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Probiotics, prebiotics, and phytogenic substances for optimizing gut health in poultry – Part II

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In modern animal production systems, it is essential to minimize the impacts of chronic inflammation and excessive stress so that chickens can use their energy for growth rather than defense.

Although there is no “magic ball” to prevent the multifactorial conditions associated with chronic stress, numerous studies have shown that alternative products, such as probiotics, targeted microbes, prebiotics and phytochemicals, can help improve gut microbial balance, metabolism and intestinal integrity.

PROBIOTICS

Probiotics in adequate doses improve intestinal microbial balance, colonization resistance to infection and immune responses.

Lactobacillus spp., Streptococcus thermophilus, Enterococcus faecalis and Bifidobacterium spp. are the most used lactic acid bacteria (LAB) in probiotic formulations. Possible mechanisms of action include:

Deleted:

There is also ample evidence that probiotics affect the immune system by balancing pro- and anti-inflammatory cytokines. Some probiotics have antioxidant capabilities and improve barrier integrity.

A commercial probiotic based on acid bacteria was recently studied for use in poultry. Using this LAB culture, extensive laboratory and field research has shown increased resistance to Salmonella infections in chickens and turkeys.

Figure 1. Mechanism of action of probiotics against the presence of pathogens at the intestinal level.

Higgins et al. reported that probiotics reduced idiopathic diarrhea in commercial turkey rearing houses based on published experimental and commercial trials. In addition, the probiotic blend was shown to improve yield and reduce production costs in large-scale commercial experiments.

Long-term probiotic requirement

Commercial probiotics that are long-lasting, cost-effective and resistant to the heat pelleting process are urgently needed to promote compliance and wider use.

Some probiotic products contain bacterial spore formers, typically of the genus Bacillus. Some (but not all) have been shown to prevent certain gastrointestinal problems.

Therefore, spores of selected Bacillus strains have been used as reliable direct feeding microorganisms (DFMs) in animal production due to their ability to withstand adverse environmental conditions and long storage periods.

Improving amplification and sporulation efficiency

Field trials suggested that a spore isolate of Bacillus subtilis is effective as a commercial probiotic based on lactic acid bacteria in reducing Salmonella spp. Further research may reveal more potent isolates or combinations of isolates.

Some of these environmental Bacillus isolates have been tested In vitro for antibiotic activity, heat stability and population growth.

High concentrations of NSP

Increased digesta viscosity and longer feed passage time caused by high concentrations of soluble non-starch polysaccharides (NSP) in poultry diets influence the intestinal bacterial population.

Direct feeding microorganisms

Bacillus-DFM has also been shown to prevent gastrointestinal tract disorders and provide a variety of nutritional benefits for both animals and humans. In vitro and in vivo studies have shown that 90% of B. subtilis spores germinate in different segments of the GIT within 60 minutes in the presence of feed.

Interestingly, supplementation with Bacillus-based DFM was shown to improve growth performance, digesta viscosity, bacterial translocation, microbiota composition and bone mineralization in broilers and turkeys fed a rye-based diet.

These differences may be due to the lower amount of substrates available for bacterial growth, which resulted in less intestinal inflammation and bacterial translocation when intestinal viscosity was reduced by including the candidate DFM, implying that the supplemented groups absorbed more nutrients at the brush border of the intestine.

The significant improvements in performance observed in turkeys and broilers fed the Bacillus-DFM supplemented diet compared to the unsupplemented control group suggest that:

Enzyme production from the combined Bacillus spp strains used as DFM can:7

DFM was also shown to significantly reduce the severity of experimental Salmonella enterica subspecies enterica serotype Enteritidis and aflatoxicosis infections.

PREBIOTICS

Prebiotics are a relatively recent concept, arising from the idea that non-digestible food elements (e.g., non-digestible oligosaccharides) are selectively fermented by bacteria known to benefit intestinal function.

Reduction of pathogens

For example, prebiotics can interact directly with intestinal immune cells or interact indirectly with immune cells through colonization of beneficial bacteria and preferred microbial metabolites.

Prebiotics can function similarly to probiotics to support intestinal health in chickens. The most commonly used prebiotics in poultry are:

Benefits of using prebiotics
A frequently used prebiotic concerns Aspergillus oryze, which is marketed as Aspergillus meal (AM). AM includes 16% protein and 44% fiber and can be used to improve performance in commercial poultry diets with low protein levels.

The mycelium or A. oryzae also contains betaglucans, FOS, chitosan, and MOS. This substance also benefits chickens by promoting growth, most likely to improve absorption and digestibility of feed ingredients.

Dietary Aspergillus meal (AM) was shown to alter intestinal morphometry in turkey poults. It increased the number of acid mucin cells, neutral mucin cells and sulfomucin cells in the duodenum and ileum.

In addition to the height and surface area of the villi in the duodenum and ileum of the newly hatched poults compared to the control.

Finally, chitosan is a natural biopolymer created by the deacetylation of chitin, the main component of fungal cell walls and arthropod exoskeletons. As noted above, chitosan has several benefits, including antimicrobial and antioxidant properties.

Also, chitosan has shown promising applications in agriculture, horticulture, environmental sciences, industry, microbiology and medicine. In addition, many studies have used chitosan as a mucosal adjuvant, increasing IgA levels.

Figure 2. The role of symbiotics in digestive physiology.

SYMBOTICS

When a combination of prebiotics and probiotics are used, they are called synbiotics and have the ability to further enhance the viability of probiotics. Probiotics, prebiotics and synbiotics are now widely used throughout the world. In the next section, we discuss the role of synbiotics in digestive physiology and poultry production.

Role of symbiotics in poultry production

Immediately after hatching, birds must switch from endogenous energy – the lipids in the yolk – to energy from an exogenous carbohydrate-rich diet. During this vital period, the size and morphology of the intestine change dramatically. Changes in epithelial cell membranes alter the mechanical interface between the internal environment of the host and the luminal contents.

Studies on nutrition and metabolism of early growth in chicks can help to optimize the nutritional management for optimal growth.

PHYTOGENIC ADDITIVES FOR BALANCED FOODS

Several commercial products are based on herbs such as:

These phytogenic substances are promoted, due to their safety profiles and qualities to improve animal performance and health, through the following effects:

In addition to pharmacological effects, recent studies indicated that phytogenic substances modulate the intestinal microbiota, that is, increase Firmicutes, Clostridiales, Ruminococcaceae and Lachnospiraceae.

Table 1. Effect of diet on microbiome composition.

Various factors can modulate the intestinal microbiota causing a positive or negative effect on the host. The effects of diet on the composition of the microbiome are shown in Table 1. Supplementation of day-old chicks with antibiotics negatively modulated the gut microbiota and adversely affected the development of the immune system.

CONCLUSIONS


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