Written by: Ashley Wagner, Ph.D., Director of US Business & Technical Sales Probiotech International Inc.
Weaning is a highly stressful event for pigs.
Intestinal health is crucial for pig well-being and performance.
CCC, a blend of monoterpenes and polyphenols, can mitigate weaning stress.
Improved intestinal health through CCC leads to better pig performance.
Trial Report: Impact of CCC on impaired intestinal integrity due to weaning
Pigs experience environmental, physiological, and social challenges even under the best management practices in today’s pig production systems. These challenges elicit a stress response in the brain that signals biological systems away from homeostasis. The severity of the challenge will result in differing impacts to the animal. For example, a social challenge may be mixed in open pen gestation and could lead to aggressive behaviors that may have no economic bearing or could be severe enough to lead to mortality. Although there are several challenges in today’s pig production systems, weaning is by far the greatest challenge and most stressful period for the animal. This is because weaning encompasses many stressors into a single event.
Beyond the role of digestion and absorption, the intestines operate as a defense mechanism against pathogenic bacteria and toxins. The intestinal barrier functions through physical, chemical, and immune protective mechanisms. The physical barrier comprises epithelial cells and the tight junction protein complexes (Figure 2) that selectively allow the absorption of nutrients while preventing access to pathogens and toxins. The chemical barrier prevents the colonization of pathogens via antimicrobial proteins and mucins secreted by the epithelial and goblet cells, respectively. The intestinal immune barrier protects the animal by recognizing foreign stimuli at a local level. Weaning impairs intestinal integrity, compromising the intestines’ ability to perform these barrier functions.
Alterations to the physical barrier following weaning have been well-examined in pigs. Researchers have different tools to determine the integrity of the physical barrier of the intestines. The use of the Ussing chamber system has allowed researchers to evaluate intestinal permeability by measuring transepithelial electrical resistance (TER; Smith et al., 2010). This system takes living intestinal tissue harvested from pigs, allowing researchers to examine transport barrier function and leaky gut in real time. Leaky gut occurs when there is an impairment to the intestinal physical barrier (Figure 3). Another tool researchers have is measuring the protein or mRNA expression level of the tight junction protein complexes from intestinal tissue samples. A lower expression or level of protein indicates a leaky gut. Weaning stress alters intestinal TER (Boudry et al., 2004; Smith et al., 2010; Hu et al., 2013) and decreases the expression of the following tight junction proteins: ZO-1, occludin, claudin-1, and -3 (Boudry et al., 2004; Hu et al., 2013; Cao et al., 2018).
Weaning as an event causes the pig to experience environmental, physiological, and social challenges. This alters the production of neurotransmitters utilized to signal from the brain to other biological systems that there is a stress event. There is a reduction in the amount of serotonin (a neurotransmitter involved in sleep, hunger, and general good feelings), and an increase in norepinephrine and epinephrine which work together to mobilize the body for fight or flight. This alters normal biological systems from homeostasis. Additionally, there is a rise in the stress hormone cortisol, which aids in altering normal body functions. These neurotransmitters signal many other pathways that there is a challenge (weaning), which eventually leads to alterations in digestion, absorption, and the barrier function of the intestines previously described.
So, how do we overcome what the body naturally does to set these pigs up for a successful transition during weaning?
CCC
CCC (Essential Ag Solutions, Sioux Falls, SD) is a blend of monoterpenes and polyphenols expertly selected for their anti-anxiety, anti-depressant, and antioxidant properties. Monoterpenes and polyphenols are compounds found in many plants, such as herbs (oregano, eucalyptus) and fruits (citrus and grapes). Monoterpenes are volatile compounds made up of terpene isomers. These compounds’ volatility produces an aroma that alters brain signaling. This effect is amplified when animals both smell and consume monoterpenes. This blend of compounds in CCC increases serotonin production (Perveen et al., 2009) while decreasing circulating cortisol production during a stress event such as open pen gestation (Brown et al., 2017). Together, this lowers the systemic stress response on other biological systems.
