[LEXINGTON, Ky.] – The 2019 Alltech Global Feed Survey, released today, estimates that international feed tonnage has increased by a strong 3 percent to 1.103 billion metric tons of feed produced in 2018, exceeding 1 billion metric tons for the third consecutive year. The eighth edition of the annual survey includes data from 144 countries and nearly 30,000 feed mills. The feed industry has seen 14.6 percent growth over the past five years, equating to an average of 2.76 percent per annum. As the population grows, so does the middle class, which is well reflected in an increase in overall protein consumption.  

The top eight countries are China, the U.S., Brazil, Russia, India, Mexico, Spain and Turkey. Together, they produce 55 percent of the world’s feed production and contain 59 percent of the world’s feed mills, and they can be viewed as an indicator of the trends in agriculture. Predominant growth came from the layer, broiler and dairy feed sectors.  

“Alltech works together with feed mills, industry and government entities around the world to compile data and insights to provide an assessment of feed production each year,” said Dr. Mark Lyons, president and CEO of Alltech. “We are proud to present the eighth annual Alltech Global Feed Survey and share the results publicly to demonstrate the importance of the animal feed industry as we strive to provide for a planet of plenty.”  

The Alltech Global Feed Survey assesses compound feed production and prices through information collected by Alltech’s global sales team and in partnership with local feed associations in the last quarter of 2018. It is an estimate and is intended to serve as an information resource for policymakers, decision-makers and industry stakeholders. 

Regional results from the 2019 Alltech Global Feed Survey 

• North America: North America saw steady growth of 2 percent over last year due to an increase in the major species, with beef and broilers leading the growth at 3 percent each. The U.S. remained the second-largest feed-producing country globally, behind China. Feed prices in North America are the lowest globally across all species, and with the availability of land, water and other resources, the region is expected to remain a primary contributor to feed production.  

• Latin America: As a region, Latin America was relatively stagnant this year. Brazil remained the leader in feed production for the region and third overall globally. Brazil, Mexico and Argentina continue to produce the majority of feed in Latin America, with 76 percent of regional feed production. Brazil stayed flat, while Mexico and Argentina saw growth of 1 percent and 4 percent, respectively. Colombia’s feed production grew by approximately 8 percent, primarily due to an increase in pork and egg production. Several countries saw a decline in feed production, such as Venezuela (-27 percent), El Salvador (-16 percent) and Chile (-8 percent).  

• Europe: Europe saw an overall growth of about 4 percent over last year, making it the second-fastest-growing region in the survey, resulting from feed production increases in layer (7 percent), broiler (5 percent), aquaculture (5 percent), dairy (4 percent) and pig (3 percent). Beef was the only primary protein species to decline, though it was less than 1 percent.  

Much of the region’s growth can be attributed to smaller countries, such as Turkmenistan, Macedonia, Azerbaijan, Montenegro, Kazakhstan and Uzbekistan, which all saw increases in overall production estimates of 20 percent or more. Additionally, larger-producing countries like Russia, Spain and Turkey saw strong increases in feed production estimates, which added to the overall production growth.  

• Asia-Pacific: The Asia-Pacific region is home to several of the top 10 feed-producing countries, including China, India and Japan, and accounted for more than 36 percent of the world’s feed tonnage. China maintained status as the top feed-producing country in the world with 187.89 million metric tons, with 10 million metric tons more than the U.S. Increased production for Asia-Pacific came from India with 13 percent due to growth in dairy, layer and broiler feeds. Other countries that demonstrated higher growth variance included Pakistan, Myanmar and Laos. Southeast Asia’s feed production represented over 20 percent of the Asia-Pacific region’s feed production, with Indonesia, Vietnam, the Philippines and Thailand contributing to 93 percent of Southeast Asia’s feed production.  

• Africa: Africa continued strong growth with a 5 percent increase in overall feed production, and no country in the region saw a decline. Morocco demonstrated strong growth across dairy, beef, layers, broilers and turkeys. The areas that declined for feed production were equine (-4 percent) and pets (-14 percent). These two areas represent a very small proportion of Africa’s overall production, so the impact is very minimal. Most of the major animal production species in ruminant and poultry contributed to the overall growth of the region. 

Notable species results from the 2019 Alltech Global Feed Survey  

• In the poultry industry, major growth areas for layer feed included Europe, Latin America and Asia-Pacific. In Europe, Poland and Uzbekistan each saw growth of around 200,000 metric tons. Latin America had increases in Colombia, Peru, Brazil and Mexico. In the Asia-Pacific region, South Korea, India and Indonesia all saw growth of several hundred metric tons. North America experienced overall growth of 2 percent, in which both the U.S. and Canada saw increased production. Africa saw a small decrease in layer production due to declines in both Egypt and Seychelles. 

Globally, broiler production increased by approximately 3 percent in 2018. There was growth in all regions, except for Latin America, in which a very small decline was observed. Africa showed 9 percent growth, demonstrating an overall trend that as populations grow and become wealthier, interest in protein — particularly in palatable chicken — does as well.  

• Pig feed production saw an increase of nearly 1 percent in 2018. The primary producing region for pig feed is Asia-Pacific, but this was also the only region that saw a decline in pig feed production as Mongolia, Vietnam, China, New Zealand and Japan experienced decreases. From a tonnage standpoint, Europe saw the largest growth at approximately 2.2 million metric tons. Russia and Spain accounted for the majority, while Finland, Denmark, France and Poland also contributed. Latin America saw the greatest growth in pig feed as a percentage at 5 percent, with the largest growth seen in Mexico and Argentina. 

• Global dairy feed production saw growth in North American, Europe and Africa, while Latin America remained flat. Europe, a global leader in dairy production, grew on average by approximately 4 percent. The largest increase was in Turkey with 10 percent, while Ireland, Russia and the U.K. also contributed to the region’s growth. Africa’s growth was primarily due to a significant increase in both Morocco and Nigeria.    

• North America has always led beef feed production and continues to do so with an increase of 3 percent in 2018. Europe saw a small decline at barely 1 percent and remained in second place. Latin America saw strong growth of approximately 8 percent, with Mexico and Argentina as the primary contributors. As a result, the Latin American region has taken third place in beef feed production, moving ahead of the Asia-Pacific region.  China and Australia both saw growth in the Asia-Pacific region but could not offset the overall decline in countries such as Bangladesh, Mongolia, Indonesia, Taiwan, Vietnam and Pakistan. 

• Overall, aquaculture feeds showed growth of 4 percent over last year. This was primarily attributed to strong increases in the Asia-Pacific and European regions. The traditional Asia-Pacific leaders in aquaculture, Vietnam, India and Indonesia, combined for an additional 1.58 million metric tons of feed in the region. China, the region’s leader, also saw an increase of 1 percent over last year. The primary European leaders either experienced strong growth or remained relatively flat. Those that did grow included Norway and Turkey, both at 7 percent, and Spain at a substantial 31 percent. The other regions remained relatively flat or saw only a 1 percent increase or decrease in feed production, demonstrating the continuity of the industry as a whole.  

• The pet food sector saw growth of approximately 1 percent, primarily attributed to an increase in the Asia-Pacific region, which was offset by a decrease in the Latin American and African regions. North America and the Middle East both remained relatively flat. In previous surveys, Europe had been the top-producing region for pet food production, but after a reassessment of 2017 numbers and despite growth of 2 percent, it ranks just behind North America. Europe is estimated in 2018 to have produced 8.6 million metric tons in total, approximately 200,000 behind North America. Africa saw a small decrease in production, but the actual tonnage is quite small compared to many of the other regions. The Latin American region experienced a decrease of about 5 percent, which was spread across several countries, including Chile, Venezuela, El Salvador, Colombia, Argentina and Ecuador. 

To access more data and insights from the 2019 Alltech Global Feed Survey, including the results booklet, an interactive global map and a pre-recorded video presentation of the results by Dr. Mark Lyons, visit alltechfeedsurvey.com.

Alltech now collects data from 144 countries and nearly 30,000 feed mills to compile its annual Alltech Global Feed Survey. This data collection is a major undertaking, made possible only through Alltech’s global reach.

However, the real work (and fun!) begins when all the data is received, and we have the opportunity to dig deep for insights and trends. We seek to answer the following questions:

Which countries are growing the fastest? Which species saw declines in production? Are any major players slowing down? What are the surprises?

The data presents seemingly endless opportunities for comparison, and we’ve decided to share 18 of the facts we’ve found most interesting from our 2018 data. Perhaps this will serve as “food” for your next dinner conversation!

