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The Effect of Transport on Core and Peripheral Body Temperatures and Heart Rate of Sheep

Published online by Cambridge University Press:  11 January 2023

J R Ingram
Affiliation:
Technology Development Group, HortResearch, Private Bag 3123, Hamilton, New Zealand
C J Cook*
Affiliation:
Technology Development Group, HortResearch, Private Bag 3123, Hamilton, New Zealand
P J Harris
Affiliation:
Technology Development Group, HortResearch, Private Bag 3123, Hamilton, New Zealand
*
* Contact for correspondence and requests for reprints
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Abstract

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The effect of transport on core and peripheral body temperatures and heart rate was assessed in ten 18-month-old Coopworth ewes (Ovis aries) Manual recordings of core (rectal) temperatures were obtained, and automated logging of peripheral (external auditory canal and pinna) temperatures and heart rate was carried out on the day prior to (day 1) and during (day 2) a standardised transport procedure. Transport produced a significant increase in the rectal temperature, which declined following unloading. Peripheral measures of body temperature also exhibited changes with transport. However, both ear-canal and pinna temperatures declined during actual transport, reflecting to some extent the decline in ambient temperatures recorded externally by sensors on the ear tags of the animals. Peripheral measurement of temperature, particularly at the readily accessible ear canal, may offer potential as a technique for the long-term monitoring of thermal responses to stress. However, further research is required into the potentially confounding effects of ambient temperature and wind chill factors.

Type
Technical Contribution
Copyright
© 2002 Universities Federation for Animal Welfare

References

Borsini, F, Lecci, A, Volterra, G and Meli, A 1989 A model to measure anticipatory anxiety in mice? Psychopharmacology 98: 207211CrossRefGoogle Scholar
Briese, E and Cabanac, M 1991 Stress hyperthermia: physiological arguments that it is a fever. Physiology & Behavior 49: 11531157CrossRefGoogle ScholarPubMed
Broom, D M 1988 The scientific assessment of animal welfare. Applied Animal Behaviour Science 20: 519CrossRefGoogle Scholar
Cabanac, A and Briese, E 1992 Handling elevates the colonic temperature of mice. Physiology & Behavior 51: 9598CrossRefGoogle ScholarPubMed
Jacobson, L H and Cook, C J 1998 Partitioning psychological and physical sources of transport-related stress in young cattle. The Veterinary Journal 155: 205208CrossRefGoogle ScholarPubMed
Harris, P J 1999 The auditory evoked response as an indicator of stress in free-ranging animals. PhD Thesis, University of Waikato, Hamilton, New ZealandGoogle Scholar
Hill, R W and Veghte, J H 1976 Jackrabbit ears: surface temperatures and vascular responses. Science 194: 436438CrossRefGoogle ScholarPubMed
Kluger, M J, O'Reilly, B, Shope, T R and Vånder, A J 1987 Further evidence that stress hyperthermia is a fever. Physiology & Behavior 39: 763766CrossRefGoogle ScholarPubMed
Knowles, T G, Brown, S N, Warriss, P D, Phillips, A J, Dolan, S K, Hunt, P, Ford, J E, Edwards, J E and Watkins, P E 1995 Effects on sheep of transport by road for up to 24 hours. The Veterinary Record 136: 431438CrossRefGoogle ScholarPubMed
Kopin, I J, Eisenhofer, G and Goldstein, D 1988 Sympathoadrenal medullary system and stress. Advances in Experimental Medicine and Biology 245: 1123CrossRefGoogle ScholarPubMed
Marezziti, D, Di Muro, A and Castrogiovanni, P 1992 Psychological stress and body temperature changes in humans. Physiology & Behavior 52: 393395CrossRefGoogle Scholar
Mohr, E and Leuschner, T 1989 Microcomputer assisted telemetric system for recording ultradian temperature fluctations in farm animals. Journal of Veterinary Medicine 36: 331339CrossRefGoogle Scholar
Morimoto, A, Watanabe, T, Myogin, T and Murakami, N 1987 Restraint stress elicits acute phase responses in rabbits. Pflügers Archives 410: 554556CrossRefGoogle Scholar
Nakamori, T, Morimoto, A, Morimoto, K, Tan, N and Murakami, N 1993 Effects of alpha- and beta-adrenergic antagonists on rise in body temperature induced by psychological stress in rats. American Journal of Physiology 264: R156R161Google ScholarPubMed
Parrott, R F and LLoyd, D M 1995 Restraint, but not frustration, induces prostaglandin-mediated hyperthermia in pigs. Physiology & Behavior 57: 1051 -1055CrossRefGoogle Scholar
Parrott, R F, Hall, S J G and Lloyd, D M 1998 Heart rate and stress hormone responses of sheep to road transport following two different loading procedures. Animal Welfare 7: 257267Google Scholar
Parrott, R F, Lloyd, D M and Brown, D 1999 Transport stress and exercise hyperthermia recorded in sheep by radiotelemetry. Animal Welfare 8: 2734Google Scholar
Poole, S and Stephenson, J E 1977 Core temperature: some shortcomings of rectal temperature measurements. Physiology & Behavior 18: 203205CrossRefGoogle ScholarPubMed
Singer, R, Harker, C T, Vander, A J and Kluger, M J 1986 Hyperthermia induced by open-field stress is blocked by salicylate. Physiology & Behavior 36: 11791182CrossRefGoogle ScholarPubMed
Snow, A E and Horita, A 1982 Interaction of apomorphine and stressors in the production of hyperthermia in the rabbit. Journal of Pharmacology and Experimental Therapeutics 220: 335339Google ScholarPubMed
Tanaka, H, Yanase, M and Nakayama, T 1988 Body temperature regulation in rats during exercise of various intensities at different ambient temperatures. Japanese Journal of Physiology 38: 167177Google ScholarPubMed
Toates, F 1995 Stress: Conceptual and Biological Aspects. John Wiley & Sons: New York, USAGoogle Scholar