INTRODUCTION
Globally, poultry production (meat and eggs) has been the leading sector in the agricultural industry 1,2. It has recently intensified to meet up with the steady increase in the demand for poultry-based agricultural products 3,4. The population of Nigeria has been estimated to increase to 250 million by the year 2030 5. However, poultry producers in Nigeria could find it difficult to meet up with the poultry-based products for human consumption due to the climatic condition (humid tropical climate) in the country. Generally, Nigeria is located on latitude 4 - 14°N and longitude 3 - 15°E and the country is known to be warm mostly throughout the year due to high temperatures ranging from 25 to 32°C 6. Therefore, providing cool environment for the birds could be challenging as it would require constant availability of power supply which could add to the cost of production of the poultry-based products.
Over the years, many studies have been carried out evaluating the productivity and profitability of poultry egg farming in Nigeria 7,8,9,10. Tijjani et al 10 conducted an economic analysis of poultry egg production in the northern part of Nigeria to estimate the cost incurred in poultry production and the returns. The authors indicated that the main problems in the region (Northern Nigeria) were the cost of feed, poor ventilation and poor veterinary and management practices among others. The prospects and challenges facing large scale poultry production were recently evaluated by Adeyemo and Onikoyi 11. They indicated that the major challenges confronting poultry production were poor feed quality, improper handling of eggs during incubation, high cost of feed, poor veterinary services and poor marketing strategies. In a study carried out by Ezeh et al 12, it was shown that flock size, feed consumption and labour input affected poultry production in the eastern region of Nigeria. It could be observed from the above research works that environmental conditions to which the birds were subjected were not considered. Environmental conditions play a crucial role in animal production and it has been indicated that animal performances could be directly related to the environmental conditions to which they are subjected 13,14.
It has been shown that there are two main factors to control the thermal environment of the poultry building 15. The first is the knowledge of the poultry grower (farmer) about the thermoregulation of the birds. The second focusses on the environmental parameters required by the birds. Lack of understanding of the environment to which poultry birds are subjected could result in high mortality and poor production. The heat stress affecting poultry is majorly caused by the air temperature and relative humidity16. These parameters have been indicated to be controlled by increasing the air movement within the poultry building. As reported by Blanes-Vidal et al 17, it is not appropriate to raise poultry birds in an environment with low air movement as it could result in heat stress which could cause significant mortality rates 18. This indicates that it is detrimental to raise poultry birds in the environments that would impair their activities (drinking and feeding) and the exhibition of natural behaviours like wing flapping, dust bathing, perching and distribution.
Heat stress in livestock production could be explained as the combination of any environmental parameters (temperature, relative humidity and air velocity) creating conditions that are greater than the temperature range of the thermoregulatory zone of the animals. A change, either temporal or permanent, in the environment to which animals are kept could result in stress. The change could affect feed consumption, feed efficiency, growth rate, meat yield and quality and egg production of laying birds 19. In case of extreme weather conditions, it may be difficult to control heat stress in poultry birds. According to Kapetanov et al 20, it could be difficult to remove warm air surrounding adult birds by providing higher ventilation rate when the relative humidity within the poultry building is high. Many studies have evaluated the level of heat stress in poultry production using heat stress indices 19,21. However, since climatic conditions in different areas differ, there is still a need to evaluate the heat stress to which poultry birds experience based on the environmental conditions to which they are subjected in the humid tropical climate.
Therefore, the objective of this study was to understand the climatic conditions to which poultry birds (layers) are subjected. In addition, the heat stress to which the birds are experiencing was evaluated based on the environmental parameters measured within the layer bird building so as to understand how to create suitable environment for the birds mostly during the hot weather periods. To this end, this study was set up to 1 measure and evaluate the environmental parameters (air temperature, relative humidity and air velocity) in the layer hens building; 2 determine the level of heat stress to which the birds were subjected.
MATERIALS AND METHODS
Experimental site. The study was carried out at Poultry Research Farm of the Federal University of Technology, Akure, Ondo State, Nigeria. The study area falls between the latitudes 7° 17' 03'' N to 7° 19' 06'' N and longitudes 5° 07' 02'' E to 5° 09' 05'' E. The area is characterised for having high temperatures ranging from 22°C to over 30°C throughout the year.
It also has two major seasons namely; rainy season (April to October) and dry season (November to March). It has an annual rainfall of about 2400 mm, which makes the region to be more humid.
