Explore

Communities in English

Advertise on Engormix

Why Do We Need Low Protein Meat Chicken Diets?

Published: November 15, 2024
By: M. HILLIAR 1 and R. SWICK 1 / 1 School of Environmental and Rural Sciences, University of New England, Armidale, NSW 2351, Australia.
Summary

The current level of protein used in meat chicken diets is linked to various issues observed in the industry including feed cost and feed efficiency, health and welfare concerns, and negative environmental impacts. This review covers the benefits of low protein diets and how they can be extended into industry with use of feed additives and management. The implementation of low protein diets will contribute to the sustainability and efficiency of the poultry industry.

I. INTRODUCTION

The meat chicken industry is growing rapidly as a result of an increasing population, relatively low production costs and excellent marketability with regards to affordability, sustainability and minimal religious restrictions. Poultry diets with lower crude protein (CP) have generated global interest from the meat chicken industry due to the benefits concluded by published literature. Low protein (LP) diets have been identified to lower feed costs, improve feed utilisation, reduce environmental impacts, and minimise health and welfare concerns. This review will give a comprehensive overview of the benefits of LP diets and methods for their adoption by the poultry industry.

II. THE BENEFITS OF LOW PROTEIN DIETS

a) Feed cost and ingredient concerns

The current CP levels used in the poultry industry contribute to higher feed costs. Poultry feed is not only the most expensive component of chicken production but, with 287 mmt of poultry feed produced globally in 2016 (Alltech, 2017), any unnecessary costs incurred are significant. To satisfy the nutritional requirements of meat chickens and meet production goals, minimum levels of digestible amino acids (AA) must be presented in the feed. In poultry diet formulations, grains can make up half the CP content; the remaining digestible AA requirements are achieved with protein meals and crystalline AA. Protein meals supply a broad range of AA while crystalline AA are used to meet specific AA requirements. Compared to other unprocessed feed ingredients, these products require manufacturing from raw materials, adding to their overall cost. Crystalline AA supplements are becoming more affordable, enabling the practical extension of LP diets in industry.
Protein meals present inconsistent nutrient profiles, are known to contribute to health issues and are linked to negative environmental impacts. Both fish and meat and bone meals vary in amino acid digestibility between batches due to inconsistencies in source and manufacturing (Smith and Scott, 1965; Batterham et al., 1986). Batterham et al. (1986) observed a decrease in lysine availability in meat and bone meal from 93% to 86% and 31% with application of heat (125°C and 150°C, respectively) over four hours. In 2000, use of meat and bone meal in animal feed was banned in the European Union, following transmissible spongiform encephalopathy outbreaks (Ducrot et al., 2013), restricting meat and bone meal use in poultry feed. Animal derived protein meals have also been identified as a predisposing factor for necrotic enteritis and are subject to oxidative rancidity, impairing chicken health and efficiency (Drew et al., 2004). Soybean meal (SBM) is the most widely used protein meal in the poultry industry due to its ideal nutrient characteristics. In 2015/2016 Australia imported 775,000 tonnes of SBM compared to local soybean production of only 27,000 tonnes (USDA, 2017). Importing SBM from the US, Argentina and Brazil includes transportation and importation costs and biosecurity and customs regulations not incurred for domestically produced ingredients. SBM produced in Brazil can be associated with tropical deforestation, a result of grazing cattle being pushed into forested areas to enable soybean production in grassland areas; this is of consumer concern and reflects on industries that use this product (Morton et al., 2006). Australian canola meal, a plant based protein meal, is lower in energy compared to SBM and contains anti-nutritive components including glucosinolates, tannins and phytate, which restrains its use in poultry diets (Khajali and Solminski, 2015).
Digestible AA are known as expensive nutrient requirements in meat chicken diets. A review into existing requirements and reducing industry dependence on current protein levels will help reduce environmental impacts and improve bird health, feed cost and feed utilisation.

