Safe and Effective Water Acidification for Poultry: Strategies and Considerations

Dr.J.Pothanna Technical Manager Trouw Nutrition India

Maintaining optimal water quality is crucial in poultry farming, as it directly impacts the health, growth, and productivity of the flock. One effective way to improve water quality and promote better health in poultry is through the acidification of drinking water. This practice involves lowering the pH of water to create an environment that is less conducive to harmful pathogens while supporting the birds' overall well-being.

  • Benefits of Water Acidification in Poultry
  • Pathogen Control
  • Enhanced Nutrient Absorption
  • Boosted Immune System
  • Improved Feed Conversion Ratio (FCR)

Acidifying drinking water for poultry offers several benefits, including the inhibition of harmful bacteria like E. coli, Salmonella, and Campylobacter by creating an unfavourable environment for their growth. This approach not only helps in controlling pathogens but also enhances the solubility and bioavailability of essential nutrients, leading to improved digestion and nutrient absorption. Additionally, acidified water supports a balanced gut pH, which boosts the immune system, and studies have shown it can improve feed conversion ratios, making poultry operations more cost-effective by reducing the amount of feed required for weight gain

In poultry, both inorganic and organic acids are commonly used for acidification, but organic acids are generally considered more effective and beneficial for several reasons.

Organic acids like formic, acetic, and propionic acid significantly enhance poultry gut health by promoting beneficial bacteria and suppressing harmful ones, which improves nutrient absorption and overall bird performance. The carboxylic acid group (–COOH) in these acids enables them to penetrate bacterial cells, disrupt their internal environment, and inhibit their growth. Compared to inorganic acids, organic acids provide a longer-lasting effect in the digestive tract, maintaining a stable gut environment essential for optimal health and productivity. They are also safer, less likely to cause irritation or toxicity, and more palatable, which boosts water intake. Additionally, their versatility allows them to be used effectively in water, feed, or as a spray on litter, often in combination with other additives to enhance their overall efficacy.

Inorganic acids, like hydrochloric or sulfuric acid, are primarily used for rapid pH reduction and are less expensive. However, they lack the additional antimicrobial benefits and are more corrosive, potentially leading to equipment damage and handling hazards. Therefore, while both types of acids have their place, organic acids are generally preferred in poultry for their broader benefits and safety profile.

Among the organic acids used in poultry, formic acid is generally the most effective due to its low pKa value of approximately 3.75, which allows it to dissociate more readily and lower the gut pH significantly, enhancing its antimicrobial properties. In contrast, acetic acid, with a pKa of around 4.76, and propionic acid, with a pKa of about 4.87, are weaker acids that are less effective at lowering pH but still contribute to gut health and pathogen control. Therefore, formic acid is often preferred for its superior ability to create a hostile environment for harmful bacteria, while acetic and propionic acids can be used in combination with other acids to achieve a balanced and effective approach in poultry management.

  • Synergistic Effect

In poultry management, using chlorine tablets alongside acidifiers is essential for comprehensive pathogen control and sanitation. Acidifiers lower the pH in the gut, creating an environment that inhibits harmful bacteria, while chlorine tablets, such as sodium dichloroisocyanurate (NaDCC) or trichloroisocyanuric acid (TCCA), disinfect water and surfaces. When these compounds dissolve in water, they release chlorine molecules that form hypochlorous acid (HOCl), an effective disinfectant that penetrates and destroys pathogens. Chlorine tablets maintain a residual level of free chlorine in the water, providing ongoing disinfection and preventing microbial regrowth. This combined approach addresses both internal (gut health) and external (water and surfaces) sources of contamination, ensuring a cleaner environment and better overall flock health. The synergistic effect of acidifiers and chlorine tablets enhances pathogen control and sanitation, leading to improved water quality and reduced risk of disease outbreaks.

