Effects of stocking density on the performance, tibia mineralization, and the expression of hypothalamic appetite genes in broiler chickens

Abudabos, A., Samara E.M., Hussien E.O.S., Al-Ghadi M.Q., Al-Atiyat R.M. (2013) Impacts of stocking density on the performance and welfare of broiler chickens. Ital. J. Anim. Sci., 12: 66–71. Search in Google Scholar

AOAC (Association of Official Analytical Chemists). (2000). Official Methods of Analysis, 17th ed. Gaithersburg, MD, USA: AOAC International. Search in Google Scholar

Averós X., Estevez I. (2018) Meta-analysis of the effects of intensive rearing environments on the performance and welfare of broiler chickens. Poult. Sci., 97: 3767−3785.10.3382/ps/pey243616235829924356 Search in Google Scholar

Bai S. P., Huang L., Luo Y., Wang L., Ding X., Wang J., Zhang K. (2014). Dietary manganese supplementation influences the expression of transporters involved in iron metabolism in chickens. Biol. Trace Elem. Res., 160: 352–360. Search in Google Scholar

Baitshotlhi J. C., Moreki J. C., Tsopito C. M., Nsoso S. J. (2014). Influence of stocking density on bone development in family chickens reared up to 18 weeks of age under intensive system. Int. J. Poult. Sci., 13: 652–656. Search in Google Scholar

Beg M. A. H., Baqui M. A., Sarker N. R., Hossain M. M. (2011) Effect of stocking density and feeding regime on performance of broiler chicken in summer season. Int. J. Poult. Sci., 10: 365–375. Search in Google Scholar

Beloor J., Kang H. K., Kim Y. J., Subramani V. K., Jang I. S., Sohn S. H., Moon Y. S. (2010) The effect of stocking density on stress related genes and telomeric broiler chickens. Asian Aust. J. Anim. Sci., 23: 437–443. Search in Google Scholar

Benyi K., Acheampong-Boateng O., Mahlako K. T. (2012). Responses of male broiler chickens from two genetic groups to different stocking densities in a semi-arid subtropical environment. Trop. Anim. Health Prod., 44: 185–190. Search in Google Scholar

Benyi K., Netshipale A. J., Mahlako K. T., Gwata E. T. (2015). Effect of genotype and stocking density on broiler performance during two subtropical seasons. Trop. Anim. Health Prod., 47: 969–974. Search in Google Scholar

Blake J. P., Hess, J. B. (2014). Poultry litter ash as a replacement for dicalcium phosphate in broiler diets. J. Appl. Poult. Res., 23: 101–107. Search in Google Scholar

Boswell T., Dunn I. C. (2015). Regulation of the avian central melanocortin system and the role of leptin. Gen. Comp. Endocrinol., 221: 278–283. Search in Google Scholar

Buijs S., Keeling L., Rettenbacher S., Van Poucke E., Tuyttens F. A. M. (2009). Stocking density effects on broiler welfare: identifying sensitive ranges for different indicators. Poult. Sci., 88: 1536–1543. Search in Google Scholar

Buijs S., Van Poucke E., Van Dongen S., Lens L., Baert J., Tuyttens F. A. M. (2012). The influence of stocking density on broiler chicken bone quality and fluctuating asymmetry. Poult. Sci., 91: 1759–1767. Search in Google Scholar

Cengiz Ö., Köksal B. H., Tatli O., Kuter E., Ahsan U., Güven G., Sevim Ö., Bilgili S. F., Önol A. G. (2018) Supplemental boric acid does not prevent the development of footpad dermatitis in broilers subjected to high stocking density. Poult. Sci., 97: 4342–4350. Search in Google Scholar

Dawkins M. S., Donnelly C. A., Jones T. A. (2004). Chicken welfare is influenced more by housing conditions than by stocking density. Nature, 427: 342–344. Search in Google Scholar

Dedic N., Chen A., Deussing, J. M. (2018). The CRF family of neuropeptides and their receptors - mediators of the central stress response. Curr. Mol. Pharmacol., 11: 4–31. Search in Google Scholar

Dozier W. A., Thaxton J. P., Branton S. L., Morgan G. W., Miles D. M., Roush W. B., Lott B. D., Vizzier-Thaxton Y. (2005). Stocking density effects on growth performance and processing yields of heavy broilers. Poult. Sci., 84: 1332–1338. Search in Google Scholar

European Commission. (2007). Council directive 2007/43/EC of 28 June 2007 laying down minimum rules for the protection of chickens kept for meat production. Official Journal of the European Union, 12 July 2007: L 182/119-128. Search in Google Scholar

Everaert N., Decuypere E., Buyse J. (2019) Feed intake and regulation. In: Poultry and Pig Nutrition Challenges of the 21^st Century, Hendriks W. H., Verstegen M. W. A., Babinszky, L. (eds). Wageningen Academic Publishers, Wageningen, The Netherlands, pp 59–75.10.3920/978-90-8686-884-1_3 Search in Google Scholar

Feddes J., Emmanuel E., Zuidhoft M. (2002). Broiler performance, body weight variance, feed and water intake, and carcass quality at different stocking densities. Poult. Sci., 81: 774–779. Search in Google Scholar