1. The top eight countries produce 55% of the world’s feed production.
2. Vietnam saw an increase of nearly 1 million metric tons of aquaculture feed, contributing to the estimated 6% growth of the Asia-Pacific region’s aquaculture feed production in 2018.
3. Morocco saw the largest growth of any country in Africa thanks to the addition of two new feed mills as well as an extension to an existing feed mill late last year.
4. Although not typically known for its pig production, India took a big leap in pig feed production in 2018. Why? The industry is trending toward more organized farming in areas like Kerala and Punjab, with new feed millers contributing to this growth.
5. Where’s the beef? Feed production for beef was stagnant this year. Not only that, but the third-largest producing region, Asia-Pacific, dropped enough to let Latin America step up and take the bronze.
6. Southeast Asia’s feed production represents over 20% of the Asia-Pacific region’s feed production. Indonesia, Vietnam, the Philippines and Thailand carry most of the weight and contribute to 93% of Southeast Asia’s feed production.
7. Showing 7% growth last year and 13% this year, India is clearly growing its feed production at a rapid clip, not just in one, but in all species! From aquafeed to goat grains, India’s feed production increased across all 13 categories we assess.
8. The European Union (EU) countries contribute to more than 50% of all major species feed production in Europe (with the exception of aquafeed).
9. Norway is Europe’s largest producer of aquafeed, contributing 45% of the region’s total aquafeed production.
10. Layer feed grew by 4% globally, indicating a growing need and continued interest in this efficient protein source.
11. After years battling African swine fever, Estonia is back in the game, showing a more than three-fold increase in pig feed production over last year.
12. Eighty percent of European turkey feed production occurs in the EU.
13. Higher costs of corn and soy reduced Brazil’s broiler feed production by 2%, eating away at the entire region’s total and making Latin America the only region to see a decrease in broiler feed production in 2018.
14. Dairy showed growth in all regions, indicating the ongoing affinity for this protein source.
15. Africa’s feed production grew the most of any region at 5%. Expected to have one of the fastest-growing populations, how will this region farm in the future? Will it embrace conventional farming or leapfrog other methods and embrace Agriculture 4.0?
16. Turkey feed saw a big leap in Spain with an additional 300,000 tons of feed estimated in 2018.
17. Pet feed reassessed: It turns out Europe is not the primary producer as originally thought! North America leads by about 200,000 tons of feed, making it a close race. With a renewed focus on value rather than volume in the pet food sector, who will lead in 2019 and beyond?
18. Insect protein is working its way into aquaculture feed production. It’s possible Alltech will include this new alternative feed source in future surveys!
19. The North American regions continues its steady course of 2% growth; the biggest contributors to this increase were beef and broiler each at 3%.

These quick facts are just a few of the insights we can derive from the Alltech Global Feed Survey. To discover more from the 2019 Alltech Global Feed Survey, including the results booklet, an interactive global map with information from each country and a presentation of the results, visit alltechfeedsurvey.com. 

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The following is an edited transcript of Tom Martin's interview with Dr. Raj Kasula. Click below to hear the full audio:

Tom:            Raj Kasula is a poultry technical consultant at Ridley Feed Ingredients. A certified professional animal scientist for poultry via the American Registry of Professional Animal Scientists, he has more than 28 years of experience in multispecies animal nutrition with a focus on poultry. He is currently spearheading the development of a modern version of layer nutrition software called the Alltech Poultry Model. He is also the Alltech lead on projects such as the Alltech Egg Squad, poultry blocks, a natural de-wormer, extruded chicken starter feed and vitamin organic trace mineral premix. We thank you for joining us, Raj.

Raj:              Thank you. My pleasure.

Tom:            Are consumers becoming more critical of egg quality? What are they looking for in an egg?

Raj:              At the consumer level, they are probably not so critical about the eggshell quality. However, they are interested in egg quality in the sense that they walk into the superstore, then they're looking for a selection of eggs, from a regular commercial egg to a pasture-raised or organic to enriched eggs, in terms of pigment or omega-3 or selenium or vitamin E. So, yeah, they're definitely looking for quality and value from the egg as compared to just the traditional belief of “an egg is an egg is an egg.”

Tom:            I'm curious, because I know most of us mainly check to see if the eggs are cracked, but what does somebody with your expertise look for when you go to the grocery store to buy eggs? Or do you have another source?

Raj:              Yeah, being in the industry and working so closely with the birds and eggs, my way of looking at eggs will be really different. Certainly, I do look for the total quality in terms of external parameters of the egg: the shape, the color, the strength (like any cracks on it), how clean it is and how glossy it is, because from each of those parameters, I can read what the hen is about, what is going on with the hen. So, definitely, yes, my look will be totally different.

Tom:            It would be interesting to take Raj Kasula along with us to the supermarket now and then! From a producer perspective, what are the characteristics of superior eggshell quality?

Raj:              From the producer's perspective, among the eggs that don't make [it] to market, about 90 percent of them are due to the poor shell quality. A producer is producing the eggs to make money, and he doesn't make money unless those eggs make it to the market. So, to see any returns, he has to get the egg into the market, and if the shell is not good — doesn't show good color, good shape; it’s not hard enough, the egg cracks, are dirty — they're not going to make [it] to market. That’s the problem in about 90-plus percent of the cases where the eggs don't make [it] to the market.

Tom:            I mentioned that, for the average consumer, we open up the carton and we look to see if they're cracked, and that's kind of how we make our decision, but how significant is an egg breakage? Are there ways, through nutrition, to strengthen the shell to prevent cracking?

Raj:              Eggshell breakage is actually a natural phenomenon, I should say. As the bird is growing older, the size of the egg increases. The shell gland’s capability of depositing calcium on an egg remains the same. It's able to deposit only the same amount of calcium on the egg. So, when the egg is growing bigger, it's tilling out on the egg. That’s how it becomes a bit soft and breaks; it can crack. There is a natural phenomenon, but then, there are ways — by nutrition and management — we can try to minimize that.

Tom:            And is there a certain point in the bird's life-cycle when the producer should start thinking about egg development and about eggshell quality?

Raj:              Typically, anywhere about 45-50 weeks of age. If the producer has been in the business and [is] seasoned enough, he would know that he has to take some additional precautions with his nutrition and management toward the eggshell quality, and it usually happens.

Tom:            Do you recommended a general nutritional strategy, or does it vary from farm to farm, types of birds to types of birds?

Raj:              It’s pretty general, although there are some minor differences depending on the type of farming, such as cage-free or organic or free-range, and the specialty eggs. There are some different strategies for those.

Tom:            So, what sorts of nutritional additives, such as vitamins and minerals, have proven effective in ensuring superior external and internal egg quality?

Raj:              Yeah, let me talk about the external quality first. For the external quality, especially the shell strength, calcium is the key. It is very important to make sure that you provide all the things required by the bird's physiology to absorb calcium from the gut — these levels of calcium, levels of phosphorous — because calcium and phosphorus work together. It is proven that phosphorus, at very high levels beyond the point of production, is not really good for the shell quality. There is another mineral called magnesium, which is also important, that gives the strength to the shell quality, helping the calcium minerals to get on the shell.

                    On top of that is vitamin D, which is important for absorption of calcium from the gut. Vitamin D actually enhances the cell — the interstitial cells — of pigs from the gut to digest the calcium. So that is very important.

                    And then, the trace minerals are very important, because although those are small in quantity — very tiny amounts are required in the ration — when you look at it on the ration, you feel like, “Oh, these are tiny amounts. Do they really make a difference?” And they really do. So, zinc is important and [is] an enzyme that actually helps in formation of calcium carbonate from calcium from the blood and bicarbonate from the blood.

                    We have manganese that helps in the formation of collagen, which is important for formation of the egg and the shell membrane. Then we have copper for some of the glycoproteins, and those, which are, again, components of eggshell and shell membrane. There is also selenium, which is very important for keeping the health of the interstitial cells so that they can absorb more nutrition rapidly. These are my recommendations for primary placement. These are very important.

Tom:            And you recommend organic, correct?

Raj:              I recommend organic because of the efficiency aspect. The trace minerals in the inorganic form and their application use and benefits have been tested and proven for several decades. But, the current trend is in organic minerals because they are a lot more efficient. If you look at research literature, it says the organic minerals are anywhere between three to six times better absorbed from the gut in comparison to inorganic minerals. This is a lot more efficient, because you're feeding the animal less while getting more, and you're not contaminating the environment — the soil — with minerals that are not absorbed.

                    The biggest disadvantage, I would say, with unabsorbed inorganic minerals is that you are feeding the “bugs” in the hindgut, which we don't want. We really want to keep them suppressed. The moment they get these kinds of nutrients, they are going to be more robust, and they're going to be more aggressive when they get a chance to take over. There is enough research to say that organic minerals perform much better than the inorganic minerals — even at lower levels — and on a sustainable basis.