b) Feed utilisation, health, welfare, and environmental impacts

Excess CP can overload the gastrointestinal tract (GIT) with excessive AA, peptides and undigested protein (Apajalahti and Vienola, 2016). This overload impedes feed efficiency, contributes to health and welfare issues and adds to negative environmental impacts. Excess AA presented in the diet are absorbed and catabolised, producing higher levels of N excretion in the form of uric acid (Wu, 2013). Improved feed utilisation can be achieved by improving N retention. Belloir et al. (2017) investigated the effect of dietary CP on N retention. Birds fed diets containing 150 g/kg CP achieved 70% N retention in comparison to birds on the 190 g/kg CP diet achieving only 60% N retention (r = 0.86). Reducing dietary CP can improve N utilisation.
Dietary protein content is correlated with water consumption and excretion (Alleman and Leclercq, 1997; Wheeler and James, 1949), which leads to wet litter at higher dietary CP levels. Higher water consumption may result from the sodium dependent AA transporters drawing water across the lumen with greater AA absorption. Wet litter occurs as a result of increased water excretion and water spillage from more frequent visits to the water lines. Wet litter is known to cause dermatological diseases such as foot pad dermatitis and cellulitis (Harms et al., 1977). Skin infections are the main causes of carcass and chicken paw downgrade, reducing the yield of the meat chicken industry (US Poultry & Egg Export Council, 2009).
Undigested protein that exits the small intestine acts as a substrate for the bacterium Clostridium perfringens in the hindgut, a pathogenic bacterium responsible for necrotic enteritis (Drew et al., 2004). The combination of the higher N waste levels (Ferguson et al., 1998), odorants (Sharma, et al., 2017) and wet litter (Wheeler and James, 1949) that are associated with higher CP diets, creates an optimal environment for disease and infection. These have all been reduced with LP diets (Belloir et al., 2017; Sharma et al., 2017; Wheeler and James, 1949), lowering the risk of disease and improving animal welfare. With the removal of antibiotic growth promoters from poultry diets, the risk of necrotic enteritis and other diseases will increase. Any disease preventative measures, including reduction of dietary CP, become increasingly important.
N wastes have become a focus of environmental sustainability due to their impact on waterway pollution and ecosystems (Sims and Wolf, 1994). Reducing dietary CP further promotes the sustainability and marketability of the poultry industry. Improving industry sustainability with LP diets comes from reduced water intake and N excretion (Wheeler and James, 1949; Belloir et al., 2017).
Decreasing industry dependence on dietary CP improves the health and welfare of meat chickens by improving living conditions as well as feed utilisation. The health benefits of LP diets must also be considered with future regulations on antibiotic growth promoter use. To remain an efficient and sustainable production system, the industry must consider concepts such as LP diets.

III. ACHIEVING LOW PROTEIN DIETS

In order to achieve the widespread use of LP diets in the meat chicken industry, several methods must be investigated. Supplementation of crystalline essential AA such as D,Lmethionine, L-lysine HCl and L-threonine to balance the digestible AA in intact protein, reduces dietary CP to the current levels observed in poultry diets.
One method of maintaining performance with LP diets involves using an ideal amino acid ratio to ensure minimum amounts of AA are offered in the required quantities and ratios without overloading the gut with excess protein. A study conducted by Belloir et al. (2017) found that the use of an ideal amino acid ratio described by Mack et al. (1999), with modifications to arginine and threonine, did not negatively affect performance in diets at 190 and 170 g/kg CP.
In conjunction with ideal amino acid ratios, other crystalline amino acid supplements such as nonessential AA have also been investigated. Maintaining performance with diets containing 160 g/kg CP (Dean et al., 2006; Ospina-Rojas et al., 2014) has been achieved with the use of crystalline essential AA and glycine. Many studies consider both glycine and serine (Gly + Ser) levels in LP diets due to their interconversion in vivo (Wu et al., 2013). Glycine has been thought to become limiting in LP diets because of its involvement in uric acid synthesis and the prominence of glycine in collagen and other important proteins such as heme (Wu et al., 2013; Shoulders & Raines, 2009). Optimum levels of Gly + Ser are yet to be agreed upon, with Schutte et al., (1997) suggesting 18 g/kg, while Dean et al. (2006) concluded that total levels need to be 23 g/kg and that lower levels of CP require higher levels of Gly + Ser. The requirement level of Gly+Ser must be confirmed for the successful adoption of LP diets in the poultry industry.
Methods of improving nutrient digestibility must also be considered. Protease is an enzyme which increases the digestibility of CP so this additive must be considered in LP diets. Angel et al., (2011) maintained bird performance at 205 g/kg CP with addition of monocomponent protease at a minimum of 200 mg/kg. Use of insoluble fibre (Hetland et al., 2003) and intermittent lighting (Rodrigues et al., 2017) have improved gut health and function by increasing GIT content retention time. These materials and practices may also contribute to maintaining performance under low CP diets, although more work is required to investigate their effects on N digestibility.
The use of ideal amino acid ratios, crystalline amino acid supplements, proteases and gut enhancing materials and practices will contribute to the employment of LP diets in the industry. This adoption of LP diets will have benefits in production and costs while addressing health, welfare and environmental issues.

