JP2012130355A - Gel-based livestock feed, method of manufacture and use - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a gel-based livestock feed and use thereof.SOLUTION: The present invention provides a method for weaving piglets by feeding young piglets for up to 7 days directly after weaning a gel feed containing nutrients. In one embodiment, the piglets at the date of weaning are less than 10 pounds in weight, and at least one of the nutrients comprises protein derived from blood. The present invention also provides a livestock feed including an alginate-based gel matrix in which water is the major component and protein is derived from blood, such as plasma or serum.

Description

(Background of the Invention)
The present invention includes a method of feeding livestock to livestock, particularly feeding pigs. The present invention also includes a novel composition of gel feed and a method for producing such gel feed.

  There are many situations where both feed and water supply are required but are difficult to provide or provide both outcomes at an additional cost. For example, when transporting livestock, it is difficult and expensive to maintain water supply for each livestock. In addition, there are situations related to the life of an animal where the animal does not show much interest in ingesting feed but specific nutrition is required. For example, since young animals have to learn how to ingest solid food, nutritional problems arise during the transition period such as weaning. For young animals, it may be difficult to get used to nutrition intake other than by feeding. Early weaning provides benefits in avoiding disease and weight gain. However, early weaning needs to be considered to ensure that the young animals can receive sufficient nutrients.

  Female pigs also require special nutrition immediately before and after delivery. Adequate nutrient intake minimizes the growth of growing fetuses, the needs of the sows themselves (maintenance), the secretion of milk, and the reduction in feed intake of sows after delivery Required by female pigs to limit.

  Growing and finishing pigs may also require special nutrients, which may be due to any factor such as disease and environmental factors. Disease and environmental factors can affect nutrition intake and, in turn, affect the profitability of pig farmers.

(Summary of the Invention)
The present invention includes a method for producing a gel-type feed for livestock. The method initially forms a feed mixture by mixing a feed nutrient component, water, alginate, a water-insoluble calcium component, or a sequestrant that inhibits the reaction between the calcium component and the alginate. Including that. Once the feed mixture is formed, the calcium component is solubilized or sequestered against the reactivity between the alginate and the calcium component so that a gel feed is formed that includes a gel matrix containing the feed nutrient component. Is removed.

  The present invention also includes a method of feeding livestock with gel feed produced according to the method of the present invention.

  In another aspect of the invention, piglets are weaned by feeding a gel diet containing nutrients for at least 7 days immediately after weaning.

  In yet another aspect of the present invention, the gel livestock feed comprises an alginate-based gel matrix in which water is the major component and the protein is derived from blood such as plasma or serum. In another embodiment, egg protein may be replaced with or combined with blood derived protein.

