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Increasing the incubation temperature between embryonic day 7 and 10 has no influence on the growth and slaughter characteristics as well as meat quality of broilers

Published online by Cambridge University Press:  08 January 2010

C. Werner ,
C. Wecke ,
F. Liebert  and
M. Wicke
C. Werner*
Affiliation:
Institute of Food Quality and Safety, University of Veterinary Medicine, D-30173 Hanover, Germany
C. Wecke
Affiliation:
Division Animal Nutrition Physiology, Department of Animal Sciences, Georg-August-University Goettingen, D-37075 Goettingen, Germany
F. Liebert
Affiliation:
Division Animal Nutrition Physiology, Department of Animal Sciences, Georg-August-University Goettingen, D-37075 Goettingen, Germany
M. Wicke
Affiliation:
Division Animal Breeding and Genetics, Department of Animal Sciences, Georg-August-University Goettingen, D-37075 Goettingen, Germany
*
E-mail: Carsten.Werner@tiho-hannover.de
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Abstract

Avian embryogenesis can be manipulated by alteration of the temperature during incubation of the brooding egg. Investigations in turkeys showed that a higher temperature during early embryogenesis positively affects the myogenesis accompanied with a higher muscle fibre number (MFN). The aim of this study was to transfer this result to broiler and to investigate if an alteration of the temperature also affects the meat quality after slaughter of the birds. Therefore brooding eggs of the Cobb 500 broiler genetic were either incubated at 37.5°C during the whole incubation period (at normal temperature (NT)), or at 38.5°C during embryonic day (ED) 7 to 10 (at high temperature (HT)). After hatch the chicks were sexed and reared up to an age of 36 days in an experimental stable. Growth and feed conversion properties were determined during this period. After slaughter different meat quality characteristics as well as the muscle microstructure were analysed. The hatch rate and chick weight did not differ between the broiler of the NT and HT group. After 36 days the final body weights and the cumulative feed conversion rates were not different in the NT and HT groups. No differing results were obtained with regard to the slaughter, breast and leg weights of the NT and HT animals. Considering the gender of the animals no differences in the slaughter characteristics could be determined although the carcass and breast weights of the HT cocks were tendentially higher. The muscle fibre areas and MFNs in the breast muscles of the NT and HT cocks did not differ significantly and were in the range of the HT hens. Only the NT hens had significantly larger muscle fibres and less MFN than the other animals. With regard to the meat quality characteristics no clear differences of the pH, electrical conductivity (EC) and colour (L*a*b*) values were found. The L*a*b* values in the investigated breast muscles of all broilers usually increased during ageing. The increase of the incubation temperature had no impact on the hatch, growth, slaughter and meat quality characteristics of the broiler except for the tendentially higher carcass and breast weights of the HT cocks. However, the decrease of the fibre areas in the HT hens is an interesting effect of using a higher incubation temperature, which needs to be considered when implicating further investigations.

Keywords

broiler, incubation, carcass characteristics, meat quality, muscle structure
Type
Full Paper
Information
animal , Volume 4 , Issue 5 , May 2010 , pp. 810 - 816
Copyright
Copyright © The Animal Consortium 2009