We recently completed a trial to evaluate CCC’s impacts on pigs’ intestinal integrity following weaning. This trial utilized 1296 weaned pigs from the same sow farm. Pigs were fasted during a 1-hour transportation to a commercial wean to finish the research facility. Pigs were assigned to either a control or CCC treatment: 24 pens per treatment and 27 pens per pen. Nine pigs per treatment were sacrificed on day 7 for ileum sample collection to determine tight junction gene expression. Initial body weights did not differ between treatments, but d 7 body weights were heavier in the CCC group. There was also an improvement in body weight gain during the first seven days for CCC pigs over the control. The day 7 gene expression for the tight junction proteins ZO-1, Claudin-1, -2, and -4 was elevated in the CCC group compared to the control by 49%, 151%, 232%, and 192%, respectively. The combined results of improved intestinal integrity and higher body weight at the end of 7 days indicate the ability of CCC to assist the weaned pig in a successful weaning transition.
Weaning stress is a challenge that all pigs endure. As a producer, the goal is to get them thriving quickly. This will enhance profits as well as the animal’s performance. By reducing the perception of weaning stress with CCC, intestinal integrity is less impaired. This may reduce the susceptibility to additional challenges (microbial) that may further impair performance. CCC is the key to getting over the weaning slump. Ask your Essential Ag Solutions representative about CCC; it is available in both liquid and feed form.
Written by: Manuel Contreras, DVM, MS, Diplomate ACPV, Agrimprove/Special Nutrients
KEY TAKEAWAYS:
Endotoxins are only present in Gram-negative bacteria.
Endotoxins can affect commercial poultry when some bacterins are injected without following the manufacturer’s instructions.
There are not many scientific reports currently reporting impaired performance, lesions, and symptoms associated with the presence of endotoxins in Poultry.
The importance of endotoxins in poultry production is a new topic frequently covered in animal production and veterinary medicine technical magazines worldwide. Marketing campaigns are, in part, responsible for this trend. Some commercial/technical articles show the effect of several mycotoxin binders against endotoxins. Reviewing some of these reports, we quickly detected the absence of measurements indicating that endotoxins were present in the evaluated animals. Therefore, it is worth asking how we can associate performance improvements when using these additives if, during the trials, the presence or reduction of endotoxins was not reported. We fully understand that a significant limitation in detecting endotoxins is the lack of availability of reliable laboratory tests in blood, urine or feces. So far, the techniques available are inaccurate, and the interpretation of the results tends to confuse researchers. In the last decade, we have evaluated the results of field tests carried out in pig farms in the European Union, where endotoxins were suspected of causing production deficiencies. In this case, a mycotoxin binder was evaluated to ameliorate the poor performance reported.
Although a statistically significant effect was reported in various production parameters when using the additive, it was not clearly established that its inclusion in the feed caused the changes.
What are endotoxins?
Endotoxins are used to describe a complex containing lipopolysaccharides (LPS) associated with the outer membrane of bacteria such as Escherichia coli, Salmonella, Pseudomonas, and Pasteurella.
Gram Negative bacteria have a cell envelope that contains three layers or membranes:
Cytoplasmic membrane (interior)
Peptidoglycan membrane or R layer
Outer membrane
Since Gram-positive bacteria do not have an outer membrane, endotoxins are not present.
How are endotoxins released?
1. Production during the initial bacterial growth phase, both in the laboratory (in vitro) and in animals (in vivo).
Through this mechanism, minimal amounts of soluble endotoxins are released. It is important to emphasize that for this growth and release to occur, a liquid medium is needed. Once released from the cell wall, an immune response is initiated that depends on the type and concentration of LPS, duration of exposure, host genetics, and the presence of clinical signs caused by viral or bacterial infections.
2. Destruction (lysis) of bacteria by the immune system or antimicrobial agents.
Since the intestines are loaded with Gram-negative bacteria, they represent animals’ most significant source of endotoxins. Its elimination in the feces allows it to combine with food and form a bioaerosol that can stimulate an inflammatory response in the respiratory tract. In experimental tests, when performing intra-tracheal inoculation of endotoxins in broilers, hypertension of the lungs was reported, and it is speculated that it may play an essential role in the development of ascites.
To emphasize the excellent dissemination capacity of this bio-aerosol in commercial poultry production, the same type of endotoxin present in birds has been detected in the blood of farm personnel.
The most important bacteria containing endotoxins belong to the group Enterobacteriaceae, which inhabits the normal intestinal microflora of birds and mammals (including humans).