The present invention also provides a method for supplying water to a confined livestock by feeding the confined livestock with a gel feed comprising water as a main component and supplying the confined livestock with a daily amount of water. Including.
For example, the present invention provides the following items:
(Item 1)
A method for producing livestock feed,
Forming a feed mixture by mixing a feed nutrient component, water, alginate, a water-insoluble calcium component, or a sequestering agent that inhibits the reaction between the calcium component and the alginate; and
Once the feed mixture is formed, the calcium component is solubilized or the effect of the sequestering agent on the reactivity between the alginate and the calcium component is removed, so that the feed nutrient component A gel feed comprising a gel matrix containing
Including a method.
(Item 2)
The method according to item 1, further comprising adding an acid or an acidic substance to the feed mixture to lower the pH and solubilize the calcium component.
(Item 3)
Item 3. The method of item 2, wherein the acid is any of citric acid, fumaric acid or propionic acid, or any combination thereof.
(Item 4)
Item 2. The method according to Item 1, wherein the pH during mixing of the feed nutrient components forming the feed mixture is about 6.0 or more.
(Item 5)
3. The method of item 2, wherein sufficient acid or acidic material is added to reduce the pH to at least about 4.5 or less.
(Item 6)
Item 2. The method according to Item 1, wherein the calcium component is a calcium salt.
(Item 7)
Item 7. The method according to Item 6, wherein the calcium salt is dicalcium phosphate, calcium carbonate, calcium gluconate, calcium iodate, calcium sulfate, or any combination thereof.
(Item 8)
Item 7. The calcium salt becomes soluble at a selected pH, becomes reactive with the alginate, and the pH of the feed mixture is lowered below the selected pH. the method of.
(Item 9)
Item 2. The method according to Item 1, wherein the water is a main component.
(Item 10)
Item 2. The method of item 1, wherein an antibiotic or chemotherapeutic agent is added when the feed mixture is formed.
(Item 11)
The antibiotic or chemotherapeutic agent is apramycin, bacitracin methylenedisalicylate, zinc bacitracin, bambermycin, chlortetracycline, lincomycin, neomycin, oxytetracycline, penicillin, tiamulin, tylosin, virginiamycin, arsanilic acid, carbodox, 11. A method according to item 10, comprising roxarson, sulfamethazine, sulfathiazole, or any combination thereof.
(Item 12)
The feed mixture comprises about 25-90% water, about 2-25% protein, about 3-40% carbohydrate, about 0-10% lipid, and less than about 2% fiber. The method according to 1.
(Item 13)
Item 2. The method according to Item 1, wherein the at least one nutritional component is a blood-derived protein.
(Item 14)
A method of feeding livestock,
Forming a feed mixture by mixing the feed nutrient component with water, alginate, a water-insoluble calcium component, or a sequestering agent that inhibits the reaction of the calcium component with the alginate;
Once the feed mixture is formed, the calcium component is solubilized or the effect of the sequestering agent on the reactivity between the alginate and the calcium component is removed, so that the feed nutrient component Forming a gel feed comprising a gel matrix containing
Feeding the gel feed to livestock
Including a method.
(Item 15)
15. The method according to item 14, further comprising adding an acid or an acidic substance to the feed mixture to lower the pH and solubilize the calcium component.
(Item 16)
16. A method according to item 15, wherein the acid is any of citric acid, fumaric acid, or propionic acid, or any combination thereof.
(Item 17)
15. A method according to item 14, wherein the pH during mixing of the feed nutritional components forming the feed mixture is about 6.0 or higher.
(Item 18)
16. The method of item 15, wherein sufficient acid or acidic material is added to lower the pH to at least about 4.5 or less.
(Item 19)
Item 15. The method according to Item 14, wherein the calcium component is a calcium salt.
(Item 20)
20. The method of item 19, wherein the calcium salt is dicalcium phosphate, calcium carbonate, calcium gluconate, calcium iodate, calcium sulfate, or any combination thereof.
(Item 21)
20. A method according to item 19, wherein the calcium salt becomes soluble at a selected pH and the pH of the feed mixture is lowered below the selected pH.
(Item 22)
Item 15. The method according to Item 14, wherein the water is a main component.
(Item 23)
Item 15. The method of item 14, wherein an antibiotic or chemotherapeutic agent is added to form the feed mixture.
(Item 24)
The antibiotic or chemotherapeutic agent is apramycin, bacitracin methylenedisalicylate, zinc bacitracin, bambermycin, chlortetracycline, lincomycin, neomycin, oxytetracycline, penicillin, tiamulin, tylosin, virginiamycin, arsanilic acid, carbodox, 24. The method of item 23 comprising roxarson, sulfamethazine, sulfathiazole, or any combination thereof.