IV. CONCLUSION

The extension of LP diets in the poultry industry promotes a decrease in feed costs, environmental, health and welfare issues and an increase in N utilisation with proper dietary formulation. These benefits will result in an improvement in environmental sustainability and marketability of the meat chicken industry. LP diets have the potential to contribute to the successful adoption of antibiotic free animal production, reducing predisposing factors to disease. LP diets can be achieved with crystalline AA, proteases and GIT enhancing practices. However, LP diets require further research to make their extension practical, profitable and worthwhile for the Australian meat chicken industry.
      
Presented at the 29th Annual Australian Poultry Science Symposium. For information on the next edition, click here.

Alltech (2017) Global Feed Survey 2017.

Angel CR, Saylor W, Vierira SL & Ward N (2011) Poultry Science 90: 2281-2286.

Apajalahti J & Vienola K (2016) Animal Feed Science and Technology 221: 323-330.

Belloir P, Meda B, Lambert W, Corrent E, Juin H, Lessire M & Tesseraud S (2017) Animal 11: 1881-1889.

Batterham ES, Darnell RE, Herbert LS & Major EJ (1986) British Journal of Nutrition 55: 441-453.

Dean D, Bidner TD & Southern LL (2006) Poultry Science 85: 288-296.

Drew MD, Syed NA, Goldade BG, Laarveld B & van Kessel AG (2004) Poultry Science 83: 414-420.

Ducrot C, Paul M & Calavas D (2013) Natures Sciences Sociétés 21: 3-12.

Ferguson NS, Gates RS, Taraba JL, Cantor AH, Prescatore AJ, Ford MJ & Burnham DJ (1998) Poultry Science 77: 1481-1487.

Harms RH, Damron BL & Simpson CF (1977) Poultry Science 56: 291-296.

Hetland H, Svihus B & Krogdahl Å (2003) British Poultry Science 44: 275-282.

Khajali F & Slominski BA (2015) Poultry Science 91: 2564-2575.

Mack S, Bercovici D, de Groote G, Leclercq B, Lippens M, Pack M, Schutte JB & van Cauwenberghe S (1999) British Poultry Science 40: 257-265.

Morton DC, DeFried RS, Shimabukuro YE, Anderson LO, Arai E, del Bon Espirito-Santo F, Freitas R & Moresette J (2006) Proceedings of the National Academy of Science of the United States of America 103: 14637-14641.

Ospina-Rojas IC, Murakami AE, Duarte CR, Eyng C, Oliveira CA & Janeiro V (2014) British Poultry Science 55: 766-773.

United States Department of Agriculture (2017) Production, Supply and Distribution. Retrieved from: https://apps.fas.usda.gov/psdonline/app/index.html#/app/advQuery

US Poultry & Egg Export Council (2009) US Chicken Feet Kicked Out of China. http://www.thepoultrysite.com/poultrynews/18142/us-chicken-feet-kicked-out-of-china

Rodrigues I, Toghyani M, Svihus B, Bedford M, Gous R & Choct M (2017) Proceedings of Australian Poultry Science Symposium 28: 266.

Schutte JB, Smink, W & Pack M (1997) Archiv für Geflügelkunde 61: 43-47.

Sharma N, Choct M, Dunlop MW, Wu S, Castada HZ & Swick RA (2017) Poultry Science 96: 851-860.

Shoulders M & Raines R (2009) Annual Review of Biochemistry 78: 929-958.

Sims JT & Wolf DC (1994) Advances in Agronomy 52: 1-83.

Smith RE & Scott HM (1965) Poultry Science 44: 394-400.

Wheeler RS & James EC (1949) Poultry Science 28: 465-467.

Wu G (2013) Amino Acids: Biochemistry and Nutrition: CRC Press, 2013.

Related topics:
Authors:
Matt Hilliar
Robert Swick
University of New England
University of New England
Recommend
Comment
Share
Profile picture
Would you like to discuss another topic? Create a new post to engage with experts in the community.
Featured users in Poultry Industry
Padma Pillai
Padma Pillai
Cargill
United States
Kendra Waldbusser
Kendra Waldbusser
Pilgrim´s
United States
Phillip Smith
Phillip Smith
Tyson
Tyson
United States
Join Engormix and be part of the largest agribusiness social network in the world.