Tom:            Is what's good for the shell also good internally? Are there different or additional additives, minerals, vitamins, that have to be considered for internal health? Do you also have to think about interactions between those?

Raj:              If you're talking about the internal quality of the egg, there are some minerals within the egg mass that are the same as the minerals needed for external shell quality. There are additional considerations for the quality of protein and some of the vitamins and if the producer is focusing on the color of their egg yolk —a darker pigment. If it is a specialty egg enriched with omega-3, omega-6, selenium or vitamin D, vitamin E, those are additional strategies and technologies that you would use to make sure you get them inside the egg yolk.

Tom:            And you've mentioned calcium. Is there something about the size of the calcium particle that's important to consider?

Raj:              Yes, there is. For calcium, the main source in the rations is limestone. There is research showing that limestone is available in many sizes of fine, medium and coarse. The research shows that, when limestone is used as larger particles — especially in the older laying birds — when the birds start laying, they require a sustained release of calcium. If the particle size is too fine, it gets dissolved and absorbed very quick, and it gets excreted also very quick, so there is not a continuous or sustained level of calcium. A larger particle dissolves slowly and gives a sustained level, so the bird is able to calcify the shell during the dark period of the night when she is not eating. That is very important.

                    The larger particles of limestone will also help us in grinding the ration, the nutrients, the feeding grain that it's consuming and liberating nutrients and preventing the digestion for further attack by the good acids and enzymes at subsequent stages.

Tom:            Okay, let's move on to looking at some of the more common problems being encountered by egg producers today. What would you say those are?

Raj:              The disease aspect is very complex and varies from market to market. But in general, as a producer and as a nutritionist, the most common one is the shell quality. There are also behavioral issues, such as pecking. The birds start pecking each other and they end up killing each other — cannibalism. These are some of the issues we commonly find. There are cases where you also find issues with worms; especially when birds that have access to the floor and outside, they end up picking up some of the worm eggs [which] develop inside, and those cause severe production losses.

Tom:            In very recent years, we've seen some spikes in mycotoxins in silage and barlage, in particular, in this country. Are egg producers concerned about mycotoxins?

Raj:              Sure, they are, because mycotoxins are something nobody would like to take a risk with. They are not easily seen; you cannot necessarily determine by sight if a particular ingredient — say, corn, or what have you — has mycotoxins or not. It isn’t visible to the naked eye. So, the best approach would be, like, we do insurance: always have a mycotoxin-binding or a mycotoxin-countering technology built into the ration. Typically, all nutritionists do that.  

Tom:            Tell us about the layer nutrition software that you're working on right now.

Raj:              Okay, the layer nutrition software I'm working on is called the Alltech Poultry Model. This is a software modeled to a particular breed — any breed — based on its life cycle, the way the breed would behave, the modes of ration, and what levels of nutrients are required based on its production and body maintenance. It also takes into consideration the environmental parameters, such as the highest temperature and lowest temperature and the amount of feed the bird is consuming.

                    This software gives a very good idea of the levels of nutrients the bird needs for whatever she's doing at that particular point of time we are evaluating it. So, when we're entering these parameters and the ingredients available, the software will tell you, “Okay, this is what this bird needs, and this is how the ration should be.” It’s then left to the nutritionist to take a look and approve it or make any tweaks needed.

Tom:            Are there any emerging trends, any new technologies in poultry, that have captured your attention and your interest?

Raj:              Yes, lately, in the U.S. at least, I would say the trend is with the cage-free, organic and free-range. Also, the specialty eggs enriched with pigments, omegas, vitamin D, vitamin E. These are all the trends coming up and people are moving toward. I would say they are adding to their range a niche segment, a niche set of products, eggs with these kinds of specialized enrichments. That is something I have seen. Especially, the organic production is picking up much faster than what we usually thought. So, these are the trends, I would say.

Tom:            Raj Kasula is a poultry technical consultant at Ridley Feed Ingredients. We thank you so much for spending time with us, Raj.

Raj:              Thank you, Tom. My pleasure.

I want to learn more about supporting health and profitability in my poultry production. 

Winners Tammy Wiedenbeck from Lancaster, Wis.; Rachel Ezzell from Waxhaw, N.C.; Jacob Pierce from Waxhaw, N.C.; and Katie Edmondson from Cortez, Col. were selected by public voting on Facebook

[LEXINGTON, Kentucky] – The Alltech #iamAG online agvocacy photo contest showcased the beauty of American agriculture through the eyes of producers, who submitted and shared photos of their farms for the opportunity to win a trip to ONE: The Alltech Ideas Conference (ONE19), to be held in Lexington, Kentucky, on May 19–21, 2019. 

The winners of the Alltech #iamAG photo contest are:

• Tammy Wiedenbeck from Lancaster, Wis. (photo)
• Rachel Ezzell from Waxhaw, N.C. (photo)
• Jacob Pierce from Waxhaw, N.C. (photo)  
• Katie Edmondson from Cortez, Col. (photo)

The submitted photos were posted on Alltech’s Facebook page (Facebook.com/AlltechNaturally) for public voting. Winners and a guest each received free registration to ONE19 and $2,000 for travel expenses.

General registration is now open for ONE: The Alltech Ideas Conference, held in Lexington, Kentucky, USA, from May 19–21, 2019. The annual international conference draws 4,000 attendees from nearly 80 countries to network and discuss world-changing ideas. For more information or to register, visit one.alltech.com. Join the conversation online with #ONE19.

-Ends-

Contact: press@alltech.com

Jenn Norrie

• Communications Manager, North America
• jnorrie@alltech.com; (403) 863-8547

Photo Caption:

Tammy Wiedenbeck from Lancaster, Wis. has won a trip to ONE: The Alltech Ideas Conference in Lexington, Kentucky, USA, for their #iamAG photo.

Photo Caption: 

https://photos.alltech.com/pf.tlx?KvMKg0Kp_XeA

Photo Caption:

https://photos.alltech.com/pf.tlx/7879y7YA833

Jacob Pierce from Waxhaw, N.C has won a trip to ONE: The Alltech Ideas Conference in Lexington, Kentucky, USA, for their #iamAG photo.

Photo Caption:

https://photos.alltech.com/pf.tlx/tQyt4otU.iqpGt

About Alltech:

Founded in 1980 by Irish entrepreneur and scientist Dr. Pearse Lyons, Alltech discovers and delivers solutions for the sustainable nutrition of plants, animals and people. With expertise in yeast fermentation, solid state fermentation and the science of nutrigenomics, Alltech is a leading producer and processor of yeast additives, organic trace minerals, feed ingredients, premix and feed.

Our guiding ACE principle seeks to develop solutions that are safe for the Animal, Consumer and the Environment. Our more than 6,000 talented team members worldwide put this purpose to work every day for our customers.

Alltech is a family-owned company, which allows us to adapt quickly to emerging customer needs and to stay focused on advanced innovation. Headquartered just outside of Lexington, Kentucky, USA, Alltech has a strong presence in all regions of the world. For further information, visit www.alltech.com/news. Join us in conversation on Facebook, Twitter and LinkedIn.

Though historians may disagree on the exact timeline of the first U.S. Thanksgiving — and it is unknown whether turkey was even on the menu back then — the annual tradition of consuming this uniquely American bird on the fourth Thursday in November eventually caught on, and Thanksgiving was officially declared a national holiday by President Abraham Lincoln in 1863.

The official "pardoning" of White House turkeys, however, didn’t get its start until much later. The National Thanksgiving Turkey Presentation began in 1947 under President Harry S. Truman and carried on over the next few decades, with presidents occasionally sparing the birds from their dinner table fate to live out their remaining days on farms or in zoos instead. It wasn’t until 1989 when, during his first year in office, President George H. W. Bush decided to instill a permanent Thanksgiving poultry pardon, thus resulting in the tradition that has carried on annually for 29 years.

How it works

Each year, shortly before Thanksgiving Day, the National Turkey Federation (NTF) organizes the presentation of a live bird to the current U.S. president. The NTF chairman receives a formal White House invitation and arrives with two turkeys in tow, and though one bird is official and the other is considered a back-up, both go on to a life of leisure after their presidential pass.

To fulfill the annual pardon, a small flock of Broad Breasted White turkeys is raised each year, typically on the farm of the current NTF chairperson. The birds are rigorously maintained and are even trained to handle the pressures of fame — loud noises, flash photography and crowds — and to stand quietly on a table. Finalists are ultimately chosen for both their looks and their personalities. Their names are then selected by White House staff, who often receive suggestions from schoolchildren residing in the state in which the birds were raised. For instance, the 2017 pair raised in Minnesota were aptly named Drumstick and Wishbone.