Composition of LPS:
Lipid A
Nucleus
O antigen
Lipid A is a hydrophobic structure not mixed with water and is associated with toxicity. It acts as an anchor when bacteria invade the host’s cells. Even though endotoxins differ, Lipid A is always the same regardless of the bacteria. This factor explains why endotoxins from different bacteria cause the same type of damage in the host.
When animals are exposed to a stressful environment, the concentration of free endotoxins in the body increases. Once the balance established in the intestinal microflora is lost (dysbacteriosis or dysbiosis), the result is the development of Salmonellosis and/or Colibacillosis. In other words, the absence of some beneficial bacteria, such as Lactobacillus, will allow pathogenic bacteria to grow in the intestines.
It is essential to differentiate endotoxins from exotoxins. Gram-negative and Gram-positive bacteria produce the latter and mainly affect the host. Unlike endotoxins, exotoxins are secreted by bacteria in small amounts and are lethal.
Can endotoxins cause harm to commercial birds?
Deleterious effects have been observed when injecting bacterins prepared with Gram-negative bacteria for decades. Scientific publications have shown that by injecting small concentrations of endotoxins from Pasteurella multocida in broilers, the clinical signs of acute cholera can be reproduced without the need to challenge using the whole bacteria. The best example of this type of damage at a commercial level is caused by the injection of bacterins against Fowl Cholera, which depressed birds characterize after its application in pullets during the rearing period.
On the other hand, the reactions at the application site are significant due to condemnations at the slaughterhouses, especially when using oil emulsions. A recommendation by biological companies that illustrates the importance of endotoxins when vaccinating is to keep vaccines at an average temperature of approximately 37 ºC. Overheating will release the endotoxins present in the vaccine, and mortality and hemorrhagic syndrome could occur.
Photo 1. Local reaction at the application site of a bacterin injected into the neck of a 12-week-old commercial pullet, probably caused by endotoxins (LPS). The photo was taken at 18 weeks and shows yellowish caseous material of bacterial origin due to needle or syringe contamination.
How are endotoxins prevented? Determining if they are harming birds before investing in prevention is critical. The following strategies can be used if a real deleterious effect is established.
Vaccination with endotoxin segments. Lipid A has been used experimentally to obtain protection. The big drawback is the high cost of these products.
Use of mycotoxin binders mixed with the feed (organoclays). In in–vitro tests, about 90% adsorption capacity against endotoxins is reported. However, this does not mean they necessarily work when used in animal feed. Several scientific tests conducted with pigs in the United States, challenged with pathogenic strains of E. coli, have demonstrated the efficacy of some clays in reducing the incidence of diarrhea and poor performance. Although endotoxins are not measured in these reports, it is speculated that part of the efficacy of these products is a consequence of neutralizing the endotoxins released by the bacteria used to challenge.
It is critical to follow the manufacturer’s recommendations when applying bacterins to prevent the impact of endotoxins.
In conclusion, although the adverse effects caused by endotoxins in pigs and dairy cows seem to be more established, their negative impact on poultry is not categorically demonstrated.
Written by: Josep Garcia-Sirera, Special Nutrients Agrimprove
KEY TAKEAWAYS:
Endotoxins have a wide variety of effects on livestock and negatively affect production performance.
Different methods of endotoxin mitigation have been tested, but most are too expensive to be considered in animal production.
A more cost-effective method would be using toxin binders to capture endotoxins in the gastrointestinal tract and prevent them from entering the blood systems.
What are Endotoxins?
Gram-positive and Gram-negative bacteria are differentiated, among other things, by their type of cell envelope. Gram-negative bacteria are encircled by a thin peptidoglycan cell wall that is also enclosed by an outer membrane containing lipopolysaccharides (LPS), also called endotoxins. Gram-positive bacteria do not have an outer membrane; therefore, endotoxins are absent in this group. Gram-negative bacteria have a cell envelope that contains three essential layers or membranes: cytoplasmic (inner), peptidoglycan or R-layer, and the outer membrane. The latter contains phospholipids, proteins, and LPS. On the other hand, LPS consists of three elements: Lipid A, a hydrophobic component that serves as an anchor when a bacterium invades a host’s cell. The core is an oligosaccharide, and the O antigen is a hydrophilic component. Lipid A is apparently responsible for most of the toxicity caused by endotoxins.