Harrold J. A., Dovey T. M., Blundell J. E., Halford J. C. G. (2012). CNS regulation of appetite. Neuropharmacology, 63, 3–17.10.1016/j.neuropharm.2012.01.00722313528 Search in Google Scholar

He X., Lu Z., Ma B., Zhang L., Li J., Jiang Y., Zhou G., Gao F. (2019) Chronic heat stress alters hypothalamus integrity, the serum indexes and attenuates expressions of hypothalamic appetite genes in broilers. J. Therm. Biol., 81: 110–117. Search in Google Scholar

Lei Q. B., Shi L. X., Zhang K. Y., Ding X. M., Bai S. P., Liu Y. G. (2011). Effect of reduced energy, protein and entire substitution of inorganic phosphorus by phytase on performance and bone mineralisation of laying hens. Bri. Poult. Sci., 52: 202–213. Search in Google Scholar

Li J., Miao Z., Tian W., Yang Y., Wang J., Yang Y. (2017) Effects of different rearing systems on growth, small intestinal morphology and selected indices of fermentation status in broilers. Anim. Sci. J., 88: 900–908. Search in Google Scholar

Li Q., Zhao X. L., Gilbert E. R., Liu Y. P., Wang Y., Qiu M. H., Zhu Q. (2015) Confined housing system increased abdominal and subcutaneous fat deposition and gene expression of carbohydrate response element-binding protein and sterol regulatory element-binding protein 1 in chicken. Genet. Mol. Res., 14: 1220−1228. Search in Google Scholar

Li X. M., Zhang M. H., Liu S. M., Feng J. H., Ma D. D., Liu Q. X., Zhou Y., Wang X. J., Xing S. (2019) Effects of stocking density on growth performance, growth regulatory factors, and endocrine hormones in broilers under appropriate environments. Poult. Sci., 98: 6611– 6617. Search in Google Scholar

Livak K. J., Schmittgen T. D. (2001). Analysis of relative gene expression data using real-time quantitative PCR and the 2 ^{(-Delta Delta C(T))} method. Methods, 25: 402–408. Search in Google Scholar

Madilindi M. A., Mokobane A., Letwaba P. B., Tshilate T. S., Banga C. B., Rambau M. D., Bhebhe E., Benyi K. (2018) Effects of sex and stocking density on the performance of broiler chickens in a sub-tropical environment. S. Afr. J. Anim. Sci., 48: 459–468. Search in Google Scholar

Magnuson A. D., Liu G., Sun T., Tolba S. A., Xi L., Whelan R., Lei X. G. (2020) Supplemental methionine and stocking density affect antioxidant status, fatty acid profiles, and growth performance of broiler chickens. J. Anim. Sci., 98: skaa092.10.1093/jas/skaa092718335132207523 Search in Google Scholar

Maniam J., Morris M. J. (2012). The link between stress and feeding behaviour. Neuropharmacology, 63, 97–110.10.1016/j.neuropharm.2012.04.01722710442 Search in Google Scholar

McKeith A., Loper M., Tarrant K. J. (2020) Research note: stocking density effects on production qualities of broilers raised without the use of antibiotics. Poult. Sci., 99: 698– 701.10.1016/j.psj.2019.09.004758773332029155 Search in Google Scholar

Mellouk N., Ramé C., Barbe A., Grandhaye J., Froment P., Dupont J. (2018) Chicken is a useful model to investigate the role of adipokines in metabolic and reproductive diseases. Int. J. Endocrinol., 2018: 4579734. Search in Google Scholar

Meluzzi A., Fabbri C., Folegatti E., Sirri F. (2008). Effect of less intensive rearing conditions on litter characteristics, growth performance, carcase injuries and meat quality of broilers. Br. Poult. Sci., 49: 509–515. Search in Google Scholar

Mench J. A. (2018). Advances in Poultry Welfare. Cambridge, MA, USA, Woodhead Publishing. Search in Google Scholar

Ministry of Agricultural of the People’s Republic of China. (2004). Feeding standard of chicken. Beijing, China, China Agricultural Press. Search in Google Scholar

Moore P. A., Daniel T. C., Edwards D. R., Miller D. M. (1996). Evaluation of chemical amendments to reduce ammonia volatilization from poultry litter. Poult. Sci., 75: 315–320. Search in Google Scholar

Rambau, M.D., Mudau M.L., Makhanya S.D.,Benyi K. (2016) Effects of stocking density and daily feed withdrawal periods on the performance of broiler chickens in a semi-arid environment. Trop. Anim. Health Prod., 48: 1547–1554. Search in Google Scholar

Rashidi N., Ghorbani M. R., Tatar A., Salari S. (2019) Response of broiler chickens reared at high density to dietary supplementation with licorice extract and probiotic. J. Anim. Physiol. Anim. Nutr (Berl)., 103: 100−107.10.1111/jpn.1300730315590 Search in Google Scholar

