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How to control ammonia levels in poultry houses

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There are several strategies for controlling ammonia in poultry. These strategies can be used individually or in combination and can help encourage good barn air quality and better potential poultry performance.

One of the biggest complaints surrounding the poultry barn — apart from flies — is the smell of the manure. The ammonia concentration in poultry houses not only contributes to the smell but can be harmful for both the birds in the barn and the workers who frequent the barn. Understanding how ammonia gas is formed, the impact it can have on the bird and how to control ammonia levels can be helpful for proper poultry management.

How is ammonia gas formed?

Nitrogen is a component of poultry diets, via either protein or other sources. Some of this nitrogen can be used by the bird and is incorporated into tissues or eggs, but most of it is excreted in the urine or feces in the forms of uric acid (around 80%), ammonia (around 10%) and urea (around 5%). Once the uric acid and urea are excreted, they are converted into ammonia through microbial and enzymatic breakdown via the bacteria and enzymes found in manure. After this process, ammonia is readily released into the air as a gas that can be detected by both birds and farmworkers.

Factors that influence how ammonia is formed and released into the poultry house environment Factors that influence how manure bacteria and enzymes break down nitrogen to form ammonia
  • Litter type
  • Bird activity
  • Stocking density
  • Manure handling
  • Frequency of manure removal
  • Ventilation rate
  • Nitrogen content
  • Temperature
  • Moisture/humidity
  • pH

What impact can ammonia have on the bird?

The results of poultry research studying how ammonia levels can impact production are varied. Some groups suggest that 25 ppm should be the maximum, whereas other groups suggest that exposing birds to 20 ppm for long periods of time could lead to issues like a debilitated immune system and respiratory tract damage. Other research suggests that, when poultry can choose between environments featuring different levels of ammonia, they choose environments with ammonia levels under 11 ppm.

Ammonia is toxic to animals. High levels of ammonia may lead to observable changes, such as difficulty breathing, irritation of the trachea (the breathing tube), air sac inflammation, inflammation of the mucus membranes of the eye or a combination of these symptoms. Many other, less obvious changes can take place upon exposure to lower levels of ammonia. Studies have found that exposure to 20–25 ppm throughout production can result in increased susceptibility to secondary challenges (viral or bacterial), decreased feed efficiency and tissue damage. These changes have been noted in broilers exposed to ammonia levels between 20–30 ppm for 16–28 days. Studies of turkeys have found that, among birds dealing with an E. coli challenge, those that were exposed to ammonia levels between 10–40 ppm had more bacteria in their lungs than the birds that were not exposed to ammonia. In layers, it has been suggested that early exposure to ammonia could have a lasting effect and might impact how pullets perform later as laying hens. Additionally, chronic exposure to high ammonia concentrations may impair egg production for layers. 

At a microscopic level, researchers have found that exposure to ammonia can trigger changes within the animal. In poultry, high-level exposure to ammonia for 20 days decreased the intestinal surface area (possibly impacting nutrient absorption), decreased the bird’s resistance to oxidative stress, altered the intestinal tract’s ability to break down nutrients and impacted immune organs. Exposure to high concentrations of ammonia for even a short period of time may impact birds just as much as exposure to medium concentrations of ammonia for longer periods.

Harmful effects of ammonia concentrations in poultry and humans

5 ppm Lowest detectable level.
6 ppm Irritation of the eyes and the respiratory tract.
11 ppm Reduced animal performance.
25 ppm Maximum exposure level allowed for a period of one hour.
35 ppm Maximum exposure level allowed for 10 minutes.
40 ppm Headache, nausea and loss of appetite in humans.
50 ppm Severe reduction in performance and animal health; increased possibility of pneumonia
100 ppm Sneezing, salivation and irritation of mucus membranes in animals
300 ppm or more An immediate threat to human life and health.


How to reduce ammonia levels in poultry houses

There are several strategies for decreasing ammonia in the barn. These strategies can be used individually or in combination and can help encourage good barn air quality and better poultry performance potential. These strategies include ventilation and management of both the barn and the poultry litter/manure.

Ventilation acts as an in-barn air quality control, removing ammonia from the barn and bringing in clean air. This method does not, however, reduce or inhibit the formation of ammonia. Nevertheless, maintaining appropriate ventilation during all seasons will help reduce the gaseous ammonia levels in the barn and keep the litter dry.

Good barn management can help to diminish the formation of ammonia gas. Proper barn management includes ensuring that the litter or manure is not wet. Several ways to keep litter from getting wet are to fix leaky drinkers and sprinkler systems; choose the appropriate litter; maintain a suitable barn relative humidity for the age of the bird; reduce the potential for condensation; and properly heat and ventilate the barn.

Strategies for managing the litter and manure can be separated into two main management actions:

  • Managing the bird diet: The formation of ammonia in the manure and its subsequent release as a gas can be traced back to increased nitrogen levels in the manure. Fecal nitrogen levels can increase if the bird does not properly break down and absorb the protein in the feed. This can happen if the bird’s diet features too much complex protein, if the bird is sick or if its gastrointestinal tract is not functioning properly. These issues can be remedied or prevented by balancing the protein and/or amino acid levels in the diet and by maintaining the bird’s gastrointestinal health. 

Another method to help prevent ammonia emissions from nitrogen within the feces is to use components such as the extract of Yucca schigidera, which plays a role in binding ammonia. De-Odorase® is derived from Yucca schigidera and has been shown to reduce blood urea and blood ammonium ions, reduce excessive nitrogen breakdown in the ceca and bind ammonia so it stays in the manure instead of being released as gas. When it is used in the feed from the time the birds are placed to the time the birds leave the barn, it can control the release of ammonia into the air.

  • Managing the manure once it is in the barn: Acidifying agents can be used to lower the pH of the litter (below its usual 7.5–8.5), which will help slow down and decrease the activity of the microbes that break down the nutrients in the manure to release ammonia. Another strategy could be to use odor and moisture absorbents in the litter or manure. These absorbents, which are usually clay-based, act to either slow down the microbial activity or lower the moisture content of the litter. De-Odorase® can also be used as a spray over and on manure to help control ammonia that has been released and reduce its odor. There may also be microbial and urease enzyme inhibitors that can be used to prevent the action of the microbes and enzymes in the manure that help to release ammonia.

All these strategies, however, can be negatively affected by litter and manure accumulation, litter and manure moisture, bird type, barn temperature, disease challenges or a combination of these factors.   

Conclusion

Poultry farm ammonia emissions from manure and ammonia gas in the barn are complex topics in the poultry industry, but with a combination of good ventilation, good barn management and a strategy to reduce ammonia gas formation, this issue can be successfully overcome at any time of the year.

This blog is a summary of an article published in Canadian Poultry.

 

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