Figure 1. Differences between Gram-negative and Gram-positive bacteria
Figure 2. Structure of LPS or endotoxin
Endotoxins are common in the gastrointestinal tract (GIT) of animals, particularly in the large intestine. They are also present in bioaerosols that produce inflammatory reactions, particularly in the respiratory tract. It has been detected that bioaerosols, coming from feed, litter, and feces, have the highest concentration of bacterial endotoxins. When endotoxins are present in the GIT and excreted together with feces, these endotoxins will be attached to the dust particles present in the farm and end up in the air, which causes the inhalation of particles by the animals. As a result, we can observe respiratory or gastrointestinal diseases affecting the animals that inhale them.
Under normal commercial production conditions, a small number of endotoxins will be transferred from the GIT to the bloodstream. According to scientific papers, it represents concentrations lower than ten pg/ml (picograms per milliliter), and these levels are capable of stimulating the immune system. Under stress, the level of free endotoxin in the GIT will be higher. Stress can produce dysbiosis or dysbacteriosis, that is, microbial imbalance in the intestines and the production of more endotoxins in the system. It is critical to emphasize the importance of keeping the correct microbial balance in the intestines because diseases such as Salmonellosis or Colibacillosis are intrinsically associated with the unrestricted growth of pathogenic bacteria that displace the intestinal favorable microflora (i.e., Lactobacillus to mention).
When bacteria are eliminated due to the administration of antimicrobials or because of the work of the immune system, bacterial cells will be destroyed, and the final consequence is the liberation of endotoxins that will harm the animal. Endotoxins are released from the bacterial cell wall during the growth and division phases of the microbe.
Understanding the Mode of Action
The mechanism is complex. In humans, LPS binds to a lipid binding protein (LBP) that moves LPS to the serum to eventually bind with Toll-like receptor-4 (TLR4). This triggers the signaling cascade for macrophage/endothelial cells to secrete pro-inflammatory cytokines and nitric oxide that leads to characteristic “endotoxic shock.”
The injection of living or killed gram-negative cells or purified LPS into experimental animals causes a wide spectrum of nonspecific pathophysiological reactions, such as fever, changes in white blood cell counts, disseminated intravascular coagulation, hypotension, shock, and death. Injection of small doses of endotoxin results in death in most mammals. The sequence of events follows a regular pattern: (1) latent period; (2) physiological distress (diarrhea, prostration, shock); and (3) death. How soon death occurs varies depending on the dose of the endotoxin, route of administration, and animal species. Animals vary in their susceptibility to endotoxin.
Impact on the pig
The effect on production that comes from exposure to endotoxins in swine is a consequence of two factors (Parra et al., 2011):
The inflammatory response translates into alterations in the gastrointestinal barrier, blood circulation, fever, and other symptoms. In 2011, Parra S et al. studied the effects of endotoxins on the morphology of the gastrointestinal gut barrier. Results showed that LPS decreased the height and area of the intestinal villi and increased the width of the villi and the depth and width of the intestinal glands. The authors concluded that these effects probably could contribute to decreased intestinal nutrient absorption and increased co-infection with other pathogens, thus leading to post-weaning diarrhea syndrome. Fever is mediated through the action of IL-6, known to be increased because of exposure to endotoxins. Other symptoms that can be related, even though they have multifactorial causes, would be ear necrosis and lesions that lead to tail biting.
There is a nutrient expense derived from the need for the inflammatory system to be activated. As a result of inflammation, endotoxemia leads, among other things, to a feverish state that results in reduced feed intake. The productive performance of farm animals (i.e., producing milk, eggs, meat, etc.) requires energy and shows a poor feed conversion rate (FCR). The energy required for the inflammatory response will come from the energy used normally for production. This results in lower FCR and decreased growth performance.
J. Parra et al., Lipopolysaccharide (LPS) from E. coli has detrimental effects on the intestinal morphology of weaned pigs. Rev Colom Cienc Pecua Vol.24 no.4 Medellín Oct./Dec. 2011.
Controlling Endotoxins
In general, strategies to control endotoxin contamination in animals are aimed at the reduction of bacterial contamination. These strategies include biosecurity, prebiotics, probiotics, improved nutrient digestibility, etc. Other strategies include vaccination, immunomodulation, and the use of toxin binders scientifically proven to target endotoxins.
