Hostname: page-component-586b7cd67f-tf8b9 Total loading time: 0 Render date: 2024-11-26T14:44:19.689Z Has data issue: false hasContentIssue false

The effect of different housing systems and feeding regimes on the performance and rectal temperature of sheep

Published online by Cambridge University Press:  02 September 2010

K. Bøe
Affiliation:
Department of Agricultural Engineering, Agricultural University of Norway, Box 65, N-1432 Ås-NLH, Norway
J. J. Nedkvitne
Affiliation:
Department of Animal Science, Agricultural University of Norway, Box 25, N-1432 Ås-NLH, Norway
D. Austbø
Affiliation:
Department of Animal Science, Agricultural University of Norway, Box 25, N-1432 Ås-NLH, Norway
Get access

Abstract

The effect of insulated (IN) and uninsulated (UN) buildings on food intake, performance and body temperature of sheep was studied over 4 years. The lowest average monthly temperature was -13·1°C. In the UN the temperature was on average 6-6°C higher than outside but the temperature in the IN remained fairly constant and was close to 10°C. Summarized for all 4 years the roughage intake was proportionately 0·02 higher in the UN than in IN (P > 0·05). There was no effect of treatment on weight gain, but the weight of the fleece was higher in IN than in UN (1·74 kg v. 1·66 kg per sheep). The mean age at first oestrus was 222 days. There was no difference in the length of pregnancy and lambing percentage was 185% in both treatments. The average birth weight was higher for lambs born in UN than IN (5·10 v. 4·95 kg), but the weight at weaning was the same. On only one occasion was the rectal temperature lower for ewes in UN than IN before shearing (38·7°C v. 39·2°C). After shearing no effect of treatment was found except for the 1st year, but in year 2 there was an interaction between plane of nutrition and housing. Results clearly indicated that uninsulated buildings are well suited for sheep.

