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Metabolic and endocrine changes induced by chronic heatexposure in broiler chickens: growth performance, body composition and energy retention

Published online by Cambridge University Press:  09 March 2007

P. A. Geraert
Affiliation:
Station de Recherches Avicoles, Institut National de la Recherche Agronomique, 37380 Nouzilly, France
S. Guillaumin
Affiliation:
Station de Recherches Avicoles, Institut National de la Recherche Agronomique, 37380 Nouzilly, France
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Abstract

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The present study was performed in order to investigate the effect of chronic heat exposure (32",constant) on growth, body composition and energy retention of broiler chickens in relation to age. At 2and 4 weeks of age, fifty-four male Shaver broiler chickens were allocated to three treatments accordingto the following design: 22", ad lib. feeding (22AL); 32", ad lib. feeding (32AL); and 22", pair-feeding with the 32" group (22PF). Ambient temperature was kept constant at either 22 or 32" for 2 weeks. Heatexposure decreased feed intake by 14% YO between 2 and 4 weeks and by 24% YO between 4 and 6 weeks of age. Even with the same feed intake, chicks gained less weight at 32" than at 22", 55% less in young chickens and 22% less in older ones. Hot environmental conditions thus resulted in decreased feed efficiency; the feed:gain ratio was 2·85 at 32" compared with 2·06 at 22" in 22AL birds for the period4—6 weeks. Body composition appeared significantly affected by high ambient temperature. Feathering was reduced at 32" in absolute weight but not as a proportion of body weight. Heat-exposed birds showed a decrease in body protein content, protein gain and protein retention. Group 32AL birds were fatter than the pair-fed (22PF) or ad fib.-fed (22AL) groups at 22". The percentage of energy retained as fat was 79 in heat-exposed chickens compared with 64 in the control groups. The energy retained as protein:energy retained as fat for groups maintained at 22" (0·56) was twice that forthose maintained at 32" (0·28). These modifications should be investigated further in relation to metabolic and endocrinological changes.

Type
Chronic heat exposure in chickens
Copyright
Copyright © The Nutrition Society 1996