Vaccination: Currently, immunization against Lipid A is under development, but the high cost makes it a non-viable option for livestock production. Another option considered in vaccination is to immunize against LBP. By neutralizing the reaction of the LBS-LBP complex, the cascade of events leading to pathogenesis can be reduced. This option is also expensive and is currently only applied for human use.
Immunity modulators: The use of immune modulators to compensate for the effects of endotoxins has been tested in animal production. An example of this immune-modulating action is found in B-glucans present in the yeast cell wall, which can reduce LPS-induced inflammation, though it does not prevent inflammation.
Toxin binders: A more practical approach to reduce the absorption of endotoxins from the gastrointestinal tract of livestock is the use of toxin binders. Toxin binders are widely used to control other toxins, such as mycotoxins. The binder and the mycotoxin form a complex that is too large to be absorbed into the blood system. The complex is then eliminated in the feces. Most mycotoxin binders are hydrophilic molecules (ex., bentonites, aluminosilicates, etc.) efficient at capturing polar molecules such as Aflatoxin. The capacity of these traditional mycotoxin binders to capture more lipophilic-like molecules such as zearalenone or DON is questionable.
Some preliminary studies have already tested the capacity of different toxic binders against endotoxins in vitro. A recent study at the University of Ghent went beyond in-vitro data and effectively proved the capacity of a toxin binder to capture endotoxins in the intestines of piglets. In the study, the authors compared the effect on the production of cytokines by the injection of endotoxins, with or without the addition of the toxin binder. The model was intestinal loops of live piglets.
The data proved that the toxin binder was capable of reducing the cytokine production that results from endotoxin activation of the receptor.
Summary
Endotoxins have a wide variety of effects on livestock, affecting performance parameters. Different means of control of endotoxins have been tested, but most of them are too expensive to be considered in animal production. A cost-effective method would be the use of toxin binders to capture endotoxins in the gastrointestinal tract and prevent them from entering the blood systems. Some studies are underway to test this possibility.
After cleaning, BioPure is introduced to prevent biofilm reformation, benefiting flock health and growth. Data analysis reveals lower mortality rates with BioPure, compared to traditional additives, impacting key metrics like feed intake, weight gain, gut development, livability, and overall weight. The consistent use of the BioClean and BioPure combination emerges as a successful strategy for improving livestock performance, contributing to enhanced financial outcomes for producers.
KEY TAKEAWAYS:
Recurrence of biofilm in the water lines decreases the likelihood of health challenges for livestock relying on these water sources.
Enhances the overall well-being and establishes a proactive resilience that positively influences measures of Livability and Weight.
Water makes up between 70% and 75% of the body mass of broilers and turkeys and is one of the three essentials for Life, along with Food and Air. The quality of the water and the infrastructure used to deliver the water to poultry livestock, therefore, is critically important to the vitality and well-being of flocks throughout the grow-out process. What follows here are numerous data sets that demonstrate that the use of BioPure Probiotic Water Additive in poultry waterlines is a proven means of improving flock performance when the waterline system has been properly prepared by cleaning it out with BioClean Probiotic Biosurfactant Cleaner.
This discussion will be in three parts:
Cleaning waterlines with BioClean
Impact of adding BioPure to the water supply
Where BioClean and BioPure fit it (or not) with conventional practices
Cleaning Waterlines with BioClean
Biofilm that harbors and generates unwanted pathogens in waterlines that can negatively impact a flock’s growth and livability rates represents one of the most significant unseen challenges for producers. Conventionally, chemical additives such as Chlorine Dioxide (ClO2) have been added to waterlines to inhibit the build-up of such biofilms, but do they work?
Consider this example:
NOTE: BioClean does not need to be left in waterlines for 5 days. 24 to 48 hours is sufficient residency to trigger the release.
It is well known that chemical disinfectant and sanitizing products (such as chlorine and chlorine dioxide) do not dismantle biofilm, which is confirmed in this example. So why does BioClean work at releasing the biofilm from waterlines?
Biofilm is made up of two core components:
Protein Junctions
Strands of Polysaccharides
The Protein Junctions hold the Polysaccharide Strands together, much like cement holds bricks together in a brick wall. The probiotics in BioClean (and BioPure) are living entities and need food to survive. The Protein Junctions that hold the biofilm structure together represent an available food source for the Probiotics.