This research study was conducted in one of the naturally ventilated layer houses in the Research Farm. It is the largest house with dimensions 29.5 m (length), 9m (width) and 3.5 m (height). The house has a one-sided open roof designed to allow heat loss from the building (Figure 1). The house was located at about 7.5 m away from another house at the windward side (Figure 2) and surrounded by vegetations such as orange tree and plantains at the leeward side and one of its ends respectively. The houses were occupied with three sets of 3-tiered battery cages (Figure 2 and 3). The birds were manually fed by the farm workers while the watering system is automatically controlled. The droppings from the birds fall into about 0.7 m deep pit directly under the cages and daily washed into an opened outdoor pit where it could either be allowed to decay or used for agricultural purpose.
Instrumentations. In this study, data acquisition both within the house and the outdoor were hot wire anemometer (HT-9829) for indoor, fan wheel anemometer (AS836) for outdoor and temperature-hygrometer sensors (HTC-1) for both indoor and outdoor. The hot wire anemometer has accuracies of ±1°C and 1% for temperature and air velocity respectively, resolutions of 0.1 and 0.01 ms-1 for temperature and air velocity respectively and measurement ranges of 0-50°C and 0.125.0 ms1 for temperature and air velocity respectively. The fan wheel anemometer has measurement ranges of 0-45°C and 0.0-45.0 ms1 for temperature and air velocity respectively, accuracies of ±2°C and ±3% for temperature and air velocity respectively and resolutions of 0.2°C and 0.1 ms1 for temperature and air velocity respectively. The temperature-hygrometer sensor has temperature and humidity measurement ranges of -10 to +50°C and 10-99% respectively, temperature and humidity resolutions of 0.1°C and 1% respectively and temperature and humidity measuring accuracies of ±2°C and 10% respectively. In this study, only the relative humidity of the temperature-hygrometer sensor was recorded since the other sensors have temperature sensors embedded in them.
Experimental measurements. The measurements obtained during the study were, air temperatures (indoor and outdoor), relative humidity (indoor and outdoor) and air velocity (indoor and outdoor). All the sensors (hot wire anemometer, digital anemometer and temperature-hygrometer sensor) were installed both indoor (at the centre of the house) and outdoor (at the windward side of the house) at the height of 2.5 m above the floor (Figure 4). The study was conducted over a period of three hours when the climatic condition was considered to be harsh for poultry birds 22. Generally, in Nigeria, the climatic condition starts to be hot around 1100 H and lasts till around 1600 H. In this study, the three hours study was conducted between 1100 H and 1400 H. The environmental parameters were measured and recorded at an interval of 5 minutes.
The heat stress index (THI) to which the laying hens were subjected to in the layer house was estimated using an expression developed by National Oceanic and Atmospheric Administration (NOAA) for the laying hen heat stress index and also used in other studies 19,23. The heat stress index for the laying birds (Equation 1) was developed based on the indoor temperature and relative humidity of the house since the heat stress is mostly assessed by the THI 24.
THI (Ti, Hi) = (9/5Ti + 32)- 11/2(1-Hi)(9/5Ti-26)
where Ti is the indoor temperature (°C) and Hi is the indoor relative humidity (%).
Data analysis. The data obtained during the study were processed with Microsoft Excel 2016 and analysed with SAS JMP Pro 13. The processed data were subjected to t-test (one tailed) to determine the level of significance between the indoor environmental parameters and the outdoor environmental parameters. The data analysed was subjected to a significance level of 5%.
RESULTS
Air temperature. The air temperatures variation inside and outside the layer house were measured and analysed. The results of the air temperature measured during the study are shown in Figure 5. The outdoor temperature fluctuated between 29 and 38.4°C while the indoor temperature steadily increased from 28.9°C to over 33°C. The panting rate, a potential indicator of heat stress of the laying birds, was monitored by an observer during the study to evaluate the level of heat stress in the building. It was discovered that the panting rate of the birds was high as the temperature increased. The result of the statistical analysis (t-test) indicated that there was a difference (p<0.0001) between the mean air temperature inside the house and the air temperature outside the house.
Relative Humidity. Figure 6 shows the relative humidity obtained both within and outside the layer house. As shown in Figure 6, outdoor relative humidity varied between 32.0% and 50.0% while the indoor relative humidity was initially high (79.0%) and steadily dropped to 59.0% after three hours. The result of the t-test analysis showed that there was a difference (p<0.0001) between the mean outdoor relative humidity and the mean indoor relative humidity.