While these birds are typically short-lived — the average lifespan of this meaty breed is between three and five years — the pardoned turkeys often go on to spend their golden years at posh digs like George Washington’s Mount Vernon estate. They’ve also previously received new homes at Disney World, Disneyland, a Virginia farm park and a special home for turkeys at Virginia Tech University known as Gobbler’s Rest.

A first-time honor

For the first time ever, South Dakota will have the honor of providing the 2018 White House turkeys. Manager of Riverside Turkey Farm Ruben Waldner, this year’s presidential turkey handler, has raised a special flock of 49 birds and will aid in selecting the lucky duo. During the week of Thanksgiving, the birds will be escorted by Ruben to their special suite overlooking the White House at the four-star Willard InterContinental Hotel, where they will be introduced to the media before being presented to President Trump by Jeff Sveen, chairman of the board of Dakota Provisions and current chairman of the NTF.

As former President Barack Obama mentioned during his final turkey pardon in 2016 — when he kept turkeys Tater and Tot from becoming a Thanksgiving meal — one thing’s for sure: these birds will get to ride the gravy train to freedom.

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The following is an edited transcript of Tom Martin's interview with Dr. Richard Murphy and Dr. Roger Scaletti. Click below to hear the complete audio:

Tom:            Why are we still using inorganic minerals? Why do nutritionists continue to overfeed nutrients and waste money? How can a mineral management program improve the health of the herd? Here to discuss these questions, among others, about the role of minerals in animal nutrition are Dr. Richard Murphy, research director at the Alltech European Bioscience Center in Dunboyne, Ireland, and Dr. Roger Scaletti, who focuses on the technical sales and support of the Alltech® Mineral Management program. Thank you both for being with us.

                    There may be some confusion and contention around the issue of organic versus inorganic minerals and the effectiveness of one over the other. First, Dr. Murphy, a brief primer, if you would, on the difference between organic versus inorganic?

Richard:        That's a great way to start this conversation. I guess it's going to be a fun conversation over the next while! Effectively, when we talk about organic minerals, all we've done is taken the mineral source, we've reacted it with an amino acid or a peptide or some other organic bonding group, and we basically make that mineral protected. Rather than thinking about an inorganic mineral as just being straight mineral, with the organic mineral, we've protected the mineral, and that protection offers us a lot of benefits. Particularly in the intestinal tract, it offers us stability — changing the pH that we would see in the gastrointestinal tract.

                    For instance, at the start of the intestinal tract, the pH is neutral. When it gets into the gastric environment — or the stomach — it becomes very acidic. Those changes in pH can impact amino acid. With the organic mineral, what we're doing is we're bonding it to either an amino acid or a peptide or some other organic molecule, and that protects us as it moves through the GI tract and makes it much more stable.

Tom:            Dr. Scaletti, just to be clear, is the use of organic versus inorganic specific to the production method? In other words, are organic minerals only for organic farms?

Roger:          Another great question. No, organic minerals would be beneficial for any farm. In a typical presentation, I would start off by saying when I mention organic minerals — I'm not talking about not using pesticides or herbicides — I'm talking about the chemistry of carbon, just like Dr. Murphy mentioned. Remember, there is no real requirement for inorganic trace minerals.  Animals need zinc, copper, manganese, selenium, etc. every day, but the source of that trace mineral is not dictated, so organic minerals are suitable for all different production systems.

Tom:            Okay, for either of you, has research proven that an organic mineral is more bioavailable and usable by the animal?

Richard:        Absolutely. I think Roger would agree. We've got an absolute wealth of information that we've built up over the last 20 years or so showing that the organic minerals are a far superior source of mineral to use in all diets.

Roger:          Yes, like Dr. Murphy mentioned, the bioavailability part, I think, is what gets people's attention initially. But then, at the end of the day, the farmer, no matter what species, is looking for a production response. So, we also have research covering production responses that you would see as you change your mineral supplementation from inorganic to organic.

Tom:            What is it about organic minerals that makes them more beneficial?

Richard:        For me — my background is in biochemistry — it's trying to understand how minerals interact, not just in terms of how the animal responds to it, but how those minerals would interact with feed and materials, for instance. Certainly, with the organic minerals, you have benefits beyond just health and just performance in that we change the way in which we can impact or influence the nutrients in the diet.

                    With the organic minerals, we know it will have less of an impact on vitamin stability, less of an impact on antioxidant function. Even with some of the enzymes that are part of the gastrointestinal and digestion process — they won't be as impacted by organic minerals as they would by inorganics.

Roger:          Then, to follow a little bit with Dr. Murphy's comment, some of the, for example, enzyme interaction work that we've done in vitro has been done in dairy cows as well, showing that, when you're only supplementing with organic minerals — in our case, Bioplex® and Sel-Plex® — you have a more effective rumen fermentation. So, you're producing more total volatile fatty acids and more butyrate, which is kind of the business of the rumen: to produce those volatile fatty acids. Whether it's a case of the organic minerals enhancing that or leading to accelerated rumen organism replication, it's one possible pathway, but I think another possible pathway would be that you're removing rumen microorganism inhabitation when you take out the inorganic minerals.

Tom:            Which trace minerals are key to improving livestock performance? Is there a shortlist?

Roger:          The shortlist would be zinc, manganese, copper, cobalt and selenium. Depending on where you are in the world, or even within a given country, one of those may be more important than another one. In North America, our most important mineral for supplementation and consideration would be selenium, just based on the background selenium in soil, which is going to dictate the selenium in forages and grains. Those five would be the main ones. On the monogastric animal, we would add iron to that. We have six minerals we'd be talking about.

Tom:            We may have touched on this a little bit before, but what is known about the utilization of the minerals by the animal — or animals, I should say?

Richard:        Well, minerals themselves are used in many different ways. Predominantly, when you look at their role in cellular systems, they're essential co-factors for many different enzymes, for instance. You won't get cellular processes working optimally or working efficiently if you don't have the necessary mineral required for the enzyme to carry out its function, or for the enzyme that's necessary for those biological functions.

                    They're wide-ranging. If you look at copper, for instance, it's involved in many different enzymes that are involved in the antioxidant response. Selenium is a particularly important one in terms of its ability to modulate, not just in antioxidant response, but in many other enzymes that are involved in many other processes as well. So, really, they're essential and critical for the most basic of cellular functions.

Tom:            Are there differences in animal chemistry species to species, or even within species, that cause mineral forms to perform differently?

Roger:          My answer — and this would be more in Richard’s wheelhouse — but just in a ruminant, we have to deal with the rumen, the rumen environment, the rumen microorganisms. In other species, you wouldn't have the rumen part. In equine or in horses, they would have a hindgut fermentation. There’s a difference in terms of how each animal is set up, but for the most part, you're seeing the similar benefits from organic minerals across the species.

Richard:        There is one common factor across all species — we touched on this at the start — which is that change in pH along the length of the GI tract. That's one of the most critical parameters that is involved in defining how good or how poor a mineral source is. If that mineral source is enabled to withstand those constant changes in pH, you won't get it to the sites of absorption in the intestine. You really need to look at having a stable mineral molecule. Obviously, organic minerals are the most stable of those. But even within the different types of organic mineral products that are out there, you'll see distinct differences in terms of the stabilities of individual products, and that will have an impact on how individual products will function in the animal.

Tom:            Why do organic trace minerals mean less inclusion, less waste and better meat quality?

Roger:          Well, to me the starting point would be that you don't need as much mineral to get the job done. Corollary to that, you're getting a more effective job done with organic minerals. I think, over the years, in the industry side of things, it's kind of been a race to the top. One company was using however many PPM [parts per million] — or milligrams — of a mineral, and the next company would add a little more to it, operating under the old adage of more is better.

                    Well, that's really not the case. We found, and have the research to show, that you're getting a more effective response with less mineral use, probably through a lot of the pathways Dr. Murphy mentioned, but it's not always an apples-to- apples comparison. Zinc oxide, at a given parts-per-million, is not going to perform the same as a zinc proteinate, or Bioplex zinc, at a much lower concentration inclusion in the diet.

Richard:        It's actually of interest on the regulatory side — and I think Dr. Scaletti would probably agree with this as well — when you look at changes in legislation over the last number of years, in particular in the EU, there have been changes in the maximum permissible limits that are allowed in feed. I think the zinc — this is just back to Roger's mention of zinc oxide there — I think the zinc area is one in which we can demonstrate that quite nicely. There's a lot of talk in the EU about how they're going to ban zinc oxide use as a prophylactic and prevent scouring in piglets and calves, for instance.