When the Probiotics consume these Protein Junctions, it’s like removing the cement in a brick wall. Once the cement is removed, there is nothing holding them or the wall together, so the wall becomes structurally unstable and collapses.
That is what happened here in this waterline example. The Probiotics in BioClean consumed the Protein Junctions in the unseen Biofilm, triggering the collapse in its structure and subsequent release. So, cleaning out the waterlines with BioClean will deliver superior results and healthier water.
Adding BioPure to the Ongoing Water Supply:
Once the waterlines are clean, preventing Biofilm reforming is critical. Adding BioPure Probiotic Waterline Additive to the water is the solution not just to inhibiting biofilm reformation but also provides demonstratable, proven benefits to flock health, livability, and growth.
Data Set #1 – BioPure vs ClO2 – Average Flock Mortality (Turkeys):
The data used for the chart below came from three commercial turkey barns on the same ranch of the same size and bird population. The water source was also the same.
This chart highlights how when BioPure was added to the waterlines instead of ClO2, the mortality rate dropped to:
only 3% mortality with BioPure vs
over 6% for the flock using only ClO2.
After viewing the significantly lower mortality rate within the first 5 weeks of using BioPure instead of ClO2, this producer decided to switch a 3rd barn from ClO2 to BioPure at week 5. Even though BioPure was not used for the first 5 weeks by switching away from ClO2 to BioPure, the flock in that third barn also saw a significantly lower mortality rate of 4.5% vs 6.5% for the barn using only ClO2. It is also important to note that that the flock using only BioPure achieved harvestable weight earlier!
Data Set #2 – Impact of BioPure vs ClO2 and other water additives (Broilers)
The following data sets came from trials conducted by the University of Arkansas to compare the impact on key metrics by BioPure compared to other common chemical water additives used to maximize bird health and growth, such as ClO2.
BioPure was applied at two different dilution rates:
1:8200 (normal recommended rate) – #3 in all the Uni of Arkansas data
1:1640 (super ratio – used in past on flocks with health issues) – #4 in all the Uni of Arkansas data
Data on the products Z BioScience’s BioPure was being compared with were not provided by the University. The Control flock had nothing added to the water.
Feed Intake and Weight Gain Data:
BioPure at 1:1640 dilution generated:
by far the best Feed Intake and Weight Gain
BioPure at 1:8200 dilution generated:
The 3rd best Feed Intake performance and the 2nd best Weight Gain
Gut Length
Gut integrity and length are critical determinants of both the general health of a bird and its performance.
As this picture clearly shows, using BioPure at both dilutions generated substantially better bird gut development, explaining why BioPure produced superior Weight Gain performance.
Data Set #3 – BioPure vs ClO2 (Turkeys – actual commercial barn data)
A large commercial organic turkey producer compared the performance of BioPure used in 3 different barns to ClO2 being used in 3 other barns.
The key performance metrics measured were:
Livability
Weight
In all instances, the barns using BioPure delivered better Livability and Weight performance.
Data Set #4 – Impact on flocks when BioPure is not used
In this data set the water systems servicing multiple Turkey grow-out barns ran out of BioPure. For the 3 weeks BioPure was not added to the water (weeks 3, 4 & 5 of the grow-out), mortality rates surged by between double and quadruple the levels of when BioPure was available to the birds.
Conclusions:
The outcomes highlighted in Data Set #4 are incredibly important!
Key to any livestock program is building resilience within the animal as a primary means of ensuring maximum performance and the ability to overcome unexpected and unwanted assaults on the health of the animal. Cleaning the water lines with BioClean to remove unwanted pathogens that compromise an animal’s performance is a critical 1st step.
Ongoing use of BioPure delivers two critical components:
It inhibits biofilm reformation in the lines and, in doing so, reduces the risk of potential health assaults on livestock dependent upon those water lines.
The probiotics in BioPure find their way into the guts of livestock, which strengthens their overall health and builds a level of preventative resilience that improves Livability and Weight metrics.