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References

Berri, C, Le Bihan-Duval, E, Baeza, E, Chartrin, P, Picgirard, L, Jehl, N, Quentin, M, Picard, M, Duclos, MJ 2005. Further processing characteristics of breast and leg meat from fast-, medium- and slow-growing commercial chickens. Animal Research 54, 123134.CrossRefGoogle Scholar
Berri, C, Le Bihan-Duval, E, Debut, M, Sante-Lhoutellier, V, Baeza, E, Gigaud, V, Jego, Y, Duclos, MJ 2007. Consequence of muscle hypertrophy on characteristics of Pectoralis major muscle and breast meat quality of broiler chickens. Journal of Animal Science 85, 20052011.CrossRefGoogle ScholarPubMed
Cavitt, LC, Hargis, BM, Owens, CM 2004. The use of halothane and succinylcholine to identify broilers prone to developing pale, soft, exudative meat. Poultry Science 83, 14401444.Google Scholar
Chan, T, Burggren, W 2005. Hypoxic incubation creates differential morphological effects during specific developmental critical windows in the embryo of the chicken (Gallus gallus). Respiratory Physiology and Neurobiology 145, 251263.Google Scholar
Christensen, VL, McMurtry, JP, Donaldson, WE, Nestor, KE 2001. Incubation temperature affects plasma insulin-like growth factors in embryos from selected lines of turkeys. Poultry Science 80, 949954.CrossRefGoogle ScholarPubMed
Cobb-Vantress 2008. Cobb 500 Broiler Performance and Nutrition Supplement. Retrieved from http://www.cobb-vantress.com. Cobb-Vantress Inc., Siloam Springs, AR, USA.Google Scholar
Collin, A, Berri, C, Tesseraud, S, Requena Rodon, FE, Skiba-Cassy, S, Crochet, S, Duclos, MJ, Rideau, N, Tona, K, Buyse, J, Bruggeman, V, Decuypere, E, Picard, M, Yahav, S 2007. Effects of thermal manipulation during early and late embryogenesis on thermotolerance and breast muscle characteristics in broiler chickens. Poultry Science 86, 795800.Google Scholar
Debut, M, Berri, C, Baeza, E, Sellier, N, Arnould, C, Guemene, D, Jehl, N, Boutten, B, Jego, Y, Beaumont, C, Le Bihan-Duval, E 2003. Variation of chicken technological meat quality in relation to genotype and preslaughter stress conditions. Poultry Science 82, 18291838.Google Scholar
Fanatico, AC, Cavitt, LC, Pillai, PB, Emmert, JL, Owens, CM 2005. Evaluation of slower-growing broiler genotypes grown with and without outdoor access: meat quality. Poultry Science 84, 17851790.CrossRefGoogle ScholarPubMed
French, NA 2000. Effect of short periods of high incubation temperature on hatchability and incidence of embryo pathology of turkey eggs. British Poultry Science 41, 377382.Google Scholar
Gauly, M, Reiner, G, Groschl, M, Dzapo, V 2001. The effects of incubation conditions on the embryonic respiratory and mitochondrial energy metabolism, the thyroid hormone status, and the daily gain in turkeys. Archiv für Gefluegelkunde 65, 97105.Google Scholar
Halevy, O, Piestun, Y, Rozenboim, I, Yablonka-Reuveni, Z 2006. In ovo exposure to monochromatic green light promotes skeletal muscle cell proliferation and affects myofiber growth in posthatch chicks. American Journal of Physiology. Regulatory Integrative and Comparative Physiology 290, R1062R1070.Google Scholar
Hammond, CL, Simbi, BH, Stickland, NC 2007. In ovo temperature manipulation influences embryonic motility and growth of limb tissues in the chick (Gallus gallus). Journal of Experimental Biology 210, 26672675.CrossRefGoogle ScholarPubMed
Heywood, JL, McEntee, GM, Stickland, NC 2005. In ovo neuromuscular stimulation alters the skeletal muscle phenotype of the chick. Journal of Muscle Research and Cell Motility 26, 4956.Google Scholar
Kocamis, H, Kirkpatrick-Keller, DC, Klandorf, H, Killefer, J 1998. In ovo administration of recombinant human insulin-like growth factor-I alters postnatal growth and development of the broiler chicken. Poultry Science 77, 19131919.Google Scholar
Leeson, S, Walsh, T 2004. Feathering in commercial poultry – II. Factors influencing feather growth and feather loss. World’s Poultry Science Journal 60, 5263.CrossRefGoogle Scholar
Leon-Velarde, F, Monge, C 2004. Avian embryos in hypoxic environments. Respiratory Physiology and Neurobiology 141, 331343.Google Scholar
Lourens, A, van den Brand, H, Meijerhof, R, Kemp, B 2005. Effect of eggshell temperature during incubation on embryo development, hatchability, and posthatch development. Poultry Science 84, 914920.CrossRefGoogle ScholarPubMed