(Item 25)
The feed mixture comprises about 25-90% water, about 2-25% protein, about 3-40% carbohydrate, about 0-10% lipid, and less than about 2% fiber. 14. The method according to 14.
(Item 26)
15. A method according to item 14, wherein the at least one nutritional component is a blood-derived protein.
(Item 27)
15. A product produced by the process of item 14, wherein the gel is characterized by not sticking to the domestic animal's face.
(Item 28)
A method of weaning a piglet,
Feeding the piglet with a gel feed containing nutrients for 7 days immediately after weaning.
(Item 29)
29. A method according to item 28, wherein the weight of the piglet on the weaning day is less than 10 pounds.
(Item 30)
29. A method according to item 28, wherein at least one of the nutrients comprises a blood-derived protein.
(Item 31)
31. A method according to item 30, wherein the blood-derived protein is in the form of plasma or serum.
(Item 32)
29. A method according to item 28, wherein the gel feed is an alginate-based gel matrix, the main component of which is water, and contains the nutrient.
(Item 33)
The gel feed is
Mixing the nutrients, water, alginate and a calcium component that is initially water-insoluble or initially inhibited from reacting with the alginate to form a feed mixture;
Once the feed mixture is formed, the calcium component is solubilized or the inhibition of reactivity between the calcium component and the alginate is removed, so that the gel comprising a gel matrix containing the nutrients Feed is formed
33. A method according to item 32, first produced by
(Item 34)
34. The method of item 33, further comprising adding an acid or acidic substance to the formed feed mixture to lower the pH and solubilize the calcium component.
(Item 35)
35. A method according to item 34, wherein the acid is either citric acid, fumaric acid or propionic acid, or any combination thereof.
(Item 36)
34. A method according to item 33, wherein the pH during mixing of the feed nutritional component is about 6.0 or more.
(Item 37)
35. The method of item 34, wherein sufficient acid or acidic material is added to lower the pH to at least about 4.5 or less.
(Item 38)
34. A method according to item 33, wherein the calcium component is a calcium salt.
(Item 39)
40. The method of item 38, wherein the calcium salt is dicalcium phosphate, calcium carbonate, calcium gluconate, calcium iodate or calcium sulfate, or any combination thereof.
(Item 40)
40. The method of item 38, wherein the calcium salt becomes soluble at a selected pH, and the pH of the feed mixture is lowered below the selected pH.
(Item 41)
29. A method according to item 28, wherein the gel feed comprises an antibiotic or a chemotherapeutic agent.
(Item 42)
The antibiotic or chemotherapeutic agent is apramycin, bacitracin methylenedisalicylate, zinc bacitracin, bambermycin, chlortetracycline, lincomycin, neomycin, oxytetracycline, penicillin, tiamulin, tylosin, virginiamycin, arsanilic acid, carbodox, 42. The method of item 41, comprising roxarson, sulfamethazine, sulfathiazole, or any combination thereof.
(Item 43)
The gel feed comprises about 25-90% water, about 2-25% protein, about 3-40% carbohydrate, about 0-10% lipid, and less than about 2% fiber. 28. The method according to 28.
(Item 44)
29. A method according to item 28, wherein the gel feed contains blood-derived protein.
(Item 45)
Livestock feed comprising water as a major component and an alginate-based gel matrix comprising up to about 25 weight percent blood-derived protein.
(Item 46)
46. Livestock feed according to item 45, wherein the blood-derived protein is in the form of plasma or serum.
(Item 47)
46. Livestock feed according to item 45, further comprising an antibiotic or a chemotherapeutic agent.
(Item 48)
The antibiotic or chemotherapeutic agent is apramycin, bacitracin methylenedisalicylate, zinc bacitracin, bambermycin, chlortetracycline, lincomycin, neomycin, oxytetracycline, penicillin, tiamulin, tylosin, virginiamycin, arsanilic acid, carbodox, 48. Livestock feed according to item 47 comprising roxarson, sulfamethazine, sulfathiazole, or any combination thereof.
(Item 49)
A method of supplying water to confined livestock,
Providing a daily required amount of water to the confined livestock by feeding the confined livestock with a water-based gel feed.
(Item 50)
50. A method according to item 49, wherein the gelling agent for the gel feed is a viscous substance.
(Item 51)
51. The method of item 50, wherein the viscous material comprises agar, alginate, carrageenan, gum arabic, gati gum, tragacanth, pectin, guar, gellan, carboxymethylcellulose, locus bean, or any combination thereof.
(Item 52)
50. The method of item 49, wherein the gelling agent comprises pectin, chitin, gelatin, or any combination thereof.
(Item 53)
50. A method according to item 49, wherein the gelling agent is starch.
(Item 54)
54. The method of item 53, wherein the starch is derived from sorghum powder, ground rice, rice powder, ground and extruded corn, ground sorghum, wheat, or any combination thereof.