                    One of the reasons for that that they've quoted is that the regulators are concerned about the impact that zinc oxide can have on co-selection for antimicrobial resistance. But when you look at the permissible limits that they have of zinc in feed, they make reference to the use of phytase, for instance, as being a way to perhaps enhance the effectiveness of the zinc source that's added to the diet or enhance the background level of zinc that's in the feed.

                    All in all, I think there's a move by the regulators. Now, the regulators, if they want to change those limits again, will have to come back and revisit the delineation between inorganic and organic minerals and the differences in terms of the bioavailabilities of those. I think, in the future, we may even see regulators like the EU body — which would be the EFSA (the European Food Safety Authority) — would say, “Okay, we'll need to examine this in more detail.”

                    Certainly, the Brazilian authorities have already done that. They've made a clear delineation between the availability of inorganic and organic mineral sources. The more recent documents that have been published by authorities in Brazil basically delineate clearly between what levels of inorganic you should feed in a diet and what levels of organic you should feed in the diet, and they're distinctly different.

Tom:            As you have observed improvements in performance, are there any lessons? Any takeaways from that experience that have informed what you do going forward?

Roger:          I would say: more isn't better. I think a lot of people are accustomed to looking at a tag or a ration report, and they're looking for a certain number or level of mineral supplementation. That's only so useful if you, then, don't read the ingredient list and see, is it coming from oxide, sulfate, organic proteinate — whatever the case may be. I think the source of mineral is more important than the amount. So again, it's about making sure it's an apples-to-apples comparison, and less doesn't mean less performance. I think a lot of times, at least in the United States, our industry would be looking for high levels of supplementation, and they equate high level with being good or what is essential, and that's not really the case.

Richard:        Just to add to that as well, Dr. Scaletti, I think it's important that the industry really looks at organic minerals and says they're not all the same. There is a misconception, I think, within the industry. You have all these different brand names and different types of organic mineral products. I guess the natural inclination is to say, “Well, it's an organic mineral. One product must be the same as the other.” There are very distinct differences between them.

                    Again, this is back to that concept of how that mineral source interacts or how stable it is as it moves through the GI tract. Certainly, in some of the work that we've seen from the team at our European Biocenter in Ireland, we've basically shown there are very distinct differences in terms of the stabilities of different organic trace mineral products, and that can have distinct impacts, not just on the bioavailability, but also in which [of] those different products would interact with different premix and different feed components.

Tom:            There are some misperceptions out there about minerals. What beliefs are most prominent and how do you address them?

Richard:        I think the biggest misconception is with regard to size. That's probably the biggest industry misconception that's there, and that's a historical one. Originally, when organic minerals first became available, they were simply complexes between amino acids, like methionine or lysine, with copper and with zinc. Certainly, people thought, “Well, if you have a small bonding group, then absorption of it is much better or delivery of it is much easier.” That's not the case. What we've seen is that it's the type of bonding group that's used — so, the type of amino acid. But, particularly when you get into peptide-based technologies like we see in Bioplex, it's the actual amino acid sequence in those peptides. So, it's even more fundamental than we would have thought in the past. The configuration and the type of amino acids present in the peptide would very significantly influence the stability.

                    I think the biggest misconception in the industry about organic trace minerals is that size is important. I can absolutely say with certainty size is not an issue. It's the type of bonding group that's used. And more importantly, when you look at peptides, it's the configuration and the sequence of amino acids that are in the peptide that are of more importance.

Roger:          I would just maybe follow up with that in regard to organic selenium. The battle is typically, “What is the content of selenomethionine in a selenium yeast product?” Dr. Murphy would have research showing it's not only an effect of how much selenomethionine you have present; it's how much of that can be digested and released. So, again, just coming back to that concept of “more isn't always better,” especially if what you're supplementing isn't released — or isn't available — to the animal.

Richard:        Yeah, that's actually a great point, Dr. Scaletti, just on the organic selenium side. Certainly, in the EU, we've seen newer forms of, again, so-called organic selenium sources being produced and available for sale, and these are actually chemically synthesized selenomethionine and selenomethionine derivatives that are distinctly different and have a distinctly different offering than you would see with selenium yeast products, such as Sel-Plex, for instance.

                    Again, it's back to the concept of stability. Free selenomethionine molecule is not necessarily the most stable one when you look at again the influences of those processes in the GI tract. So, certainly, even within organic selenium sources, [it’s a] much, much different proposition now with the availability of these newer chemically synthesized molecules.

Tom:            Livestock in many parts of the world have been overfed inorganic forms of trace minerals, such as copper, manganese and zinc, to offset their inefficient digestibility. The excess ends up in manure, and levels of these trace minerals have gotten so high that it's actually illegal to spread that manure out in the fields to support growth forages or grain. So, what happens to all of that excess manure? We're stuck with it?

Richard:        Well, I guess if we can't spread it, we've got to do something with it, and it looks like we could be. I know from some of the newer technologies that are coming out — some great startup companies that are basically looking at detoxifying heavy metal in soils using microbial-based solutions. So, perhaps, this is one way in which we can look at remediating those heavily contaminated lagoons, if you like.

                    Other options may be stripping-based technologies. These are basically looking at removing minerals, and this will be costly, Tom, I would have to say, removing mineral with EDTA-based chelation. But, certainly, something has to be done, and I think organic minerals are, without a doubt, one of the solutions to the problem. You can look at adding less mineral, having less runoff and then, obviously, less contamination in those lagoons. Certainly, the drive toward reducing environmental contamination will definitely be driven and solved, without a doubt, by the increased use of organic minerals over the next couple of years.

Tom:            In some places, regulation is beginning to force the issue. A number of countries around the world have already passed legislation restricting the use of trace minerals because this overfortification has led to pollution. Do you see this type of legal action as a continuing trend?

Richard:        I guess it goes back to the comment I made earlier about the regulations around zinc and zinc usage in feed, but also, then, the impending ban in the EU on zinc oxide as a prophylactic. I think the regulators will take a greater look at the issue, and I think they will certainly have to start making decisions on whether they promote organic minerals as a way in which we can reduce this or not. It's not the job of a regulator to promote a brand of products, but certainly, I think, when you look at the proposition that organic minerals give in terms of being a solution to the problem, they'll have to start promoting the use of organic minerals as a way in which you can add less, not impacting performance, and have much less of an environmental impact.

Roger:          I would just say that I think the path forward is just going to depend [on] where you are in the world. I don't know that the United States is looking at any of these zinc, manganese or copper regulations any time soon. Our only regulations in terms of trace minerals would be selenium and the mineral we haven't talked about today: iodine. If you're using iodine in the EDDI (ethylenediamine dihydroiodide) form, there are limits on how much you're allowed to feed. Other than that, selenium would be our only regulated mineral, and today, we could go out and supplement as much zinc as we want in any animal in the United States without a problem.

Tom:            Are you seeing growth in the organic minerals market?

Roger:          We're seeing tremendous growth, both globally and regionally. In North America, I think, as people realize, again, that it's not an apples-to-apples comparison or you're not just looking at a level of mineral — that you need to pay attention to the form — that people are realizing that organic minerals have an important role. I also think we're getting a little bit closer on the cost difference; inorganic minerals are still cheaper, but their price keeps going up. I don't know that cost is as prohibitive as it used to be, from a practical farm level.

                    That's probably the only reason people aren't using organic minerals as their only source. It's a cost thing. Now, when you start looking at the response and, then, the return over investment opportunity, well, it's not a cost: it's a profit-maker. So, I think it's just a slow change.

                    When you look at trace minerals, for 60-70 years, we used inorganic minerals; for the past 20, we've used organic. So, it's still pretty new in terms of what's going on in the general supplementation industry. When you look at some of the different documents out there — for example, National Research Council or NRC Guidelines — they really don't get into a discussion on form. As Dr. Murphy mentioned, the Brazilian government recognizes that there are form differences, and some other countries around the world are starting to do so as well. I still think it’s left to feed companies, nutritionists and, ultimately, the farmer or end user to make a decision of, “Do I want to make an investment? If so, how much?” That's kind of where the decision is today.

Tom:            As you continue working toward better performance in animals, are you exploring new ideas for delivering nutrition more efficiently? Is that just an ongoing process?

Richard:        Yeah, it's an ongoing evolution. I think we've moved, over the last number of years, more toward, rather than thinking about nutrition as just being an individual component, we've really focused on the benefits of multicomponent packs. Certainly, there are a lot of different synergies you can get from different products present in a pack and the many ways you can get, I guess, good synergism between those components. Certainly, with some of the Blueprint® products that we have in Alltech, we've seen tremendous increases in health or performance and, again, these are multicomponent impacts. Rather than thinking about nutrition as being individual components added together, we tend to think about the synergism that we can get from multiple components out of them. That's something that we'll focus on more and more over the next couple of years.

