Authors: A. J. Sanda, O. Olowofeso, M. A. Adeleke, A. O Oso, S. O. Durosaro, M. O. Sanda

Abstract:

A total of 150 meat type chickens comprising 50 each of Arbor Acre, Marshall and Ross were used for this study which lasted for 10 weeks at the Federal University of Agriculture, Abeokuta, Nigeria. Growth performance data were collected from the third week through week 10 and data obtained were analysed using the Generalized Linear Model Procedure. Heritability estimates (h2) for body dimensions carried out on the chicken strains ranged from low to high. Marshall broiler chicken strain had the highest h2 for body weight 0.46±0.04, followed by Arbor Acre and Ross with h2 being 0.38±0.12 and 0.26±0.06, respectively. The repeatability estimates for body weight in the three broiler strains were high, and it ranged from 0.70 at week 4 to 0.88 at week 10. Relationships between the body weight and linear body measurements in the broiler chicken strains were positive and highly significant (p > 0.05).

Keywords: Broiler chicken strains, heritability, repeatability, traits.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1096531

Procedia APA BibTeX Chicago EndNote Harvard JSON MLA RIS XML ISO 690 PDF Downloads 2927

References:

[1] Adebambo, A.O., Faybenvo, O.I., Fragite, S.O., Ikeobi C.O.N. and Adebambo, O.A. (2005). Preliminary assessment of growth and reproductive data of three strain of chickens for broiler development in Nigeria. Proceedings of 1st Nigeria International Poultry Summit, Ota, Ogun State, Nigeria. Pp: 9-11.
[2] Adeleke, M.A., Ozoje, M.O., Olufunmilayo A. Adebambo, Peters, S.O. and Bamgbose, A.M. (2004). Estimation of body weight from linear body measurements among crossbred egg-type chickens. Proceedings of the 29th Annual Conference of the Genetics Society of Nigeria, University of Agriculture, Abeokuta, Ogun State, Nigeria, Pp 88-91.
[3] Ajayi, F.O., Ejiofor, O. and Ironkwe, M. O. (2008). Estimation of bodyweight from body measurements in two commercial meat type chickens. Global Journal of Agricultural Science. 7(1): 57-59.
[4] Akanno, E.C., Ole, P.K., Okoli, I.C. and Ogundu, U.E. (2007). Performance characteristics and prediction of body weight of broiler strains using linear body measurements. Proceedings of the 22nd Annual Conference of Nigerian Society for Animal Production, Calabar, Cross River State, Nigeria, Pp: 162-164.
[5] Amao, S.R., Ojedapo, L.O., Oyewumi, S.O. and Ameen, S.A. (2011). Estimation of body weight from linear body measurements in Wadi Ross meat type chicken in derived savannah zone of Nigeria. Proceedings of the 16th Annual Conference of the Animal Science Association of Nigeria, Anyigba, Nigeria. Pp 9-12.
[6] Argenta˜o, C., Michelan Filho, T., Marques, J.B., Souza, E.M., Eler, J.P. and Ferraz, J.B.S. (2002). Genetic and phenotypic parameters of growth and carcass traits of a male line of broilers raised in tropical conditions. In Proceedings of 7th Congress of Genetics Applied to Livestock Production, Montpellier, France. Pp: 333-336.
[7] Banerjee, S. (2011). Estimation of body weight at different ages using linear and some non-linear regression equations in a duck breed reared in hot and humid climate of Eastern India. American-Eurasian Journal of Scientific Research. 6 (4): 201-204.
[8] Cahaner, A. and Nitsan, Z. (1985). Evaluation of simultaneous selection for live body weight and against abdominal fat in broilers. Poultry Science. 64: 1257-1263.
[9] Havenstein, G.B., Ferket, P.R. and Qureshi, M.A. (2003). Growth, livability and feed conversion of 1957 versus 2001 broiler when fed representative and 2001 broiler diets. Poultry Science. 82: 1500-1508.
[10] Kabir, M.T., Yakudu, H., Akpa, G.N., Jokthan, G.E., Abdul, S.B., Abdulrashid, M. and Adamu, Y.H. (2008). Repeatability for body weight and body conformation traits in Anak 2000 strains of Broiler chickens. Journal of Animal Breeding and Genetics. 112: 17-21.
[11] Ledur, M.C., Schmidt, G.S. Figueiredo, E.P. A´vila, V.S. and Fiorentin, L. (1994). Paraˆmetros gene´ticos e fenotı´picos em linhagens de aves selecionadas para corte. Pesq. Agropec. Bras. 29: 503-508.
[12] Le Bihan-Duval, E., Mignon-Grasteau, S., Millet, N. and Beaumont, C. (1998). Genetic analysis of a selection experiment on increased body weight and breast muscle weight as well as on limited abdominal fat weight. British Poultry Science. 39: 346-353.
[13] Mignon-Grasteau, S., Beaumont, C., Le Bihan-Duval, E., Poivey, J.P., de Rochambeau, H. and Ricard, F.H. (1999). Genetic parameters of growth curve parameters in male and female chickens. British Poultry Science. 40: 44-51.
[14] Nesamvuni, A.E., Malandzii, J., Zamanyimi, N.D. and Taylor, G.J. (2000). Estimates of body weight in Nguru type cattle under commercial management conditions. South African Journal of Animal Science. 13: 114-116.
[15] Olowofeso, O. (2009). Phenotypic correlations and prediction of body weight and body size parameters in broiler chickens. Journal of Applied Agricultural Research. I: 71-76.
[16] Oluyemi, J.A. and Roberts, S.A. (1979). Poultry Production in Warm Wet Climates. 2nd Edition, Macmillan Press Ltd., London.
[17] Pundir, R.K., Singh, P.K. and Dangi, P.S. (2011). Factor analysis of biometric traits of kankrej cows to explain body conformation. Asian- Australian Journal of Animal Science. 24 (4): 449-456.
[18] Rance, K.A., McEntee, G.M. and McDevitt, R.M. (2002). Genetic and phenotypic relationships between and within support and demand tissues in a single line of broiler chicken. British Poultry Science. 43: 518–527.
[19] Yalcin, S., Settar, P., Ozkan S. and Cahaner, A. (1997). Comparative evaluation of three commercial broiler stocks in hot versus temperate climates. Poultry Science. 76: 921-929.