Detailed Description of Preferred Embodiments
The present invention provides a feed that contains nutrients, has a good taste, and has excellent storability in a gel matrix whose main component is water. This gel feed supplies both livestock and water components to livestock to the extent that no additional water is needed outside the feed to support livestock life. Livestock means agricultural animals or livestock animals such as pigs, horses, cows, sheep or goats bred in a farm, ranch or agricultural environment, or animals bred in a zoo or zoological environment.

  Alternatively, the gel may be used alone as a water source without any nutrients. It is difficult to supply water to confined pigs by transporting them individually in an enclosure or by truck trailer without entering an enclosure. By providing water in solid form, spills due to vehicle movement or animal collisions are eliminated.

  Furthermore, the gel feed of the present invention may be used as a delivery system for drugs such as antibiotics and chemotherapeutic drugs, or microbial supplements such as probiotics and functional foods. When used as a drug delivery system, the drug may be the only constituent in the gel. Examples of antibiotics approved for pigs include apramycin, bacitracin methylene disacylate, bacitracin zinc, bumbermycin, chlortetracycline, lincomycin, neomycin, oxytetracycline, penicillin, thiamulin, and tylosin Virginiamycin is included. Chemotherapeutic drugs approved for pigs include arsanilic acid, carbodox, loxolsone, sulfamethazine, and sulfathiazole. Other drugs for pigs are well known and are within the scope of the present invention.

  The hardness of the gel type feed of the present invention may range from a soft gel having a putting hardness to a hard gel having a gummy candy hardness such as Gummy Bears (registered trademark). The gel may be described as a colloidal gel in which water is the dispersion medium, that is, a hydrogel. One consideration in the hardness of the gel is that the gel does not adhere to the animals it is raised. Gels that adhere to pigs pose two problems. The first problem concerns the cleanliness of the animal and the enclosure that houses the animal. Another problem is waste of feed. This is because the animal cannot ingest feed adhering to parts that cannot be reached by mouth of the animal, such as the face and other body parts. How hard the gel is is not critical and in many cases, preferably the main component is water. By main component it is meant that the weight percentage of water is higher than all other components in the gel feed.

  The composition of the gel feed of the present invention is as follows.

本発明の組成物において有用なタンパク質の好適な原料には、動物系および植物系の両タンパク質が含まれる。動物系タンパク質の非網羅的な一覧には、肉粉、肉骨粉、血粉、赤血球、可溶性ブタタンパク質粉、加水分解羽毛粉、魚粉、粉乳、血漿および血清タンパク質、鶏肉副産物粉、乳清粉、濃縮乳清タンパク質、ならびに卵が含まれる。ゲル飼料中の血漿および／または血清タンパク質の好適な濃度は約０〜２５重量％であり、卵の好適な濃度は約０〜１５％である。植物系タンパク質の非網羅的な一覧には、アルファルファ粕、カノーラ種粕、米タンパク質、ココナッツ粕（コプラ）、小麦グルテン、ポテトタンパク質、綿実粕、亜麻仁粕（亜麻）、ピーナツ粕、ベニバナ粕、ゴマ粕、大豆粕、大豆タンパク質、およびサンフラワー粕、ならびにその他の脂肪種子粕が含まれる。

Suitable raw materials for proteins useful in the compositions of the present invention include both animal and plant proteins. Non-exhaustive list of animal-based proteins includes meat meal, meat and bone meal, blood meal, red blood cells, soluble porcine protein meal, hydrolyzed feather meal, fish meal, milk powder, plasma and serum proteins, chicken by-product meal, whey meal, concentrated milk Contains protein and eggs. The preferred concentration of plasma and / or serum protein in the gel feed is about 0-25% by weight and the preferred concentration of egg is about 0-15%. Non-exhaustive list of plant proteins includes alfalfa, canola seed, rice protein, coconut, gluten, potato protein, cottonseed, flaxseed, flax, peanut, safflower, Includes sesame meal, soybean meal, soy protein, and sunflower meal, and other oilseed meal.