Tom:            This has been really enjoyable. I have one final question: what new developments in minerals or mineral feeding strategies do you think we might see within the next five years or so?

Roger:          I don't know if I see a new development as much as just people embracing organic minerals more than they currently do. I'd say, currently, most of the industry would be at some sort of a partial supplementation, where the bulk of the mineral that's being supplemented is inorganic sulfate or oxide, and then they try to come up with how much organic to put in. They want to get all the benefits of organic, but they don't want all the price.

                    I see more of the bigger advancement being, as people just progress through that decision in their head, from partial replacement to more of the full replacement or total replacement, and realizing that organic minerals are what's doing the heavy lifting – that there really isn't a big need for those inorganic minerals that, for maybe just historical purposes, they just can't seem to kick out of the ration.

Tom:            Do you see something in the near future, Dr. Murphy?

Richard:        I'd agree with Dr. Scaletti in that. We’re going to see increased awareness in the benefits of organic minerals and how you can use less of those organic minerals and not have a negative impact on health and performance. That, obviously, is going to feed into an environmental benefit. I think we'll also see changes, perhaps, in the way in which we apply these minerals. I think people are looking more and more toward technology as a driver of agriculture.

                    I think we'll see differences in the next few years in the way in which feed delivery is made, in the way in which you can actually begin to look at delivering feed on farms. I do think we'll see more and more digital-based technologies that will influence feeding strategies, and then, it will obviously influence how we formally feed.

Tom:            Dr. Richard Murphy, research director at the Alltech European Bioscience Center in Dunboyne, Ireland, and Dr. Roger Scaletti, who focuses on the technical sales and support of the Alltech Mineral Management program. Thank you both for joining us.

Richard:        Thank you very much.

Roger:          Thank you.  

Drs. Scaletti and Murphy presented their insights during ONE: The Alltech Ideas Conference (ONE18). Don't miss the chance to hear the latest in animal health and nutrition at ONE19. Click here to learn more. 

Mycotoxins are often a hidden threat in feed, which can impact the performance and health of poultry. Mycotoxins are chemical secondary metabolites produced by molds as a reaction mechanism in response to an environmental stimulus. Molds may produce mycotoxins during the growing season, at harvest or during storage of feed materials post-harvest. It is common for feedstuffs to be contaminated with multiple mycotoxins, as one mold can produce several types of mycotoxins or multiple molds can produce mycotoxins in the same feedstuff. In fact, analysis conducted by the Alltech 37+® Analytical Laboratory shows that multi-mycotoxin contamination is present in 92.3 percent of 2017-2018 poultry feeds globally. As a result, the presence of mycotoxins is a major issue faced by the poultry industry worldwide.

Poultry that consume high levels of mycotoxins in feed may have obvious clinical signs of mycotoxicosis in relation to specific tissues, organs or performance. However, of more concern, often, is the long-term intake of lower levels of mycotoxins, as symptoms are not noticed daily but still add up to become a long-term problem. In this instance, it is important to watch the birds closely and look for a variety of specific and non-specific symptoms of mycotoxins.

A common sign of mycotoxin consumption by poultry at both lower and higher concentrations is the appearance of lesions, which start in the mouth and continue along the gastrointestinal tract. These lesions are often caused by trichothecene mycotoxins such as deoxynivalenol (DON) and T2/HT-2 toxins, which cause oxidative stress and damage to cells along the intestinal tract. These lesions — along with other side effects in the gastrointestinal tract, such as changes to mucus production, reduced villi length and impacts on gut-level immunity — can suppress health and performance and can also expose chickens to increased gut pathogen colonization. The presence of mycotoxins, such as DON and fumonisins, have been linked to increased colonization and severity of such pathogens as Salmonella, E. coli and Clostridium perfringens.

Considering the many effects that mycotoxin have on poultry health, performance changes are also likely. Research shows that growing birds may have reduced weight gain and poor feed efficiency, while layers and breeders may have reduced egg production, poor egg quality or decreased hatchability. Young birds will typically be more susceptible to the impacts of mycotoxins. Like so many nutritional and health factors, the impacts of mycotoxins on a young bird could alter the ability of the bird to attain its genetic capacity for performance.

Using the Alltech PROTECT™ Calculator and average risk in 2018 North American poultry feed as analyzed by Alltech 37+®, broilers may lose about 3.6 g/d in gain and have a 4.8 percent increase in feed conversion ratio. Likewise, layers may lose about 5.2 eggs over a 60-week egg-laying period. When mycotoxins impact performance, there is likely also a loss of profitability. Poultry producers should be aware of the costs of mycotoxins in order to better manage the risk.

Due to the characteristics of mycotoxins, laboratory analysis of a feedstuff or finished feed is the first step in understanding risk. There are a limited number of commercial laboratories in the world capable of analyzing multiple mycotoxins from one sample. The Alltech 37+® Analytical Laboratory, located in Kentucky, provides complete analysis for 50 different mycotoxins in a single sample and also considers the total mycotoxin challenge present in each sample, rather than just looking at the individual mycotoxins. As such, the results of the analysis more closely reflect commercial production and the challenges faced by producers. Since all species and lifecycles of birds are susceptible to mycotoxins to varying degrees, samples analyzed through the 37+® Program are also provided a Risk Equivalent Quantity (REQ), one number that calculates the cumulative effect of mycotoxins and the overall risk to the target animal group associated with the sample.

An understanding of mycotoxicosis in poultry is complicated by the occurrence of several mycotoxins together and their interactions in the animal, as well as their non-specific symptoms. It is clear that multiple mycotoxin contamination is an unavoidable risk — and is costly in today’s poultry production. It is important, then, to use the right economic assessment methods to evaluate the multiple contaminations and, then, to control mycotoxin risk in the feed mill and at the farm level.

I want to learn more about protecting my poultry operation from mycotoxins.

Dietary trace minerals like copper, zinc and manganese are nutrients critical to animal health, performance and welfare. Immunity, reproduction, growth and even meat and milk quality hinge on optimal trace mineral nutrition.

Everything we know about trace mineral nutrition, from inclusion levels to effects on performance, has come from studies using inorganic trace mineral salts. Trace mineral salts are made from a trace mineral loosely bound to a charged ion and have been the basis of trace mineral supplementation and research since the 1930s. Recent studies, however, are using a different form of trace mineral, and the results of those studies are challenging ideas once considered fundamental to livestock nutrition.

In the early 1990s, organic trace minerals were first developed to reflect the way trace minerals naturally occur in plants. These supplements have a protein-like or carbohydrate ring structure that attaches to the trace mineral at multiple sites. The protein or carbohydrate component serves as a protective, stable delivery system, increasing the likelihood of mineral absorption.

The last 20 years of research confirm that the difference between a mineral salt and a trace mineral bound to a stable organic ring are substantial. The evidence points to organics as a superior source of trace minerals, but beyond that, we see unprecedented effects in the animal when they receive optimally formulated minerals. Organic trace minerals are changing the way we look at livestock nutrition overall.

Below are seven major changes to nutritional dogma instigated by studies looking at organic trace minerals. While many nutritionists still cling to the low-priced, traditional inorganics, organic trace minerals are fostering a revolution in animal feeding.   

1. Not all trace mineral forms are created equal

Historically, inorganic trace minerals have been the primary form of mineral supplementation. Their inexpensive synthesis, however, produces a supplement that quickly dissociates and reacts within the feed and digestive tract.

Dr. Richard Murphy is a biochemist and research director in Dunboyne, Ireland, who has focused much of his work on characterizing, comparing and optimizing trace mineral supplements.

"When comparing mineral products — both inorganic and organic — the key differentiation point is to understand their stability through the GI tract," said Murphy. "Stability at the acidic pH found in the gastric environment is critical to ensuring maximal delivery of mineral to sites of mineral absorption in the intestine."

Dr. Murphy's work has repeatedly shown that organic trace minerals are far superior to traditional inorganic trace minerals in both stability and overall bioavailability. They are, in fact, so much more efficient that countless animal trials have shown that organic trace minerals can be fed at significantly lower levels than their inorganic counterpart without disrupting health and performance. 

Surprisingly, Dr. Murphy's research has also found that not all organic trace minerals are created equal.

"Ultimately, the type and position of the amino acids used in organic trace minerals are critical for stability," said Dr. Murphy.

Different brands of organic trace minerals use different amino acid and peptide strands, some with far weaker associations and lower stability than others.

Dr. Murphy and his research associates have developed a peptide-trace mineral configuration for use in organic trace minerals that provides optimal stability. It is, in fact, his work in differentiating organic and inorganic trace minerals that has laid the foundation for the six other breakthroughs in mineral nutrition.

