- Archer, J. S. (1965). Consistent matrix formulations for structural analysis using finite-element techniques. AIAA journal, 3(10): 1910-1918.
- Asatoor, A. M., and King, E. J. (1954). Simplified colorimetric blood sugar method. The Biochemical Journal, 56.
- Attia, Y. A., Hassan, R. A., Tag El‐Din, A. E., and Abou‐Shehema, B. M. (2011). Effect of ascorbic acid or increasing metabolizable energy level with or without supplementation of some essential amino acids on productive and physiological traits of slow‐growing chicks exposed to chronic heat stress. Journal of Animal Physiology and Animal Nutrition, 95(6): 744-755.
- Burton, R., and Guion, C. W. (1968). The differential leucocyte blood count: its precision and individuality in the chicken. Poultry science, 47(6): 1945-1949.
- Crespo, N., and Esteve-Garcia, E. (2003). Polyunsaturated fatty acids reduce insulin and very low density lipoprotein levels in broiler chickens. Poultry Science, 82(7): 1134-1139.
- Crespo, N., and Esteve-Garcia, E. (2002). Dietary polyunsaturated fatty acids decrease fat deposition in separable fat depots but not in the remainder carcass. Poultry science, 81(4): 512-518.
- Dairo, F. A. S., Adesehinwa, A. O. K., Oluwasola, T. A., and Oluyemi, J. A. (2010). High and low dietary energy and protein levels for broiler chickens. African Journal of Agricultural Research, 5(15): 2030-2038.
- Di Giorgio, J., Henry, R., and Winkelman, J. (1974). Clinical Chemistry: Principles and Techniques. 2nd. ed, RJ Henry, D. C. Cannon and J. W. Winkelman, Ed., Harper and Row Publications, Inc, Hagerstown, Md.
- Duncan, D. B. (1955). Multiple range and multiple F tests. biometrics, 11(1): 1-42.
- El-Senousey, H. K., Wang, W., Wang, Y., Fan, Q., Fouad, A. M., Lin, X., ... and Jiang, S. (2019). Dietary metabolizable energy responses in yellow-feathered broiler chickens from 29 to 56 d. Journal of Applied Poultry Research, 28(4): 974-981.
- Fan, H. P., Xie, M., Wang, W. W., Hou, S. S., and Huang, W. (2008). Effects of dietary energy on growth performance and carcass quality of white growing Pekin ducks from two to six weeks of age. Poultry science, 87(6): 1162-1164.
- Fouad, A. M., and El-Senousey, H. K. (2014). Nutritional factors affecting abdominal fat deposition in poultry: a review. Asian-Australasian journal of animal sciences, 27(7): 1057.
- Friedewald, W. T., Levy, R. I., and Fredrickson, D. S. (1972). Estimation of the concentration of low-density lipoprotein cholesterol in plasma, without use of the preparative ultracentrifuge. Clinical chemistry, 18(6): 499-502.
- Ge, X. K., Wang, A. A., Ying, Z. X., Zhang, L. G., Su, W. P., Cheng, K., ... and Wang, T. (2019). Effects of diets with different energy and bile acids levels on growth performance and lipid metabolism in broilers. Poultry science, 98(2): 887-895.
- Grundy, S. M., Brewer Jr, H. B., Cleeman, J. I., Smith Jr, S. C., and Lenfant, C. (2004). Definition of metabolic syndrome: report of the National Heart, Lung, and Blood Institute/American Heart Association conference on scientific issues related to definition. Circulation, 109(3): 433-438.
- Hocking, P. M., Maxwell, M. H., and Mitchell, M. A. (1993). Welfare assessment of broiler breeder and layer females subjected to food restriction and limited access to water during rearing. British Poultry Science, 34(3): 443-458.
- Hocking, P. M., Maxwell, M. H., and Mitchell, M. A. (1996). Relationships between the degree of food restriction and welfare indices in broiler breeder females. British Poultry Science, 37(2): 263-278.
- Hussein, M. A., and Naji, S. A. (2014). Effect of Ionized Water (Alkaline and Acidic) On Productive Performance of Broiler. Iraqi poultry sciences journal, 8(1): 54-62.
- Hu, X., Li, X., Xiao, C., Kong, L., Zhu, Q., and Song, Z. (2021). Effects of dietary energy level on performance, plasma parameters, and central AMPK levels in stressed broilers. Frontiers in Veterinary Science, 8: 681858.
