Feed Processing: Particle Size and Performance Relationship

Feed processing and particle size play an important role in maximizing benefits within animal nutrition. Current food techcnologies only seek to enhance intake and efficiency in the use of nutrients. A finer size of feed particles allows the optimal nutrient use, and improves production animal yields.

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There is a limit as to the fineness of particle size, as very fine particles adversely affect gut health due to an increased incidence of stomach ulcers in pigs and a dysfunction of the gizzard in birds.

As for the size of coarse particles, these increase acidification of  the stomach and intestine, which can be beneficial in controlling enteric pathogens’ proliferation.

Advances in genetics have undoubtedly produced commercial lines of birds and pigs with a higher yield (growth, reproduction, etc.) with a lower feed supply.

Feed processing and diet manufacturing have also evolved in such a way that diet composition, ingredient choices , and form have been refined to improve food consumption and efficiency. 

The main function of feed is to provide nutrients that can be digested and used for productive and maintenance functions.

 

To maximize yield, pig and poultry diets must contain the right balance of essential nutrients to meet the nutritional needs of the different production stages.

Application in diet formulation requires an  intimate knowledge  of the animal, its daily nutritional needs, feed consumption potential,  and understanding the selected foods’ capacity to provide the target nutrient at the lowest/best cost.

Today, most pig and poultry feed is manufactured by employing a combination of food processing technologies. These include physical grinding with  hammer  and/or roller mills along with hydrothermal processing which includes granulation, expansion or extrusion.

It is well known that processing parameters such as the degree of particle modification, temperature, pressure, duration and processing water determine the physical and chemical reactions between nutrients. As well as determining the adhesive properties on these particles’ surface.

These attributes can directly and indirectly influence the impact of processed feed on the digestive tract’s microbiota. Therefore, having an impact on health, yield, and cost of animal feed.

The presence of large amounts of fine particles in pig feed  leads to an increased incidence of stomach ulceration.  In this context, finer particles tend to increase the fluidity of the stomach contents, which is associated with lesions of the “esophageal pars”.

Pigs fed a coarse particle diet  have heavier stomachs than pigs fed a fine particle diet. This is related to the fact that coarse diets require greater muscle action for stomach processing  than fine diets.

The proventriculus and gizzard are the true stomach compartments in birds. HCl and pepsinogen are secreted in the proventriculus and mixed with the contents of the gizzard through muscle movements.

Due to the lack of teeth in birds, the gizzard has the important additional function of grinding feed material.

The lack of structural components in bird diets has been associated with dilated proventriculus and a non-functional gizzard, relating to feed utilization   and gut health.

It has also been reported that the volume of gizzards can increase when  structural components such as whole or coarsely ground cereals are added to the diet. Such increase can be twice the original size.  

Due to the grinding in the gizzard, the particles that reach the small intestine have no relation to the size of the original food particles. Therefore, the impact of the size of the food particles on the physiology of the small intestine and the cecum is minimal.

The distribution of  food particle  size has been associated with a strong influence on the presence of enteric pathogenic bacteria. Data shows that thick particle sized food generates a greater pH decrease in stomach contents compared to fine sized particles.

Studies show that pigs fed coarse crushes  had  much higher gastric microbial fermentation  than pigs fed finer diets. Associated with: slower gastric passage rate, higher gastric dry matter content and consistency.

With a low gastric pH, protein digestion and populations of beneficial bacteria (lactobacilli) are maximized and harmful bacteria such as enterotoxigenic E. coli  are inhibited.

Feed particle size not only affects gastric ecology, but also other parts of the GI tract, especially that of the large intestine.

 

POULTRY

As in pigs, the gizzard in birds is considered an  important barrier that helps prevent pathogenic bacteria from entering the intestinal tract. Bacteria  that enter the intestinal tract through food have a higher chance of being suppressed in a highly acidic environment.

The size of food particles can affect the physiological and morphological characteristics of the gastrointestinal tract and therefore the microbial state.

• Granulation

• Extrusion

• Expansion 

 

The principle behind these processes is the agglomeration of small particles into larger particles by means of mechanical compression combined with  moisture application, heat, shear forces and vapor pressure.

Most salmonella and coliforms can be removed with granulation at temperatures above 80 °C. On the other hand spore-forming bacteria are resistant to the granulation process at temperatures as high as 90 °C.

 

The most crucial stage for recontamination of the processed food is during the cooling stage. Due to the large volume of air that passes through the coolers and the dust collected at this point, there is a greater probability for contamination to occur.

The diversity of the microbiota in an intestinal section  partly reflects the type of nutrient substrates in that area. The gastrointestinal microbiota gets most of its carbon and energy from luminal compounds (dietary and/or endogenous), which are resistant to digestive fluids or they are so slowly absorbed by  the host  that bacteria can  successfully compete for them.

Since bacterial species differ in their substrate preferences and growth requirements, the chemical composition and structure of intake largely determine the distribution of bacterial species within the gastrointestinal tract.  

As mentioned before, HTP improves nutrient digestibility.

Studies revealed that heat treatment of cereals for piglets (corn and barley) and steam  granulation increased the yield of post-weaning growth and changed intestinal fermentation profiles. Authors explained that granulated diets stimulate the secretion of mucins which facilitate the colonization of Salmonella.

POULTRY

An in vivo experiment  showed that birds fed granulated diets had  significantly higher concentrations of Salmonella enterica serovar Typhimurium DT12 in their gastrointestinal tract compared to those fed with meal (“mash”)

In fact, studies have shown that feed granulation increases the incidence of Salmonella in the gizzard and ceccum  content of growing broilers. Which demonstrates that the gizzard can be an  important critical control point to reduce Salmonella contamination in broilers.

 

The benefits of feed processing in economic terms and in regards to animal performance are unquestionnable.

 

Concerns related to aspects such as granule quality, nutrient digestibility, protein denaturation and milling efficiency will continue to stimulate innovation in feed manufacturing.  The possibilities of decreasing the intensity of particle crushing during granulation, by varying parameters of the granulation process, are very limited.

Therefore, with the evolution of pig and poultry production practices, food processing regimes are no longer  appreciated only in terms of optimizing nutrient utilization, but also in terms of their impact on:

• The hygienic state of food.
• The effectiveness of food additives
• Animal health.
• Food security.

 

Summary excerpt of the article : Frontiers in veterinary science. Role of Feed Processing on Gut Health and Function in Pigs and Poultry: Conundrum of Optimal Particle Size and Hydrothermal Regimens.