2. Inorganics: Not required

The National Academies of Sciences, Engineering, and Medicine (NASEM) publishes livestock requirements for all essential nutrients, among which it lists inorganic trace minerals. New research, however, proves that, while trace minerals are essential, there is no absolute requirement for inorganic trace minerals. In fact, eliminating inorganics altogether and replacing them with organic trace minerals appears to enhance performance. 

In beef cattle, a total replacement of inorganic trace minerals with lower levels (60 percent) of organic trace minerals improved health and performance and generated a $50/head advantage (Holder et al., 2016). Total replacement with organic trace minerals in pigs improved average daily gain, increased slaughter weight by 2 kg and improved slaughter efficiency to generate a savings of $1.80 per pig.

Inorganics may prevent deficiency, but there are far more effective supplement options. Even operations feeding a combination of inorganic and organic trace minerals stand to benefit from converting to 100 percent organic trace minerals. The total replacement of inorganics offers the best results in achieving animal genetic potential.

3. Organic trace mineral bioavailability: using less to do more

Studies routinely feed organic trace minerals at levels 30-50 percent lower than inorganics because the superior delivery system of organics allows them to be more efficiently absorbed. Poultry scientists at the University of Kentucky asked, "Just how much more efficiently?"

In their study, broilers were fed organic trace minerals at levels 75 percent lower than commercial levels for inorganics. These birds reached a desirable market weight in the standard six-week period and showed no signs of deficiency or disease, even though they were fed only one-quarter the mineral ration of their inorganic-fed counterparts (Ao et al., 2009). These relative concentrations are below those traditionally recognized as needed for meeting the birds’ requirements.

Organic trace minerals are more effectively absorbed and deposited in the intended tissues, so small amounts can have a greater impact. The inefficiency of inorganics requires producers to significantly overfeed them. Organic trace minerals offer a way for producers to maximize resources. This research also gives us a clearer picture of what an animal's true trace mineral requirements might be.

4. Organic trace minerals contribute to significant improvements in animal health

Trace minerals have a lock-and-key effect on certain antioxidant enzymes that are critical to immune function. A sufficient supply of trace minerals can be described as the sustaining fuel of the immune system. Recent feeding trials and nutrigenomic studies showcase organic minerals taking on some of agriculture’s most costly diseases.

In feedlot cattle, a total replacement of inorganic trace minerals with lower levels of organic trace minerals (60 percent of commercial levels for inorganics) was able to reduce mortality by 57 percent and mortality due to bovine respiratory disease (BRD) by 69 percent. Even in the cattle contracting BRD, the number of retreats was significantly reduced with organic trace minerals (Holder et al., 2016). Too good to be true? A separate study conducted on a different continent confirmed the effects: organic trace mineral groups showed a 7.7 percent decrease in even the incidence of BRD (Sgoifo Rossi et al., 2018).

"BRD costs the U.S. beef industry upwards of $800 million and is the greatest concern and cause of loss at the feed yard,” said Dr. Vaughn Holder, lead beef researcher at Alltech. “Organic trace minerals provide a new reinforcement to the animals’ first line of defense and add tremendously to the producer’s peace of mind."

In poultry, necrotic enteritis (NE) brings devastating costs, approaching $6 billion annually with mortality rates of 1 percent per day. Organic trace minerals eliminated bird death due to NE, reducing mortality by 12 percent compared to inorganics (He et al., 2017; Bortoluzzi et al., 2017). Birds on organic trace minerals also showed significant positive changes to the expression of genes related to improved disease resistance.

From gene expression to disease markers and mortality, there is mounting evidence that the bioavailability of organic minerals better equips animals to take on and survive disease challenges.

5. Organic trace minerals lead to extended shelf life and improved meat quality

The impact of organic trace minerals spans the entire food chain, all the way to our own refrigerators. Animal nutrition directly affects meat quality, as feeding organic trace minerals results in meat that lasts longer and tastes juicier.

"Trace minerals are essential to antioxidant enzymes in the meat," said Dr. Rebecca Delles, an Alltech meat scientist. "By providing a trace mineral source that is more bioavailable, those antioxidants have a better mineral supply to sustain their activity."

Proving her point, beef from steers that were fed organic trace minerals showed increased antioxidant activity, which led to extended shelf life (Sgoifo Rossi et al., 2018). That same meat also showed increased water retention, which improves profitability and texture. Dr. Delles found that organic trace minerals had the same effect in pork loin and chicken breast, beneficially improving both sensory experience and the producer’s bottom line (Delles et al., 2014; Delles et al., 2016).

"The average amount of time it takes a consumer to recover from a bad meat purchase is three months,” said Dr. Delles. “If the appearance, flavor or texture is perceived as being low quality, it will be another three months before the customer reconsiders purchasing that meat product. In fresh pork, if only 5 percent of U.S. consumers have a bad meat experience, that could still bring a projected loss of 3 percent — or $181,938,556.80 — over the course of 12 weeks due to what might seem like 'just color or texture.'"

6. More efficient organic trace minerals decrease the environmental impact of livestock

Bioavailable organic trace minerals are the exclusive method of sustaining animal performance while simultaneously lowering environmental impact.

The instability of inorganic minerals makes them difficult for the animal to absorb. This often leads to overfeeding of trace minerals and, therefore, excretion of large quantities of minerals back into the environment. These excreted minerals alter what is known as a “mineral footprint” and contribute to soil and water contamination.

The improved bioavailability allowing lower inclusion rates of organic trace minerals has been found to directly reduce the mineral footprint of livestock.

A series of trials conducted by agriculture institutions across China in 2017 found that in swine, poultry and ruminants, organic trace minerals could be fed at substantially lower quantities than inorganics and yield the same performance — but return much lower mineral excretion. The same was not true for inorganics: while low levels of inorganics also reduced mineral excretion, they were detrimental to animal health and reduced performance (Guo et al., 2017; Ma et al., 2018; Qui et al., 2018).

"This type of research changes the way we study animal nutrition,” said Dr. Karl Dawson, ruminant microbiologist and chief scientific officer at Alltech. “These are the solutions we need to sustainably feed our growing populations — benefitting all stakeholders while decreasing the environmental impact of intensive animal production systems."

7. Optimal organic trace mineral nutrition improves herd health, reproduction and performance for multiple generations

Trace minerals have a multigenerational effect. Like other nutrients, trace minerals change gene expression, effectively turning genes on or off, up or down. Those changes in gene expression are heritable — meaning the effects of a mother's nutrition, good or bad, are passed on to her offspring before they even take their first bite of feed. This phenomenon, known as epigenetics, gives producers and nutritionists the power to use nutrition to build their future herd. 

Dairy scientists at Pennsylvania State University studied a herd over three generations and found that heifer calves experienced 10 fewer days of sickness and came into estrus 26 days sooner when their dams were fed organic trace minerals (Gelsinger et al., 2016; Pino et al., 2018). This was true even for heifer calves who didn't consume organic trace minerals themselves, confirming that the effect was solely due to maternal nutrition. Fewer days of sickness are correlated to increased milk production later in life and reaching reproductive maturity almost one month sooner, which is worth approximately $100/head in management costs and a 2-3 percent decrease in carbon footprint.

In beef cattle, calves born to cows fed organic trace minerals showed improved body weight through weaning and again at 205 days, regardless of their own diet (Price et al., 2017). Weaning is one of the most critical stress points in the beef life cycle — but organic trace minerals in utero allowed weaning and young calves to thrive despite their circumstances. While trace minerals can have an incredible impact on a single animal, results like these show potential for strategized feeding for the future herd.

The advent of precision feeding

From feed to fork, trace mineral source makes all the difference. Organic trace minerals provide livestock with an essential nutrient in an optimized form, and the effects of such precision reverberate throughout the entire food chain. With effects on animal health and welfare, producer livelihood, consumer preference and environmental protection, no stakeholder is overlooked. This is the advent of a revolution in precision feeding. Well-timed, optimally designed nutrients can reveal to us an animal's real requirements and allow them to achieve their true genetic potential, so that we can build better herds and feed a growing population.

Click here to learn more about solutions through the Alltech Mineral Management program. 

Citations

Holder, V. B., Jennings, J. S., Covey, T. L. (2016). Effect of total replacement of trace minerals with Bioplex® proteinated minerals on the health and performance of lightweight, high-risk feedlot cattle, Journal of Animal Science, 94 (5), 120

Taylor-Pickard, J., Nollet, L., and Geers, R. (2013). Performance, carcass characteristics and economic benefits of total replacement of inorganic minerals by organic forms in growing pig diets, J. Appl. Anim. Nutr. 2 (e3): 1-3

T Ao, JL Pierce, AJ Pescatore, AC Cantor, KA Dawson & MJ Ford. (2009). Effects of feeding reduced levels of organic minerals (Bioplex) on the development of white layer pullets, Poult. Sci. 88 (Suppl. 1), 197

Sgoifo Rossi, C.A., Ripamonti, G., and Compiani, R. (2018, May). Not all mineral supplements for beef cattle bring same results. Feedstuffs, 90 (5).

