. Efficiency of food egg production used for keeping layers of monochrome light with different wavelengths
DOI:
https://doi.org/10.31548/dopovidi2021.06.011Keywords:
laying hens, egg-laying, egg mass, preservation, live weight, light wavelength, light colorAbstract
Artificial light, as an environmental factor, is crucial for the release of hormones that play a key role in a bird's life, growth, immunity and reproduction. For laying hens, light plays an important role in the development and functioning of the reproductive system, significantly affecting the age of laying the first egg, egg-laying and productivity in general.
The source of artificial light of the latest generation in poultry farming is LED lamps. Compared to incandescent and fluorescent lamps, LEDs have a longer service life, specific spectrum, lower heat output, higher energy efficiency and reliability, as well as lower maintenance costs, so they are increasingly used by manufacturers.
LEDs are a special type of semiconductor diode that can give monochrome light. However, information on the effect of monochrome light with different wavelengths of light on the physiological state of the hens’ body is quite contradictory. Therefore, the aim of the work was to study the efficiency of egg production using monochrome light with different wavelengths.
For this purpose, in the conditions of a modern complex for production of food eggs in a poultry house with an area of 2915 m2, 4 groups of hens of the industrial herd "Hy-Line W-36" were formed, each of which was kept in a separate poultry house similar in area and cage equipment. Each poultry house was equipped with cage batteries "Big Dutchman" (Germany), consisting of 1176 cages with an area of 40544 cm2 (362 × 112 cm). The differences between the poultry houses applied only to LED lamps. Thus, hens of the 1st group were kept using LED lamps with a peak light wavelength of 458 nm (blue color of the spectrum), the 2nd group – 603 nm (yellow color of the spectrum), the 3rd group – 632 nm (orange color of the spectrum) and the 4th group – 653 nm (red color of the spectrum).
Every day, for 44 weeks of the productive period, the number of eggs laid by the laying hens of each group and the intensity of their laying were determined. The number of hatched hens (due to death and culling) was also counted daily and the number of livestock was determined. Once a week, the weight of eggs and live weight of laying hens were measured from certain labeled cages according to a sample. The European egg production rate on the basis of productivity was determined.
It was found that for the maintenance of laying hens of modern white-egg crosses in 12-tier cage batteries of classical designs, it is advisable to use lighting with a peak wavelength of 653 nm, that is with red light. This makes it possible for the 44-week egg-laying period to receive an additional 4.8–18.8 million eggs from each poultry house (0.4–1.6 thousand eggs per 1 m2 of its area) at the highest level of the European egg production rate at 1.0–3.8 units
The decrease in the peak wavelength from 653 to 632 nm, which was manifested by a change in light from red to orange, was accompanied by a decrease in the preservation of livestock by 0.7% (3.8% ˂ normal), body weight – by 0.6% within physiological norms, egg-laying per initial laying hen – by 2.9% (5.3% ˂ norm), which caused a decrease in the gross yield of eggs by 4.5 million eggs and egg mass – by 3273 tons from each poultry house, including 1.6 thousand eggs and 112.3 kg per 1 m2 of its area, with a decrease in the level of European egg production rate by 1.0 units.
The decrease in the peak wavelength to 603 nm, that is the change in the color of light from red and orange to yellow, was accompanied by a decrease in the preservation of livestock by 6.0–6.7% (9.8% ˂ normal), body weight – by 1.0 –1.7% within the physiological norm, egg-laying per initial laying hen – by 6.6–10.3% (11.6% ˂ of the norm) and feed consumption – by 0.6–0.7% (7.5%) > norms), which led to a decrease in gross egg yield by 7.8–12.6 million eggs and egg mass – by 505.7–833.0 tons from each poultry house, including 2.7–4.3 thousand eggs and 173.5–285.8 kg per 1 m2 of its area, with a decrease in the level of the European egg production rate by 1.6–2.6 units.