The outcomes displayed in Data Set #4 highlight how BioPure significantly contributes to the resilience of flocks to assaults that increase mortality. Data Sets #2 and #3 highlight how BioPure beneficially impacts weight gain. This makes sense, given the significant additional length in the guts of birds using BioPure in the photo. Combining cleaning waterlines with BioClean and then adding BioPure has consistently contributed to improvements in critical livestock performance metrics that improve the financial outcomes for producers.
Written by: Ashley Wagner (Probiotech International Inc.) & Ethan Groos
What is ‘stress’?
Generally, the term ‘stress’ is used to describe the detrimental effects of a variety of factors on the health and performance of livestock. Stress in birds is characterized by having limited body resources for growth, reproduction, response to environmental changes and defense mechanisms compared to mammals. Thus, any slight deviation from normal conditions leads to the rapid redistribution of body resources including energy and protein, at the expense of growth, reproduction, and health. When these challenges become more intense or occur more frequently, serious chemical and physical changes take place within the bird with far reaching consequences. For example: birds may become fatigued and weak which may lead to starvation and increased susceptibility to infectious diseases. There are common sources of stress in birds, which can be grouped under one or more of the categories defined by Rosales (1984) and summarized in Table 1.
Mammals such as pigs are no strangers to the effects of stress during production. Due to the rapid growth of pigs, there are little reserves to combat stressors, especially during early growth. This combined with environment changes, socialization, and dietary changes, can lead to reductions in performance that are stress-related. The reductions in pig performance can manifest as reduced appetite, increased susceptibility to disease (a physical symptom could be scours), and ultimately mortality.
In addition to the categories of stress mentioned above, all the possible types of stressors experienced by livestock can be broadly classified under two categories: Avoidable stressors and Unavoidable stressors (Mohan, 2005) as presented in Table 2.
Even if the avoidable stressors can be eliminated under efficient management conditions, the load of unavoidable ones at best can only be minimized; thus, stress factors are inevitable events in livestock husbandry. The consequences of the stressors, as previously mentioned, impact performance and economics in all poultry and swine production. Beyond good management practices, what else can be done to alleviate unavoidable stressors?
Can botanicals alter stress-induced behavior?
Botanical blends have been examined in all commercial livestock species to have a wide variety of benefits from supporting gut and respiratory health to brain function, impacting hormones and behaviour. The product CCC is a blend of botanicals and antioxidants that was developed to promote calm and positive-oriented behaviour(s) and improve performance during stress periods (ex. heat, transport, high density, aggressive behaviour, social re-grouping, etc.). Additionally, the compounds in CCC has been shown to alter brain serotonin (Graph 1) or the “happiness hormone” levels. Increased serotonin concentration are directly correlated to enhanced mood, emotion, and appetite. As a result, there are alterations on animal behavior and performance.
Novel Object Test (NOT) in Poultry
Botanical blends have been examined in all commercial livestock species to have a wide variety of benefits from supporting gut and respiratory health to brain function, impacting hormones and behaviour. The product CCC is a blend of botanicals and antioxidants that was developed to promote calm and positive-oriented behaviour(s) (Table 3) and improve performance during stress periods (ex. heat, transport, high density, aggressive behaviour, social re-grouping, etc.).
Post-Mixing Aggression in Pigs
Three hundred thirty-six grow/finish pigs (6 pigs/pen) were either on the control or CCC liquid treatment (200ppm) for three days prior to mixing. Pigs were monitored for fighting threats and lesions. The number and time of each fight or threat and the percentage of pigs per pen with severe lesions were reduced when pigs were on the compounds contained in CCC prior to mixing (Graph 2 and 3).
There are many different stressors livestock face at various life stages. Although some of these are avoidable with good management practices, there are a number that are unavoidable. The functional feed and water additives (CCC) were developed by Probiotech for Essential Ag Solutions based on brain-effect-selected molecules to enhance good management practices and help mitigate the consequences of unavoidable stressors through an improvement in animal welfare. Often, there is a decline in feed intake and increased susceptibility to diseases during times of stress. Because CCC impacts both appetite and mood, these deleterious effects on performance are mitigated during unavoidable stressors. Potential uses in turkey production include but are not limited to, times of heat stress, handling, moving from the brooder barn, and vaccination. Whereas potential uses in swine production are during the nursery period, before and after transportation or mixing of pigs, during sow lactation to impact fertility, and during heat stress. Make sure CCC is a part of your solution to improve performance through mitigating stress in your barns.