Type
Papers
Copyright
Copyright © British Society of Animal Science 1991

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Alexander, G. 1961. Temperature regulation in the new- born lambs. III. Effect of environmental temperature on metabolic rate, body temperature on metabolic rate, body temperatures, and respiratory quotient. Australian Journal of Agricultural Research 12:11521174.CrossRefGoogle Scholar
Alexander, G. 1962a. Temperature regulation in the new- born lamb. IV. The effect of wind and evaporation of water from the coat on metabolic rate and body temperature. Australian journal of Agricultural Research 13: 8299.CrossRefGoogle Scholar
Alexander, G. 1962b. Temperature regulation in the new- born lamb. V. Summit metabolism. Australian journal of Agricultural Research 13:100121.Google Scholar
Alexander, A. and Bell, A. W. 1975. Maximum thermogenic response to cold in relation to the proportion of brown adipose tissue and skeletal muscle in the body and to other parameters in young lambs. Biology of the Neonate 26: 182194.CrossRefGoogle Scholar
Austbo, D. 1985. [Comparative studies of production, feed intake and blood composition of sheep housed in insulated and uninsulated barns.] Ph.D. Thesis, Agricultural University of Norway.Google Scholar
Bee, K. 1985. Drikkevannsutstyr til sau. Norges landbrukshagskole, Institutt for bygn.teknikk, rapport no. 201.Google Scholar
Bae, K. 1986. Drenerende gulv for sau. Norges landbrukshegskole, Institutt for bygn.teknikk, rapport no. 218.Google Scholar
Bee, K. 1990. Thermoregulatory behaviour of sheep housed in insulated and uninsulated buildings. Applied Animal Behaviour Science 27: 243252.Google Scholar
Christopherson, R. J. and Kennedy, P. M. 1983. Effect of the thermal environment on digestion in ruminants. Canadian journal of Animal Science 63: 477496CrossRefGoogle Scholar
Degen, A. A. and Young, B. A. 1984. Effects of ingestion of warm, cold and frozen water on heat balance in cattle. Canadian journal of Animal Science 64: 7380.CrossRefGoogle Scholar
Einarsson, G. 1980. Ahrif húsagerdar á húsvist saudfjár. Fjølrit RALA, report no. 68.Google Scholar
Hahn, G. L. 1983. Management and housing of farm animals in hot environments. In Stress physiology in livestock (ed. Yousef, M. K.), pp. 151174. CRC Press, Boca Raton, Fl.Google Scholar
Hahn, G. L. and Bøe, K. 1985. Evaluating thermal demand in cold sheep housing. American Society of Agricultural Engineers, mid-central region meeting, St. Joseph, Missouri, paper no. MCR 85-150.Google Scholar
Hilgers, H. P. Untersuchungen iiber den einfluss tiefer umgebungstemperaturen aus den mineralsoff- (Mg, Na, K) und wasserhaushalt von schafen bei unterschiedlicher Mg- versorgung. Inaugural Dissertation, Tierartzlicher Hochschule, Hannover.Google Scholar
Hull, D. 1973. Thermoregulation in young animals. In Comparative physiology of thermoregulation, vol. Ill, ch. 4 Academic Press, New York.Google Scholar
Johnson, K. G. 1971. Body temperature lability in sheep and goats during short-term exposures to heat and cold. Journal of Agricultural Science, Cambridge 77: 267272.CrossRefGoogle Scholar
Kirk, A., Cooper, R. A. and Chapman, A. 1984. Effects of shearing housed pregnant ewes on their plasma glucose levels, lamb birth weight and lamb growth rate of 56 days. Animal Production 38: 524 (Abstr.).Google Scholar
Lilleng, H. and Gulden, L. A. 1979. Klima, foring og produksjon i ulike typer sauehus. Norges landrukshegskole, Instituttfor bygn.teknikk, Melding no. 99.Google Scholar
Lilleng, H. and Gulden, L. A. 1980. Ulike typer sauehus, spesielt med tanke pa arbeidsmiljeet. Norges landrukshogskole, Instituttfor bygn.teknikk, Melding no. 103.Google Scholar
Moose, M. G., Ross, C. V. and Pfander, W. H. 1969. Nutritional and environmental relationships with lambs. Journal of Animal Science 29: 619627.CrossRefGoogle Scholar
Mount, L. A. 1979. Adaption to the Thermal Environment. Man and his productive animals. Edward Arnold, London.Google Scholar
Nedkvitne, J. J. 1963. Granskingar over ulike hus og fôringsmåtar til sauer. Meldinger Norges landrukshaskole, Vol. 42, no. 12.Google Scholar
Nedkvitne, J. J. 1972. Effect of shearing before and after lambing. Ada Agriculturae Scandinavica 22: 97102.CrossRefGoogle Scholar
Nygaard, A. and Nedkvitne, J. J. 1977. Husforsok for sau. Norges landrukshagskole, Instituttfor bygn.teknikk, Stensiltrykk no. 142.Google Scholar
Olofsson, S. 1983. Naturlig ventilation i djurstallar. Sveriges Lantbruksuniversitet, Institutt for lantbrukets byggnadsteknik, Specialmeddelande no. 125.Google Scholar
Parr, G. 1980. Die Rolle des Stallklimas fur hohe Aufzuchtergebnisse und Mastleistungen in der indistrimassigen Lammermast. Tierzucht no. 11.Google Scholar
Sim, P. L. and Butcher, J. E. 1966. Water source effect on rumen temperature of sheep. Journal of Animal Science 25: 590 (abstr.).Google Scholar
Slee, J. 1970. Resistance to body cooling in male and female sheep, and the effects of previous exposure to chronic cold, acute cold and repeated short cold shocks. Animal Production 12:1321.Google Scholar
Slee, J. and Sykes, A. R. 1967. Acclimatisation of Scottish Blackface sheep to cold. 1. Rectal temperature responses. Animal Production 9:333347.Google Scholar
Statistical Analysis Systems Institute. 1982. SAS user's guide, statistics. SAS Institute, Cary, NC.Google Scholar
Sykes, A. R. and Slee, J. 1969. Cold exposure of Southdown and Welsh Mountain sheep. 1. Effects of breed, plane of nutrition and acclimatization to cold upon resistance to body cooling. Animal Production 11: 6575.Google Scholar
Ternouth, J. H. and Beattie, A. W. 1970. A note on the voluntary food consumption and the sodium-potassium ratio of sheep after shearing. Animal Production 12: 343346.Google Scholar
Verstegen, M. W. A. and Hel, W. van der. 1974. The effects of temperature and type of floor on metabolic rate and effective critical temperature in groups of growing pigs. Animal Production 18:111.Google Scholar
Vipond, J. E., King, M. E., Inglis, D. M. and Hunter, E. A. 1987. The effect of winter shearing of housed pregnant ewes on food intake and animal performance. Animal Production 45:211221.Google Scholar
Webster, A. J. F. 1976. Effects of cold on energy metabolism of sheep. In Progress in animal biometerology, vol. I, part 1 (ed. Johnsen, H. D.), pp. 218226. Swets and Zeitlinger, Amsterdam.Google Scholar
Webster, A. J. F., Hicks, A. M. and Hays, F. L. 1969. Cold climate and cold temperature induced changes in the heat production and thermal insulation of sheep. Canadian Journal of Physiology and Pharmacology 9:483.Google Scholar
Westra, R. and Christopherson, R. J. 1976. Effect of cold on digestability, retention time of digesta, reticulum motility and thyroid hormones in sheep. Canadian Journal of Animal Science 56: 699708.CrossRefGoogle Scholar
Young, B. A. 1981. Cold stress as it affects animal production. Journal of Animal Science 52:154163.CrossRefGoogle ScholarPubMed