The decrease in the peak wavelength to 458 nm, that is the change in light color from red, orange and yellow to blue, is accompanied by a decrease in the preservation of livestock by 4.2–10.9% (14.0% ˂ normal), body weight – by 2,3–4.0% (0.2% ˂ of the norm), egg-laying per initial laying hen – by 5.6–15.3% (16.5% ˂ of the norm) and feed costs – by 2.0–2.7 % (5.3%> norms), which led to a decrease in gross egg yield by 6.1–18.8 million eggs and egg mass – by 365.3–1198.3 tons from each poultry house, including 2.1–6.4 thousand eggs and 125.3–288.9 kg per 1 m2 of its area, with a decrease in the level of the European egg production rate by 1.2–3.8 units.
References
Kavtarashvili, A.Sh. (2013). Opredelenie effektivnosti proizvodstva ptitsevodcheskoy produktsii ekspress-metodami [Determining the efficiency of poultry production by express methods]. Economics, 2(123), 6–9. [in Russian].
Borille, R., Garcia, R.G., Nааs, I.A., Caldara, R.F., Santana, M.R. (2015). Monochromatic lightemitting diode (LED) source in layers hens during the second production cycle. Revista Brasileira de Engenharia Agrícola e Ambiental, 19(9), 877–881. doi:10.1590/1807-1929/agriambi.v19n9p877-881
Borille, R., Garcia, R.G., Royer, A.F.B., Santana, M.R., Colet, S., Naas, I.A., Caldara, F.R., Almeida, Paz I.C.L., Rosa, E.S., Castilho, V.A.R. (2013). The use of light-emitting diodes (LED) in commercial layer production. Brazilian Journal of Poultry Science, 15(2), 135–140. doi:10.1590/S1516-635X2013000200009
Er, D., Wang, Z., Cao, J., Chen, Y. (2007). Effect of monochromatic light on the egg quality of laying hens. Journal of Applied Poultry Research, 16(4), 605–612. doi:10.3382/japr.2006-00096
Hassan, M.R., Sultana, S., Choe, H.S., Ryu, K.S. (2013). Effect of monochromatic and combined light colour on performance, blood parameters, ovarian morphology and reproductive hormones in laying hens. Italian Journal of Animal Science, 12(3), 359–364. doi:10.4081/ijas.2013.e56
Huber-Eicher, B., Suter, A., Spring-Stähli, P. (2013). Effects of colored light-emitting diode illumination on behavior and performance of laying hens. Poultry science, 92, 869–873. doi:10.3382/ps.2012-02679
Kim, M.J., Choi, H.C., Suh, O.S. (2010). A study of different sources and wavelengths of light on laying egg characteristics in laying hens. Korean Journal of Poultry Science, 37, 383–388. doi:10.5536/kjps.2010.37.4.383
Lewis, P.D., Caston, L., Leeson, S. (2007). Green light during rearing does not significantly affect the performance of egg-type pullets in the laying phase. Poultry Science, 86, 739–743. doi:10.1093/ps/86.4.739
Li, G., Li, B., Zhao, Y., Shi, Z., Liu, Y., Zheng, W. (2019). Layer pullet preferences for light colors of light-emitting diodes. Animal, 13(6), 1245–1251. doi:10.1017/S1751731118002537
Li, D.Y., Wu, N., Tu, J.B., Hu, Y.D., Yang, M.Y., Yin, H.D., Chen, B.L., Xu, H.L., Yao, Y.F., Zhu, Q. (2015). Expression patterns of melatonin receptors in chicken ovarian follicles affected by monochromatic light. Genetics and Molecular Research, 14 (3), 10072–10080. doi:10.4238/2015.August.21.14
Li, X., Zheng, Z., Pan, J., Jiang, D., Tian, Y., Fang, L., Huang, Y. (2020). Impacts of colored light-emitting diode illumination on the growth performance and fecal microbiota in goose. Poultry science, 99(4), 1805–1812. doi:10.1016/j.psj.2019.12.034
Manser, C. E. (1996). Effects of lighting on the welfare of domesticpoultry: a review. Animal Welfare, 5, 341–360.
