤ 0·05). However this was also affected by the location of the compartment on the vehicle. A major temperature fluctuation was related to a lower rigor value (P ≤ 0·05).

I t may be concluded from these experiments that the environmental conditions during transport over a long distance may change markedly. High temperatures in the compartment may increase stress, while correct artificial ventilation may decrease stress.

Type
Research Article
Information
Animal Production , Volume 46 , Issue 2 , April 1988 , pp. 257 - 263
Copyright
Copyright © British Society of Animal Science 1988

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References

Augustini, C. 1976. EKG- und Körper Temperatur Messungen an Schweinen wahrend der Mast und auf dem Transport. Fleischwirtschaft 56: 11331137.Google Scholar
Eikelenboom, G. 1972. Stress-susceptibility in swine and its relationship with energy metabolism in skeletal musculature. Dissertation, Utrecht University.Google Scholar
Hails, M. R. 1978. Transport stress in animals: a review. Animal Regulation Studies 1: 289–343.Google Scholar
Lambooy, E. 1983. Watering pigs during 30 hours road transport through Europe. Fleischwirtschaft. 63: 14561458.Google Scholar
Lambooy, E. 1984. Watering and feeding pigs during road transport for 24 hours. Proceedings of 30th European Meeting of Meat Research Workers, Bristol, pp. 67.Google Scholar
Lambooy, E., Garssen, G. J., Walstra, P., Mateman, G. and Merkus, G. S. M. 1985. Transport of pigs by car for two days; some aspects of watering and loading density. Livestock Production Science 13: 289299.CrossRefGoogle Scholar
Lockefeer, W. L. A. 1982. The logistics of animal transportation within Europe and into Europe from further afield. Proceedings of 2nd European Conference on the Protection of Farm Animals, Strasbourg, pp. 4249.Google Scholar
Logtestijn, J. G. Van, Romme, A. M. T. C. and Eikelenboom, G. 1982. Losses caused by transport of slaughter pigs in The Netherlands. In Transport of Animals Intended for Breeding, Production and Slaughter (ed. Moss, R.), pp. 105114, Martinus Nijhof, The Hague.CrossRefGoogle Scholar
Markov, E. 1981. Studies on weight losses and death rate in pigs transported over a long distance. Meat Industry Bulletin 14: 5.Google Scholar
Mothes, E. 1981. Technologic der Tierproduktion. Lehrbuch für Veterinarmediziner VEB Gustav Fischer Verlag, Jena.Google Scholar
Puiten, G. Van and Lambooy, E. 1982. The international transport of pigs. Proceedings of 2nd European Conference on the Protection of Farm Animals, Strasbourg, pp. 103.Google Scholar
Sterrenburg, P. and Ouwerkerk, E. N. J. 1985. Tabellen van warmte-productie en temperatuureisen van varkens Instiluut voor Mechanisatie, Arbeiá en Gebouwen-Nota 193. Wageningen.Google Scholar
Stolpe, J. 1979. Tierphysiologische Grundlagen der Stallklimagestaltung. Tierhygiene Information, Sonderheft. Institut für angewandte Tierhygiene, Eberswalde-Finow.Google Scholar
Sybesma, W. and Logtkstijn, J. G. Van. 1967. Rigor mortis und Fleischqualitat. Fleischwirtschaft 4: 408410.Google Scholar
Tielen, M. J. M. 1978. Klimaatsonderzoek in Varkensstallen in Relatie lot de Cezondheidstoestand van de Dieren. Gezondheidsdienst voor Dieren in Noord-Brabant. Boxtel.Google Scholar