He, B., King, W., Graugnard, D., Dawson, K.A., Bortoluzzi, C., Applegate, T. (2017). Zinc source influences the gene expression of zinc transporters in the jejunum and cecal tonsils of broilers challenged with coccidia and Clostridium perfringens., Poultry Science Association Annual Meeting, Orlando, FL, USA, 17-23 July, 2017

Bortoluzzi, C., Lumpkins, B., Mathis, G., King, W.D., Graugnard, D., Dawson, K.A., Applegate, T. Comparative efficacy of dietary zinc sources for the mitigation of the impact of necrotic enteritis in coccidial challenged broiler chickens, Poultry Science Association Annual Meeting, Orlando, FL, USA, 17-23 July, 2017

Delles, R.M., Xiong, Y.L., True, A.D., Ao, T., Dawson, K.A. (2014) Dietary antioxidant supplementation enhances lipid and protein oxidative stability of chicken broiler meat through promotion of antioxidant enzyme activity, Poult. Sci. 93:1561-1570

Delles, R.M.,  Naylor, A., Kocher, A., Dawson, K.A., Samuel, R.S. (2016). Diets with organic trace minerals (Bioplex®) and yeast protein (NuPro®) improved the water-holding capacity of pork loin meat, Midwest Animal Science Meetings, March; J. Animal Sci. 94 (Supple. 2): 65

Guo, Y., Liu, B., Xiong, P., He, J., Gang, L., Xue, Y.,Koontz, A.F., Yu, D. (2017). Effect of Cu Provided As Bioplex® Cu or TBCC for Weaned Pigs, Growth Performance, Tissue Mineral Retention, and Fecal Mineral Excretion, ASAS-CSAS Annual Meeting, 17-20 July, Baltimore, MD, USA, 2017

LX Ma, JN He, CC Hou, JL Qiu, XT Lu, B Liu, G Lin, Y Xue, AF Koontz, DY Yu. (2018). Effect of compound organic trace minerals on growth performance, serum indices and micromineral excretion in fattening pigs, ASAS-CSAS Annual Meeting, 5-8 July, Vancouver, Canada

JL Qui, XT Lu, LX Ma, CC Hou, JN He, B Liu, G Lin, T Ao, DY Yu (2018). Effect of low dose complex organic trace minerals on productive performance, egg quality and fecal mineral excretion of laying hens, Poult. Sci. 97 (e-Suppl. 1): 202

Price, D.M., Arellano, K.K., Irsik, M., Rae, D.O., Yelich, J.V., Mjoun, K., Hersom, M.J., (2017) Professional Animal Scientist 33: 194–204

Gelsinger et al., 2016 Maternal and early life nutrition and calf health

Pino et al., 2017 Maternal and early life nutrition and offspring first lactation

Harvest time is here. During this busy time, remember to not only monitor what’s coming in from the field, but also to think about what could be happening in other regions from which you may be purchasing feed ingredients.

Molds and yeasts can grow very rapidly as the weather warms in the spring and in the heat of the early summer months. But what about the end of summer and early fall? The weather across North America was extremely variable this summer — from extremely hot temperatures to drought to floods, week after week. How do these weather patterns affect the crops, and what should you be looking for in your feed this fall?

It is commonly understood that drought-stressed fields do not yield well. Digestibility and overall quality will be poor from feed grown in drought-stressed areas. Can living organisms like molds grow during a drought? The answer is yes: many species of molds will still grow during a drought, or they become dormant and wait for the right growing environment to return. One example of a drought-tolerant mold is Aspergillus. Many times, Aspergillus molds will appear olive green to yellowish in color on infected plants. Aflatoxins come from the mold species Aspergillus flavus and Aspergillus parasiticus. Aflatoxins are carcinogenic and thrive in hot conditions. Aflatoxin B1 can convert into M1 and can be found in milk. If this toxin is found over a set limit, the milk must be discarded. When fed to livestock, aflatoxins cause liver damage, suppress the immune system and reduce protein synthesis.

What about areas under heavy rain?

Several molds are typically found during summers of heavy rain, including Fusarium, Penicillium, Mucor, Rhizopus, etc. Fusarium is commonly found in both normal growing conditions and during wetter months. Many times, this mold first appears white and will change to a reddish-pink color. Under stress, both in the field and during storage, this mold can form many mycotoxins, including the trichothecenes family (DON or Vomitoxin, T-2, etc.), fusaric acid, fumonisins, and zearalenones. Clinical signs that these are present include immune suppression, bowel hemorrhaging, reduced intakes, poor milk production, reduced weight gains, abortions, conception challenges, vasodilation and even mortality.

The Penicillium molds will typically show blue to greenish in color, or potentially white, depending on the host crop. Penicillium molds will typically infect feed during storage, but abnormal weather patterns — such as heavy rains or, sometimes, cooler temperatures — can cause more mold to form. Certain tillage practices can also influence mold growth. When stressed, Penicillium molds can form patulin, Penicillic acid and ochratoxin. Clinical signs that these are present include edema, rumen upsets, loose manure, bowel hemorrhaging and increased rates of mortality.

This is a minute sampling of the mycotoxin challenges that can exist during harvest in your fields. Remember: the commodities or other purchased feedstuffs that are shipped in by boat, train or truck may present their own mold and mycotoxin challenges. Check the origin of purchased feed to determine what stress or abnormal weather was experienced in that region. Your local dealers, nutritionists or Alltech representatives can put together information on mycotoxin results from other regions. If you want to be especially diligent in lessening mycotoxin challenges, an on-farm RAPIREAD® mycotoxin test or Alltech 37+® mycotoxin test will check your feeds for any concerns. Remember, more information on mycotoxins is always available online at knowmycotoxins.com.

I want to learn more about protecting my feed from mycotoxins.

Cristiano Bortoluzzi wins award for paper on improved performance and regulating the expression of intestinal immune-related genes of broiler chickens 

[LEXINGTON, Ky.] — Continuing their commitment to student research and agriculture innovation, Alltech presented the 35th Alltech Student Research Manuscript Award to Cristiano Bortoluzzi, a doctoral student at the University of Georgia, during the 107th annual Poultry Science Association (PSA) meeting, held in San Antonio, Texas, on July 23-26. This award is given to a student who is the senior author of an outstanding research manuscript in Poultry Science or The Journal of Applied Poultry Research, and only students awarded Certificates of Excellence for research presentations at an annual PSA meeting can compete. 

Bortoluzzi’s winning paper — entitled “Sodium butyrate improved performance while modulating the cecal microbiota and regulating the expression of intestinal immune-related genes of broiler chickens” — evaluated the effect of sodium butyrate (SB) on performance, expression of immune-related genes in the cecal tonsils, and cecal microbiota of broiler chickens when dietary energy and amino acids concentrations were reduced. The paper results confirmed that SB had positive effects on the productive performance of broilers fed nutritionally reduced diets, partially by modulating the cecal microbiota and exerting immune modulatory effects. 

"Alltech is proud to sponsor this award, as innovation is the core of our business," said Dr. Kayla Price, poultry technical manager for Alltech Canada. “We support advancements in the poultry industry and encourage students to publish their research and communicate their discoveries, which can positively influence the future of poultry production." 

Cristiano Bortoluzzi is a doctor of veterinary medicine and is currently pursuing a Ph.D. in the department of poultry science at the University of Georgia. He grew up on a farm in southern Brazil with dairy cows, pigs and poultry, so his passion for animal production started when he was young and has influenced his career path.  

Bortoluzzi completed several internships in his first year of vet school and found that poultry nutrition and health interested him the most. Throughout his studies, he was actively involved in research trials, attended scientific meetings and learned about the intestinal health/immune system of broilers and the importance of nutrition.  

While working toward his master’s degree, he spent three months working with the United States Department of Agriculture/Agriculture Research Service (USDA/ARS) in Indiana. In January 2015, he started his Ph.D. in animal science at Purdue University, later moving to the University of Georgia. Bortoluzzi has published 18 papers and will finish his Ph.D. in the fall. He is looking forward to working in and contributing his expertise to the poultry industry. 

Alltech has sponsored the Alltech Student Research Manuscript Award since 2000, recognizing young leaders in scientific innovation for their commitment to publishing and sharing their work within the poultry sector.