Resnyk C. W., Carré W., Wang X., Porter T. E., Simon J., Le Bihan-Duval E., Duclos M. J., Aggrey S. E., Cogburn L. A. (2015) Transcriptional analysis of abdominal fat in genetically fat and lean chickens reveals adipokines, lipogenic genes and a link between hemostasis and leanness. BMC Genomics., 14: 557. Search in Google Scholar

Sanchez-Casanova R., Sarmiento-Franco L., Segura-Correa J., Phillips C. J. C. (2019) Effects of outdoor access and indoor stocking density on behaviour and stress in broilers in the subhumid tropics. Animals, 9, E1016.10.3390/ani9121016694085531766675 Search in Google Scholar

SAS Institute Inc. (2009) SAS/STAT® 9.2 User’s Guide, Second Edition. Cary, NC, USA: SAS Institute Inc. Search in Google Scholar

Shakeri, M., Zulkifli I., Soleimani A. F., O’Reilly E. L., Eckersall P. D., Anna A. A., Kumari S., Abdullah F. F. (2014) Response to dietary supplementation of L-glutamine and L-glutamate in broiler chickens reared at different stocking densities under hot, humid tropical conditions. Poult. Sci., 93: 2700–2708.10.3382/ps.2014-0391025143595 Search in Google Scholar

Shipp S. L., Yi J., Dridi S., Gilbert E. R., Cline M. A. (2015). The central anorexigenic mechanism of adrenocorticotropic hormone involves the caudal hypothalamus in chicks. Neuropeptides, 53: 29–35. Search in Google Scholar

Siaga R., Baloyi J. J., Rambau M. D., Benyi K. (2017) Effects of stocking density and genotype on the growth performance of male and female broiler chickens. Asian J. Poult. Sci., 11: 96–104. Search in Google Scholar

Simsek U. G., Ciftci M., Cerci I. H., Bayraktar M., Dalkilic B, Arslan O., Balci T. A. (2011) Impact of stocking density and feeding regimen on broilers: performance, carcass traits and bone mineralization. J. Appl. Anim. Res., 39: 230–233. Search in Google Scholar

Stengel A., Taché Y. (2014). CRF and urocortin peptides as modulators of energy balance and feeding behavior during stress. Front. Neurosci., 8: 52. Search in Google Scholar

Sun Z. W., Fan Q. H., Wang X. X., Guo Y. M., Wang H. J., Dong X. (2018). High stocking density alters bone-related calcium and phosphorus metabolism by changing intestinal absorption in broiler chickens. Poult. Sci., 97: 219–226. Search in Google Scholar

Swain B. K., Sundaram R. N. S., Barbudhe S. B., Nirmale A. V. (2002). Influence of cage and deep litter rearing systems on the performance of broilers. Indian Vet. J., 79: 467–470. Search in Google Scholar

Tablante N. L., Estevez I., Russek-Cohen E. (2003). Effect of perches and stocking density on tibial dyschondroplasia and bone mineralization as measured by bone ash in broiler chickens. J. Appl. Poult. Res., 12: 53–59. Search in Google Scholar

Tahamtani F. M., Pedersen I. J., Riber A. B. (2020) Effects of environmental complexity on welfare indicators of fast-growing broiler chickens. Poult. Sci., 99: 21−29.10.3382/ps/pez510758762332416804 Search in Google Scholar

Tong H. B., Lu J., Zou J. M., Wang Q., Shi S. R. (2012) Effects of stocking density on growth performance, carcass yield, and immune status of a local chicken breed. Poult. Sci., 91: 667–673. Search in Google Scholar

Vargas-Galicia A. J., Sosa-Montes E., Rodríguez-Ortega L. T. (2017). Effect of litter material and stocking density on bone and tendon strength, and productive performance in broilers. Can. J. Anim. Sci., 97: 673–682. Search in Google Scholar

Verspecht A., Vanhonacker F., Verbeke W., Zoons J., Van Huylenbroeck G. (2011) Economic impact of decreasing stocking densities in broiler production in Belgium. Poult. Sci., 90: 1844−1851.10.3382/ps.2010-0127721753224 Search in Google Scholar

Wang B., Min Z., Yuan J., Zhang B., Guo Y. (2014). Effects of dietary tryptophan and stocking density on the performance, meat quality, and metabolic status of broilers. J. Anim. Sci. Biotech., 5: 44. Search in Google Scholar

Wang J., Yi J., Siegel P. B., Cline M. A., Gilbert E. R. (2017). Stress-induced suppression of neuropeptide y-induced hunger in anorexic chicks involves corticotropin-releasing factor signaling and the paraventricular nucleus of the hypothalamus. J. Neuroendocrinol., 29: e12555. Search in Google Scholar

Yi C., Tschöp M. H. (2012) Brain-gut-adipose-tissue communication pathways at a glance. Dis. Model Mech., 5: 583−587. Search in Google Scholar

Yi J. (2016) Hypothalamic regulation of food intake in obsess and anorexic avian models. Dissertation, Virginia Polytechnic Institute and State University, VA, USA. Search in Google Scholar

Zhang W., Cline M. A., Gilbert E. R. (2014) Hypothalamus-adipose tissue crosstalk: neuropeptide Y and the regulation of energy metabolism. Nutr. Metab. (Lond)., 11: 27. Search in Google Scholar