  The saccharide raw materials useful in the present invention include sorghum powder, ground rice, rice powder, towed sorghum, oat product, wheat, ground sorghum, or wheat, oats, barley and rye wheat. Any suitable cereal-derived starch or tubers such as tapioca and potato are included. Lactose, dextrin, sucrose, fructose, and other monosaccharides are also suitable carbohydrates.

  Lipids useful in the present invention may be derived from both plant or animal sources. Some lipids may be generated by inclusion in a protein or carbohydrate source. However, lipids may be further added, and purified products such as mixed lipids (animal and vegetable mixtures) are common, or may be poultry or tallow, or soybean oil. In some cases, it is a vegetable raw material such as corn oil, canola oil, coconut oil or olive oil. Lipids are necessary as an energy source and also for the absorption of certain vitamins that may be added to the feed of the present invention.

  The fiber useful in the present invention is dietary fiber. The main source of dietary fiber is the same vegetable source that provides protein and / or carbohydrate. If additional dietary fiber is needed, it may be obtained from common ingredients such as soybean hulls or psyllium.

  In addition to the nutrients described above, it may be desirable to provide additional supplements of vitamins and minerals as needed for a particular animal.

  One of the gelling agents used in the present invention is a viscous material that can be mixed with water to form a matrix that holds feed ingredients (the aforementioned nutrients). Examples of suitable viscous materials include agar, alginate, carrageenan, gum arabic, gati gum, tragacanth, pectin, guar, gellan, carboxymethylcellulose, and locus bean. In the case of alginate, about 0.25 to 1.5% alginate of feed ingredients (excluding water) is required for gel formation. Other types of gels can also be included in the scope of the present invention, including sorghum powder, ground rice, rice powder, ground extruded corn, ground sorghum, wheat, and sugars (dextrin and Saccharide types other than viscous substances such as starch including sucrose). Other gelling agents that may be useful in the present invention include pectin, chitin, and animal protein-based gelatin.

  The gels of the present invention are preferably of the cold set type, but are prepared by heating viscous materials in water as described in US Pat. No. 5,217,740, incorporated herein by reference. Such gels are also included in the scope of the present invention. In certain embodiments discussed herein, the gel feed is not produced by using an external heat source. First, the protein, carbohydrate, lipid, and fiber components, as well as any other nutrients, vitamins, minerals, or other supplements, along with viscous substances and calcium ingredients, selected within the scope of Table 1 To mix in water. These selections are planned for a specific animal and a specific time period in the animal's life cycle. For example, piglets during and after weaning appear to be different in the required parts of the ingredients listed in Table 1 compared to female pigs during pregnancy.

  Preferably, the calcium source is water insoluble or contains a sequestering agent that inhibits the reaction between calcium and alginate so that a gel is not immediately formed. Gels formed through the reaction between calcium and alginate are well known. The nature of alginate forming gels and the difficulty of forming suitable gels are also well known. The inventive method of forming a gel provides for the controlled formation of an alginate gel. The use of sequestering agents or the use of acids to control the formation of alginate gels in the presence of calcium for use in human food is known.

  Preferably, the calcium source is a calcium salt, which is initially insoluble but may subsequently become soluble. One calcium salt suitable in the present invention is dicalcium phosphate. Dicalcium phosphate is substantially water insoluble at pH 6 and above. Other calcium suitable for use include calcium carbonate, calcium gluconate, calcium iodate, calcium oxide, calcium sulfate.

  As the mixture is mixed, the pH decreases. Preferably, citric acid, fumaric acid, or propionic acid is used alone or in combination with other organic acids. Other organic or mineral acids or acidic materials suitable for lowering pH are within the scope of the present invention. When the pH drops below about 4.5, the gel of the present invention is formed.