- Khan, T. J., Kuerban, A., Razvi, S. S., Mehanna, M. G., Khan, K. A., Almulaiky, Y. Q., and Faidallah, H. M. (2018). In vivo evaluation of hypolipidemic and antioxidative effect of ‘Ajwa’ (Phoenix dactylifera L.) date seed-extract in high-fat diet-induced hyperlipidemic rat model. Biomedicine and Pharmacotherapy, 107, 675-680.
- Maxwell, M. H., Hocking, P. M., and Robertson, G. W. (1992). Differential leucocyte responses to various degrees of food restriction in broilers, turkeys and ducks. British Poultry Science, 33(1): 177-187.
- Mitruka, B. M., and Rawnsley, H. M. (1977). Clinical biochemical and hematological reference values in normal experimental animals. Masson Publishing USA Inc.
- Natt, M. P., and Herrick, C. A. (1952). A new blood diluent for counting the erythrocytes and leucocytes of the chicken. Poultry Science, 31(4): 735-738.
- Olorede, B. R., Onifade, A. A., Okpara, A. O., and Babatunde, G. M. (1996). Growth, nutrient retention, haematology and serum chemistry of broiler chickens fed sheabutter cake or palm kernel cake in the humid tropics. Journal of Applied Animal Research, 10(2): 173-180.
- Reitman, S., and Frankel, S. (1957). A colorimetric method for the determination of serum glutamic oxalacetic and glutamic pyruvic transaminases. American journal of clinical pathology, 28(1): 56-63.
- Richmond, W. (1973). Preparation and properties of a cholesterol oxidase from Nocardia sp. and its application to the enzymatic assay of total cholesterol in serum. Clinical chemistry, 19(12): 1350-1356.
- SAS, S. (2002). Guide SUs, SAS Institute Inc. Cary. NC, USA.
- Savory, C. J., Carlisle, A., Maxwell, M. H., Mitchell, M. A., and Robertson, G. W. (1993). Stress, arousal and opioid peptide-like immunoreactivity in restricted-and ad lib. -fed broiler breeder fowls. Comparative Biochemistry and Physiology Part A: Physiology, 106(3): 587-594.
- Shawket, T. F., and Salhie, K. C. (2010). Effect of different levels of dietary energy on some production traits for broiler chicken. Basrah Journal of Agricultural Sciences, 23(1): 35-48.
- Shen, P. F., and Patterson, L. T. (1983). A simplified Wright's stain technique for routine avian blood smear staining. Poultry Science, 62(5): 923-924.
- Siri-Tarino, P. W. (2011). Effects of diet on high-density lipoprotein cholesterol. Current atherosclerosis reports, 13: 453-460.
- Swennen, Q. G. P. J., Janssens, G. P. J., Decuypere, E., and Buyse, J. (2004). Effects of substitution between fat and protein on feed intake and its regulatory mechanisms in broiler chickens: energy and protein metabolism and diet-induced thermogenesis. Poultry Science, 83(12): 1997-2004.
- Toro, G., and Ackermann, P. G. (1975). Practical clinical chemistry. Little Brown and Company.
- Varley, H., A. H. Gowenlok, and M. Ben. (1980). Practical Biochemistry. 6th ed. William Heinemann Medical Books Ltd., London.
- Wang, J. P., Zhang, Z. F., Yan, L., and Kim, I. H. (2016). Effects of dietary supplementation of emulsifier and carbohydrase on the growth performance, serum cholesterol and breast meat fatty acids profile of broiler chickens. Animal Science Journal, 87(2): 250-256.
- Warnick, G. R., and Wood, P. D. (1995). National cholesterol education program recommendations for measurement of high-density lipoprotein cholesterol: Executive summary. The national cholesterol education program working group on lipoprotein measurement. Clinical chemistry, 41(10): 1427-1433.
- Xie, M., Zhao, J. N., Hou, S. S., and Huang, W. (2010). The apparent metabolizable energy requirement of White Pekin ducklings from hatch to 3 weeks of age. Animal feed science and technology, 157(1-2): 95-98.
- Zangana, B. S. R., and Jasim, M. M. (2014). Effect of early feeding with probiotics on body dimensions of broiler carcass. Iraqi Journal of Agricultural Sciences, 45(4): 409-417.
- Zeng, Q. F., Cherry, P., Doster, A., Murdoch, R., Adeola, O., and Applegate, T. J. (2015). Effect of dietary energy and protein content on growth and carcass traits of Pekin ducks. Poultry science, 94(3): 384-394.
- Zhao, J. P., Chen, J. L., Zhao, G. P., Zheng, M. Q., Jiang, R. R., and Wen, J. (2009). Live performance, carcass composition, and blood metabolite responses to dietary nutrient density in two distinct broiler breeds of male chickens. Poultry Science, 88(12): 2575-2584.
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