 

pH

Hardness mg/Litre

Alkanity

TDS (PPM)

5.5 - 6

0-60

Soft

<200

Normal

50-150

Excellent

 

60-120

Moderately Hard

200-300

High

150-250

Good

 

120-180

Hard

>300

Very high

250-300

Fair

 

>180

Very Hard

 

 

300-500

Poor

 

 

 

 

 

>1200

Not acceptable

Source

NRC 1974.Nutrient and toxic substances in water for livestock and poultry

 

  • Understanding of results

In poultry water acidification, pH measures the water's acidity or alkalinity on a scale from 0 to 14, with lower values being more acidic. Optimal pH for acidified water is typically between 4.0 to 6.0, which helps control harmful bacteria and supports poultry health. Alkalinity refers to the water’s ability to resist changes in pH, largely due to the presence of bicarbonates and carbonates. High alkalinity can neutralize added acids, making it more challenging to lower the pH, thus requiring more acid for effective acidification.

  • Understanding pH and Alkalinity

When the pH of water increases (becomes more basic), the alkalinity does not automatically change because pH measures the current level of acidity or basicity, while alkalinity reflects the water’s buffering capacity. Alkalinity is provided by buffering compounds like bicarbonates (HCO₃⁻) and carbonates (CO₃²⁻). If pH rises due to the addition of these buffering compounds, both pH and alkalinity will increase. Conversely, when the pH decreases (becomes more acidic), the alkalinity typically decreases as well. This is because the buffering compounds (bicarbonates and carbonates) are consumed to neutralize the added acids. Therefore, a decrease in pH usually results in a reduction in alkalinity due to the depletion of these buffering agents.

  • Impact of pH Increase on Hardness and Alkalinity

Water hardness is primarily due to high concentrations of calcium (Ca²⁺) and magnesium (Mg²⁺) ions. When the pH of water increases (becomes more basic), it often results in higher hardness and alkalinity, as elevated pH levels favor the formation of calcium and magnesium carbonates, which enhance hardness and buffering capacity. Conversely, when the pH decreases (becomes more acidic), water typically becomes softer because acidic conditions dissolve calcium and magnesium carbonates, reducing hardness. Lower pH is also associated with lower alkalinity due to decreased buffering capacity. Thus, changes in pH directly influence both hardness and alkalinity of water.

  • TDS as an Indicator of Water Quality

Total Dissolved Solids (TDS) represents the total concentration of dissolved substances in water, including salts, minerals, and organic compounds. It is measured in milligrams per liter (mg/L) or parts per million (ppm). High TDS indicates a high concentration of these dissolved solids, which can influence water hardness, pH, and alkalinity. Specifically, high TDS often means higher hardness if it contains significant amounts of calcium and magnesium salts. TDS can also affect pH and alkalinity depending on the composition of the dissolved substances: alkaline dissolved solids may raise pH and alkalinity, while acidic ones can lower them. Thus, TDS is an important indicator of overall water quality, reflecting the presence and concentration of dissolved materials that affect hardness, pH, and alkalinity.

 

  • Trouw Nutrition’s solution through -Selko pH.

Selko pH is formulated with a synergistic blend of free and buffered organic acids, along with essential minerals. Its composition includes Copper (from Copper sulfate pentahydrate), Acetic acid, Propionic acid, Formic acid, Zinc (from Zinc acetate dihydrate), and Ammonium formate. This carefully selected combination of ingredients works together to achieve multiple benefits. The free organic acids effectively reduce the pH of water and the stomach, supporting better feed digestion. Meanwhile, the buffered organic acids help maintain a healthy microbial balance in the intestine, contributing to overall gut health

Trouw Nutrition operates an innovative laboratory dedicated to optimizing water quality in farm settings. We collect water samples directly from the field, where we perform precise titrations of Selko pH. Based on these analyses, we recommend specific dosing levels to effectively address water quality issues on the farm. For critical control points, we employ advanced Selko inline devices that automatically dispense Selko pH into the drinking water pipelines, ensuring consistent and optimal water conditions.

For a complete overview of our tools and services, please contact your nearest Trouw Nutrition expert/representative