Efficiency of food egg production used for keeping layers of monochrome light with different wavelengths

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.

Influence of light wavelength on viability and reproductive function of hens

The article presents the results of influence of monochrome light with different light wavelengths on the hens’ viability and productivity. 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 “Big Dutchman” cage batteries, consisting of 1176 cages with an area of 40544 cm2. The differences between the poultry houses applied only to LED lamps. 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 4 groups – 653 nm (red color of the spectrum). Every day, for 34 weeks of the productive period (up to 52 weeks of age), the number of eggs laid by the laying hens of each group was 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. It was found that the reduction of the wavelength of light during the keeping of hens in the cages of multi-tiered batteries affects their viability and reproductive function. The decrease in the peak wavelength from 653 to 632 nm, which was manifested by a change in the color of light from red to orange, was accompanied by a decrease in the preservation by 0.3 %, body weight – by 0.8 %, egg laying on the initial laying – by 3.1 %, egg-laying per average laying hen – by 2.8 % and feed costs – by 0.2 %. 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 by 6.4–6.7 %, body weight – by 0.5–1.3 %, egg production by initial laying hen – by 7.1–10.0 %, laying hens on the average laying hen – by 0.4–3.2 % and feed costs – by 2.0–2.1 %. The decrease in the peak wavelength to 458 nm, that is the change in light color from red, orange and yellow to blue, was accompanied by a decrease in the preservation by 3.2–9.9 %, body weight – by 5.2–6.5 %, laying hens per initial laying hen – by 6.4–15.8 %, laying hens per middle laying hen – by 2.9–6.0 % and feed costs – by 1.0–3.1 %.

Economic Analysis of Kamrupa Compared to Local Chicken Production in Assam under Backyard System of Rearing

Aims: The programme was undertaken to study the economic analysis of Kamrupa and local chicken in Dhemaji district of Assam under backyard system of rearing. Study Design: The data on various expenses and returns thus collected were tabulated and subjected to statistical analysis as per the methods described by [1]. Place and Duration of Study: The study was conducted in Sissiborgaon, Dhemaji and Jonai development blocks of Dhemaji district during the period January, 2018 to July, 2019 by Krishi Vigyan Kendra, Dhemaji. Methodology: For the purpose thirty numbers of farmwomen from three different development blocks, thus a total of ninety numbers of farmwomen, of Dhemaji district were selected on the basis of their early experience in keeping local poultry along with Kamrupa chicken at backyard system. Items of cost included fixed cost e.g. land and building, equipments and variable costs e.g. cost of day-old chick, cost of feed, vaccine, medicine, labour, depreciation in poultry shed and miscellaneous cost. Return items included eggs, cocks and spent hens. Results: The cost of labour accounted for 72.44 percent of the total cost of production of Kamrupa chicken followed by feed cost (9.79%), chick cost (7.21%) and depreciation of poultry house (6.44%) up to 18 months of age. The total cost of production up to 72 weeks of age was found to be higher in Kamrupa (Rs. 3,882.48) than its local counterpart (Rs. 3,512.48). The maximum amount of income was contributed by selling of eggs (46.60%) followed by sale of cocks (26.76%) and sale of spent hens (26.64) in case of local chicken. The benefit-cost (B:C) ratio in Kamrupa and local chicken were recorded as 2.64 and 2.14, respectively, in the present study. Conclusion: From the study, it can be concluded that the small scale Kamrupa rearing is a profitable venture for farmwomen in the state of Assam.

Hen reproductive function under the influence of technological stressor

Modern industrial poultry enterprises use cage equipment for keeping laying hens, which is located in 12 and even 15 tiers, forming 4–5 floors. This makes it possible to increase the birds concentration in the poultry house by 4–5 times as compared to 3-tier cage batteries, and by 8–10 times as compared to the outdoor method of keeping. When using a 4–5 floors arrangement of cage batteries, the number of hens in one poultry house can reach 590 thousand birds. However, there are no data on the effect of such keeping on the physiological state of hens. Therefore, it is relevant to study the effect of the height of the cage battery on the reproductive function of laying hens of an industrial herd, which forms the efficiency of production of edible eggs. For this, in the conditions of a modern complex for the production of edible eggs, 4 groups of hens were formed, each of which was kept on a separate floor-analogue in area and cage equipment, located in one poultry house. Each floor was equipped with 3-tier cage batteries: tiers 1–3 were part of the 1st floor, tiers 4–6 — on the 2nd, 7–9 tiers — on the 3rd, and tiers 10–12 — 4th floors of cage equipment. The reproductive function of hens was assessed by the egg production for the initial and middle hens, its intensity and the weight of eggs. The research results showed that the content of layers in the cages of the batteries of the second floor was accompanied by a slight decrease in the safety of livestock — by 0.2–0.5%, egg production per initial layer — by 1.9–2.2%, which led to a decrease in the gross production of eggs by 0.6–0.7 million eggs, egg mass — by 48.9–67.0 tons and a decrease in the European efficiency factor by 0.7–0.9 units.Whereas when keeping laying hens in the cages of batteries on the first floor, there was a decrease in preservation by 10.3–10.8%, egg production per initial hen — by 6.4– 8.4% and body weight — by 7.5–8.1%, which led to a decrease in the gross production of eggs by 1.9–2.6 million pieces, egg mass — by 143.8–210.8 tons and a decrease in the level of the European coefficient of efficiency of egg production by 1.7–2.6 units. Thus, an increase in the layering of the cage equipment does not have a negative effect on hens reproductive function and the keeping of laying hens in the cages of the batteries of the first floor leads to the development of a stress state in them, which manifests itself in a decrease in the safety and deterioration of hens reproductive function, which leads to decrease in the efficiency of egg production.