Min, J.K., Hossan, M.S., Nazma, A., Jae, C.N., Han, T.B., Hwan, K.K., Dong, W.K., Hyun, S.C., Hee, C.C., Ok, S.S. (2012). Effect of monochromatic light on sexual maturity, production performance and egg quality of laying hens. Avian Biology Research, 5, 69–74. doi:10.3184/175815512X13350270679453
Mudhar, A.S., Tabeekh, A. (2016). The effect of color light and stocking density on some enzymes and hormones of broilers and layers. Mirror of Research in Veterinary Sciences and Animals, 5(1), 25–37. doi:10.5923/j.zoology.20160602.02
Patel, S.J., Patel, A.S., Patel, M.D., Patel, J.H. (2016). Significance of light in poultry production: a review. Advancements in Life Sciences, 5, 1154–1160.
Prayitno, D.S., Phillips, C.J.C., Omed, H. (1997). The effects of color of lighting on the behavior and production of meat chickens. Poultry science, 76, 452–457. doi:10.1093/ps/76.3.452
Prescott, N.B., Wathes, C.M. (1999). Spectral sensitivity of domestic fowl (Gallus g. domesticus). British Poultry Science, 40, 332–339. doi:10.1080/00071669987412
Rozenboim, I., Biran, I., Uni, Z., Robinzon, B., Halevy, O. (1999). The effect of monochromatic light on broiler growth and development. Poultry science, 78, 135–138. doi:10.1093/ps/78.1.135
Rozenboim, I., Zilberman, E., Gvaryahu, G. (1999). New monochromatic light source for laying hens. Poultry Science, 77, 1695–1698. doi:10.1093/ps/77.11.1695
Shi, H., Li, B., Tong, Q., Zheng, W., Zeng, D., Feng, G. (2019). Effects of LED Light Color and Intensity on Feather Pecking and Fear Responses of Layer Breeders in Natural Mating Colony Cages. Animals : an open access journal from MDPI, 9(10), 814. doi:10.3390/ani9100814
Sultana, S., Hassan, M.R., Choe, H.S., Kang, M.I., Ryu, K.S. (2013). Effect of various LED light color on the behavior and stress response of laying hens. Indian Journal of Animal Sciences, 83, 829–833.
Svobodova, J., Tumova, E., Popelarova, E., Chodova, D. (2015). Effect of light colour on egg production and egg contamination. Czech Journal of Animal Science, 60, 550–556. doi:10.17221/8597-CJAS
Yang, Y., Yu, Y., Pan, J., Ying, Y., Zhou, H. (2016). A new method to manipulate broiler chicken growth and metabolism: Response to mixed LED light system. Scientific Reports, 6, 25972. doi:10.1038/srep25972
Yenilmez, L.F., Saber, S.N., Serbester, U., Celik, L. (2021). Effects of monochromatic light on performance, egg quality, yolk cholesterol and blood biochemical profile of laying hens. The Journal of Animal & Plant Sciences, 31(1), 46–52. doi:10.36899/JAPS.2021.1.0191
Zhang, X., Hongqing, X.U., Monan, L.I., Hongmei, X.U., Muqing, L.I.U. (2017). Effects of different monochromatic light of LED on the growth performance of Jinmao broilers and egg laying performance of Jinmao breeders. Journal of Science and Technology in Lighting, 41, 143–147. doi:10.2150/JSTL.IEIJ160000592
Downloads
Additional Files
Published
Issue
Section
License
Relationship between right holders and users shall be governed by the terms of the license Creative Commons Attribution – non-commercial – Distribution On Same Conditions 4.0 international (CC BY-NC-SA 4.0):https://creativecommons.org/licenses/by-nc-sa/4.0/deed.uk
Authors who publish with this journal agree to the following terms:
- Authors retain copyright and grant the journal right of first publication with the work simultaneously licensed under a Creative Commons Attribution License that allows others to share the work with an acknowledgement of the work's authorship and initial publication in this journal.
- Authors are able to enter into separate, additional contractual arrangements for the non-exclusive distribution of the journal's published version of the work (e.g., post it to an institutional repository or publish it in a book), with an acknowledgement of its initial publication in this journal.
- Authors are permitted and encouraged to post their work online (e.g., in institutional repositories or on their website) prior to and during the submission process, as it can lead to productive exchanges, as well as earlier and greater citation of published work (See The Effect of Open Access).