References

REFERENCES

Aïn Baziz, H., Geraert, P. A. & Guillaumin, S. (1990). Effects of high temperature and dietary composition on growth, body composition and energy retention in broilers. Proceedings of the VIIIth European Poultry Conference, vol. 1 ; pp. 626–629.Fira de Barcelona:World's Poultry Science Association Spanish Branch.Google Scholar
Aïn Baziz, H., Geraert, P. A., Padilha, J. C. F., Guillaumin, S., Marchè, G. & Ricard, F. H. (1993). Does heat exposure modify carcass quality of broilers? In Proceedings of the XIth European Symposium on the Quality ofPoultry Meat, vol. 1, pp. 5258 [Colin, P. Culioli, F. H. and Ricard, F. H. editorsr]. Tours; France: World's Poultry Science Association, French Branc.Google Scholar
Austic, R. E. (1985). Feeding poultry in hot and cold climates. In Stress Physiology in Livestock, vol. 3, pp. 123136 [Yousef, M. K. editor]. Boca Raton: CRC Press.Google Scholar
Balnave, D. (1972). The effect of temperature and length of exposure on liver composition and hepatic lipogenic enzyme activity in the immature male chick (Gallus domesticus). Comparative Biochemistry and Physiology 438, 9991007.Google Scholar
Brackenbury, J. H. & Avery, P. (1980). Energy consumption and ventilatory mechanisms in the exercising fowl. Comparative Biochemistry and Physiology 66A, 439445.Google Scholar
Cahaner, A., Deeb, N. & Gutman, M. (1993). Effects of the plumage-reducing naked-neck (Na) gene on the performance of fast-growing broilers at normal and high ambient temperatures. Poultry Science 72, 767775.Google Scholar
Cahaner, A. & Leenstra, F. (1992). Effects of high temperature on growth and efficiency of male and femalebroilers from lines selected for high weight gain, favorable feed conversion, and high or low fat content. Poultry Science 72, 12371250.CrossRefGoogle Scholar
Christon, R., Le Dividich, J., Seve, B. & Aumaitre, A. (1984). Iduence de la temperature ambiante sur I'utilisation mktabolique de l'ènergie et de l'azote alimentaires chez le rat en croissance (Effect of ambient temperature on the metabolic use of dietary energy and nitrogen in growing rat). Reproduction, Nutrition, Development 24, 327341.CrossRefGoogle Scholar
Chwalibog, A. & Eggum, B. O. (1989). Effect of temperature on performance, heat production, evaporative heat loss and body composition in chickens. Archiv fur Geflugelkunde 53, 119184.Google Scholar
Dale, N. M. & Fuller, H. L. (1979). Effect of diet composition on feed intake and growth of chicks under heat stress. I. Dietary fat levels. Poultry Science 58, 15291534.CrossRefGoogle Scholar
Dale, N. M. & Fuller, H. L. (1980). Effect of diet composition on feed intake and growth of chicks under heat stress. 11. Constant vs. cycling temperatures. Poultry Science 59, 14341441.CrossRefGoogle Scholar
Geraert, P. A., Guillaumin, S. & Zuprizal, (1992). Effect of high ambient temperature on dietary ME value in genetically lean and fat chickens. Poultry Science 71, 21132116.Google Scholar
Geraert, P. A., Guillaumin, S. & Leclercq, B. (1993). Are genetically lean broilers more resistant to hot climate? British Poultry Science 34, 643653.Google Scholar
Geraert, P. A., Padilha, J. C. F. & Guillaumin, S. (1993b). Metabolic and endocrine changes induced by heat exposure in chickens. Proceedings of the Nutrition Society 52, 165A.Google Scholar
Geraert, P. A., Padilha, J. C. F., Ain Baziz, H. & Guillaumin, S. (1994). Heat-induced changes in energy metabolism in broilers. In Proceedings of the13th Symposium on Energy Metabolism of Farm Animals. European Association for Animal Production Publication no. 76, pp. 375378 [Aguilera, J. F. editor]. Madrid: Consejo superior de Investigaciones Cientificas.Google Scholar
Howlider, M. A. R. & Rose, S. P. (1987). Temperature and growth in broilers. World's Poultry Science Journal 43, 228237.CrossRefGoogle Scholar
Keshavarz, K. & Fuller, H. L. (1980). The influence of widely fluctuating temperatures on heat production and energetic efficiency of broilers. Poultry Science 59, 21212128.Google Scholar
Leclercq, B., Chagneau, A. M., Cochard, T., Hamzaoui, S. & Larbier, M. (1993). Comparative utilisation of sulphur-containing amino acids by genetically lean or fat chickens. British Poultry Science 34, 383391.CrossRefGoogle ScholarPubMed
Leenstra, F. & Cahaner, A. (1992). Effects of low, normal, and high temperatures on slaughter yield of broilers from lines selected for high weight gain, favorable feed conversion, and high or low fat content. Poultry Science 71, 19942006.Google Scholar
MacLeod, M. G. (1992). Energy and nitrogen intake, expenditure and retention at 32" in growing fowl given diets with a wide range of energy and protein contents. British Journal of Nutrition 67, 195206.Google Scholar
Meltzer, A. (1986). Efficiency of effect of high ambient temperatures on food utilisation in male broilers. British Poultry Science 27, 349351.Google Scholar
Rinaldo, D. & Le Dividich, J. (1991). Effects of warm exposure on adipose tissue and muscle metabolism in growing pigs. Comparative Biochemistry and Physiology 100A, 9951002.CrossRefGoogle Scholar
Saadoun, A. & Leclercq, B. (1987). In vivo lipogenesis of genetically lean and fat chickens: effects of nutritional state and dietary fat. Journal of Nutrition 117, 428435.CrossRefGoogle ScholarPubMed
Smith, M. O. & Teeter, R. G. (1987). Influence of feed intake and ambient temperature stress on the relative yieldof broiler parts. Nutrition Reports International 35, 299306.Google Scholar
Znaniecka, G. (1967). Calorific value of protein and fat of the chicken's body, In Energy Metabolism of Farm Animals. Proceedings of the 4th European Association for Animal Production Symposium, pp. 407408 [ Blaxter, K. L. Kielanowski, J. and Thorbek, G. editors]. Warsaw, Poland: Oriel Press Ltd.Google Scholar
Zuprizal, M. Larbier, M., Chagneau, A. M. & Geraert, P. A. (1993). Influence of ambient temperature on true digestibility of protein and amino acids of rapeseed and soybean meals. Poultry Science 72, 289295.Google Scholar