Study of Cold Air Treatment in a Poultry House in the Conditions of Azerbaijan

Broiler farming at industrial poultry enterprises is carried out in conditions of intensive technology. One of the most important technological aspects is the creation and maintenance of regulatory parameters of the microclimate in the production room, that is, comfortable conditions for poultry at the level of livestock placement. Ensuring an optimal microclimate is achieved through a complex of supply and exhaust ventilation equipment and auxiliary systems. It is important to determine the level of influence of the microclimate in the formation of viability and productivity of broilers in the industrial cultivation technologies; features of the formation of microclimatic zonality in poultry houses, which indirectly determines the uniformity of the poultry herd, and to outline ways to improve the microclimate. The use of water evaporators in the field of cold air treatment has shown that structures with freely assembled material cannot simultaneously fully, evenly and efficiently copy the treated air. All this creates the need for mathematical modeling of the process of mass transfer of heat going in the channels of evaporation tubes provided for by the improved scheme.

New Insights into the Hourly Manure Coverage Proportion on the Manure Belt in a Typical Layer House for Accurate Ammonia Emission Modeling

The main advantage of having livestock, for example, the laying hens, in a controlled environment is that the optimum growth conditions can be achieved with accuracy. The indoor air temperature, humidity, gases concentration, etc., would significantly affect the animal performance, thus should be maintained within an acceptable range. In order to achieve the goals of precision poultry farming, various models have been developed by researchers all over the world to estimate the hourly indoor environmental parameters so as to provide decision suggestions. However, a key parameter of hourly manure area in the poultry house was missing in the literature to predict the ammonia emission using the recently developed mechanistic model. Therefore, in order to fill the gap of the understanding of hourly manure coverage proportion and area on the manure belt, experimental measurements were performed in the present study using laying hens from 10 weeks age to 30 weeks age. For each test, six polypropylene (pp) plates were applied to collect the manure dropped by the birds every hour, and photographs of the plates were taken at the same time using a pre-fixed camera. Binary images were then produced based on the color pictures to determine the object coverage proportion. It was demonstrated that for laying hens of stocking density around 14 birds/m2, the manure coverage proportion at the 24th hour after the most recent manure removal was about 60%, while the value was approximately 82% at the 48th hour. Meanwhile, for laying hens at different ages, the hourly increment of manure coverage proportion showed a similar pattern with four distinct stages within 48 h. The statistical analyses demonstrated no significant correlation between the hourly increment of manure weight and the hourly increment of manure coverage proportion. Finally, prediction models for estimating the hourly manure coverage proportion on the manure belt in typical laying hen houses were provided.

Microbial communities of poultry house dust, excreta and litter are partially representative of microbiota of chicken caecum and ileum

Traditional sampling methods for the study of poultry gut microbiota preclude longitudinal studies as they require euthanasia of birds for the collection of caecal and ileal contents. Some recent research has investigated alternative sampling methods to overcome this issue. The main goal of this study was to assess to what extent the microbial composition of non-invasive samples (excreta, litter and poultry dust) are representative of invasive samples (caecal and ileal contents). The microbiota of excreta, dust, litter, caecal and ileal contents (n = 110) was assessed using 16S ribosomal RNA gene amplicon sequencing. Of the operational taxonomic units (OTUs) detected in caecal contents, 99.7% were also detected in dust, 98.6% in litter and 100% in excreta. Of the OTUs detected in ileal contents, 99.8% were detected in dust, 99.3% in litter and 95.3% in excreta. Although the majority of the OTUs found in invasive samples were detected in non-invasive samples, the relative abundance of members of the microbial communities of these groups were different, as shown by beta diversity measures. Under the conditions of this study, correlation analysis showed that dust could be used as a proxy for ileal and caecal contents to detect the abundance of the phylum Firmicutes, and excreta as a proxy of caecal contents for the detection of Tenericutes. Similarly, litter could be used as a proxy for caecal contents to detect the abundance of Firmicutes and Tenericutes. However, none of the non-invasive samples could be used to infer the overall abundance of OTUs observed in invasive samples. In conclusion, non-invasive samples could be used to detect the presence and absence of the majority of the OTUs found in invasive samples, but could not accurately reflect the microbial community structure of invasive samples.