Maltby, V, Somaiya, A, French, NA, Stickland, NC 2004. In ovo temperature manipulation influences post-hatch muscle growth in the turkey. British Poultry Science 45, 491498.CrossRefGoogle ScholarPubMed
McEntee, GM, Simbi, BH, Bayol, SA, Macharia, RG, Stickland, NC 2006. Neuromuscular stimulation causes muscle phenotype-dependent changes in the expression of the IGFs and their binding proteins in developing slow and fast muscle of chick embryos. Developmental Dynamics 235, 17771784.Google Scholar
Mehaffey, JM, Pradhan, SP, Meullenet, JF, Emmert, JL, Mckee, SR, Owens, CM 2006. Meat quality evaluation of minimally aged broiler breast fillets from five commercial genetic strains. Poultry Science 85, 902908.Google Scholar
Miller, JB, Stockdale, FE 1986. Developmental Regulation of the Multiple Myogenic Cell Lineages of the Avian Embryo. Journal of Cell Biology 103, 21972208.Google Scholar
Mortola, JP, Labbe, K 2005. Oxygen consumption of the chicken embryo: interaction between temperature and oxygenation. Respiratory Physiology and Neurobiology 146, 97106.Google Scholar
Petracci, M, Fletcher, DL 2002. Broiler skin and meat color changes during storage. Poultry Science 81, 15891597.Google Scholar
Piestun, Y, Harel, M, Barak, M, Yahav, S, Halevy, O 2009. Thermal manipulations in late-term chick embryos have immediate and longer term effects on myoblast proliferation and skeletal muscle hypertrophy. Journal of Applied Physiology 106, 233240.Google Scholar
Pitsillides, AA 2006. Early effects of embryonic movement: ‘a shot out of the dark’. Journal of Anatomy 208, 417431.Google Scholar
Romanoff, AL 1951. Resistance of avian embryo to varying periods of temperature elevation. Anatomical Record 111, 549549.Google Scholar
Rozenboim, I, Huisinga, R, Halevy, O, El Halawani, ME 2003. Effect of embryonic photostimulation on the posthatch growth of turkey poults. Poultry Science 82, 11811187.Google Scholar
Sandercock, DA, Hunter, RR, Nute, GR, Mitchell, MA, Hocking, PM 2001. Acute heat stress-induced alterations in blood acid-base status and skeletal muscle membrane integrity in broiler chickens at two ages: implications for meat quality. Poultry Science 80, 418425.Google Scholar
Santiago, HL, Denbow, DM, Emmerson, DA, Denbow, C, Graham, P, Hohenboken, W 2005. Effects of strain, plane of nutrition, and age at slaughter on performance and meat quality traits of broilers. Poultry Science 84 (suppl. 1), 128.Google Scholar
Scaal, M, Christ, B 2004. Formation and differentiation of the avian dermomyotome. Anatomy and Embryology 208, 411424.Google Scholar
Scheuermann, GN, Bilgili, SF, Tuzun, S, Mulvaney, DR 2004. Comparison of chicken genotypes: myofiber number in pectoralis muscle and myostatin ontogeny. Poultry Science 83, 14041412.Google Scholar
Tonhardt, H, Brauch, N, von Plettenberg, D 2004. Influence of incubation temperature on the noradrenaline concentration in blood plasma and cAMP content in heart muscles cells of chicken embryo. Avian and Poultry Biology Reviews 15, 235235.CrossRefGoogle Scholar
Uni, Z, Ferket, PR, Tako, E, Kedar, O 2005. In ovo feeding improves energy status of late-term chicken embryos. Poultry Science 84, 764770.Google Scholar
Von Blumroder, D, Tonhardt, H 2002. Influence of long-term changes in incubation temperature on catecholamine levels in plasma of chicken embryos (Gallus gallus f. domestica). Comparative Biochemistry and Physiology.Part A: Molecular and Integrative Physiology 131, 701711.Google Scholar
Werner, C, Janisch, S, Kuembet, U, Wicke, M 2009. Comparative study of the quality of broiler and turkey meat. British Poultry Science 50, 318324.Google Scholar
Yahav, S, Collin, A, Shinder, D, Picard, M 2004a. Thermal manipulations during broiler chick embryogenesis: effects of timing and temperature. Poultry Science 83, 19591963.CrossRefGoogle ScholarPubMed
Yahav, S, Sasson Rath, R, Shinder, D 2004b. The effect of thermal manipulations during embryogenesis of broiler chicks (Gallus domesticus) on hatchability, body weight and thermoregulation after hatch. Journal of Thermal Biology 29, 245250.Google Scholar
Young, JF, Karlsson, AH, Henckel, P 2004. Water-holding capacity in chicken breast muscle is enhanced by pyruvate and reduced by creatine supplements. Poultry Science 83, 400405.Google Scholar