Air Velocity. The indoor and outdoor air velocity were evaluated to understand the level of air velocity to which the birds and the building were exposed to during the hot weather periods. Figure 7 illustrates the air velocity measured and recorded over three hours. It could be observed from Figure 7 that the outdoor and the indoor air velocities varied from 0.0 ms-1 to 1.68 ms-1 and 0.07 ms-1 to 0.58 ms1 respectively. The results of the t-test analysis carried out indicated that there was a significant difference (p=0.003) between the mean air velocity outside the building and the air velocity within the laying birds building.
Layers Heat Stress Index (LHSI). The level of heat stress in the building, using an established heat stress index for laying birds, was estimated based on the temperature and the relative humidity within the building. Figure 8 shows the heat stress index of the layer house over the period that the study was carried out. As it could be observed from Figure 8, the heat stress was high (53.97) at around 1100 H when the study commenced and steadily reduced to 15.93 at around 1400 H.
DISCUSSION
Air temperature. Subjecting poultry to the hot condition has been reported to be detrimental to their welfare and health 25. In this study, it was found that the temperature within the layer house could affect the productivity and normal behaviours of the birds. For laying birds (pullet), the upper critical temperature (UCT) of the thermal comfort zone, as suggested by Chang et al 26, should range between 24 and 26°C. However, in this study, it has been found that the indoor temperature of the house exceeded the thermal comfort zone required by the birds to thermoregulate easily. Exposing layers to high air temperature could increase their body temperature and could also cause high mortality, poor feed and water consumptions, slow growth rate, poor egg production, and aggressiveness 27,28,29.
Relative Humidity. The higher indoor relative humidity observed at the onset of the study could have occurred as a result of the low indoor temperature observed when the study commenced. This relationship has earlier been reported by Nilius et al 30. They showed that relative humidity increased as the temperature reduced. Many factors could be responsible for the increase in the relative humidity recorded at the beginning of the study. The contributing factors could be the manure pit directly under the cages, moisture loss during panting and water drops from the drinkers 31. The adverse effects of high temperature and high relative humidity include; heat stress, increased body temperature, hormonal imbalance, poor animal performance, poor heat dissipation, respiratory disorder, disease outbreak, poor egg production, poor feed conversion 32.
Air Velocity. This study has shown that still air condition (no air movement) could occur outside the animal building and that it could significantly affect the air velocity distribution within the animal building. Similarly, the amount of air velocity obtained within the building may not provide adequate air movement required by the birds for their cooling during the weather period. It is expected that the air velocity in poultry building should be capable of preventing excessive heat and dangerous gases that could impair the welfare of birds 22. However, this study has shown that the air velocity in the layer house, where the study was conducted, may not be able to prevent excessive heat and dangerous gases from affecting the welfare of the layer birds. As suggested by Kavolelis et al 33, since the natural ventilation in the building was not sufficient to provide a cool environment for the birds, it is necessary to install fans in the building to improve air distribution, birds' welfare and performances.
Layers Heat Stress Index. The high THI noticed at 1100 H could have been caused by the high relative humidity of 79.0% measured at the onset of the study. Similar results have been reported in which high heat stress was majorly caused by high relative humidity compared to ambient temperature 34,35. The performance of laying birds greatly depends on the heat stress they are subjected. Duduyemi et al 19, have classified the THI in laying birds as comfortable (<26), heat stress (26.0 - 29.0) and acute heat stress (>29). In this study, based on the report of Duduyemi et al 19, it could be observed that the laying birds in the humid tropical climate are mostly subjected to heat stress and acute heat stress and are less subjected to comfortable conditions during the hotter periods of the day (1100 to 1400 H). According to Duduyemi et al 19, the performance of laying bird could reduce as the THI increases above the threshold of 27.5.
In conclusion the indoor environmental parameters and the heat stress index of a laying bird house have been assessed. The results have shown that poultry birds, during the hotter periods of the day, are subjected to high environmental conditions (temperature and humidity) which could be detrimental to their performances. The only mechanism (air velocity) which has been reported to mitigate the impact of hot weather conditions on livestock production has been found to be insufficient as its level in the laying bird building was below 1.5 ms-1 recommended for poultry birds subjected to hot conditions. Similarly, birds are mostly subjected to heat stress throughout their lifetime due to high heat stress which is majorly influenced by high relative humidity.
Therefore, there is a need for ventilation engineers in the humid tropical climate to design and develop a conducive environment for the laying birds which could enhance their performances. The engineers should also develop appropriate ventilation system(s) capable of improving the air movement in the poultry buildings most especially at the animal occupied zone. Further research work could be focussed on evaluating the laying bird building using computational fluid dynamics to understand the airflow pattern and air velocity distribution within the laying bird building. This would also assist the engineers to develop appropriate and suitable buildings for the battery-caged birds in the humid tropical climate.