  The strength of alginate-based gels depends on several factors, including calcium concentration, pH, and the type of alginate used. By varying the calcium content, or the type of alginate used, or adjusting the pH, gels of different gel strengths can be produced. If the usefulness of calcium is low due to either pH or low calcium concentration, a soft gel may be formed. If the pH is low, a harder gel may be formed. Water hardness may also affect the formation of alginate gels depending on the calcium carbonate content of the water.

  The alginate-based gel of the present invention may be produced either batchwise or continuously. When manufactured in a batch, the nutrients, alginate, dicalcium phosphate, and water are mixed together. The organic acid is then added to lower the pH to a selected level where a gel is formed. On the other hand, mineral acids are also suitable for addition. For continuous formation, a batch of nutrients with alginate, dicalcium phosphate and water is first mixed in the tank. Then, mix water and acid in a separate tank. These two mixtures are then pumped through the outlet system and mixed through an in-line static mixer to continuously form a gel.

  One situation that is particularly useful in the present invention involves providing nutrients to weaning piglets. Weaning poses many challenges for piglets. These challenges include abrupt changes from liquid food to solid food. Solid foods contain ingredients that may not initially be easily digestible for piglets. In addition, piglets are placed in a new social structure. When combined, these effects can disrupt the intake of nutrients necessary to maintain the integrity of the gastrointestinal tract. Such disruptions are further exacerbated by the immature immune system that affects growth potential and causes susceptibility to dyspepsia or diarrhea or both.

  Studies have shown that in the first 24 hours after weaning, half of the piglets can only drink water (Varley and Stockill, 2001).

  During the first 5 days after weaning, the water intake by the piglets fluctuates independently of physiological demands, and water intake is related to growth, intake, or severity of diarrhea There seems to be no (McLese, et al., 1992). However, after day 5, water intake appears to follow a more consistent pattern parallel to growth and intake. It is estimated that during the first few days after weaning, water consumption may be high because it is necessary to fill the digestive tract in order to obtain a fullness in the absence of ingestion. Often, early weaning pigs that have been fed dry feed in the first few days after weaning are voluntarily fed. Evidence suggests that the growth rate of pigs in the early weaning period is more limited by their intake than the possibility of growth. Pluske (1993) reports that weaning pigs do not meet maintenance requirements from day 21 weaning to day 5.

  The gel product of the present invention provides not only the nutrient intake required for young pigs, but also the proper water requirements. By utilizing the gel feed of the present invention, the piglets surprisingly started eating the gel feed of the present invention almost immediately after weaning. Preferably, the gel type feed for infant pigs contains a high quality protein raw material such as spray-dried plasma protein. Spray-dried plasma proteins have been shown to help improve growth performance during the first 7-14 days after weaning and during the stress period of piglets. Plasma proteins appear to have biological functions beyond their nutritional value.

  The invention is explained in more detail in the following examples. These examples are for purposes of illustration only, as numerous modifications and variations that fall within the scope of the invention will become apparent to those skilled in the art.

Example 1
A total of 57 weaned pigs with an average body weight of 13.3 pounds were used in a 35-day growth study. Some piglets were fed a gel-based diet where the gel matrix was starch (Soft Set ^™ starch obtained from Staley Mfg. Co. (Decatur, Ill., USA)). A control (no gel) diet was used in the test with two gel diets, each gel diet containing a different protein source (Solutein ^™ or Appetin ^™ obtained from American Protein Corp. (Ames, Iowa)). Appletein ^™ is a plasma-derived protein, while Solutein ^™ is a serum-derived protein. It describes a formulation of gel containing Solutein ^TM in Table 2 below, are set forth in Table 3 below the formulation of gel containing Appentein ^TM.

表２および表３に記載した配合中の乾燥成分を、５クオートのＫｉｔｃｈｅｎＡｉｄ Ｍｉｘｅｒで混合した。プロピオン酸および水（表２および３に記載した成分１に対して３倍量の水）を、５ガロンバケツ内で混合し、Ｍｙｅｒｓ Ｍｉｘｅｒを使用して、液体量を３０秒間混合した。３０秒後、乾燥混合物を加え、乾燥および液体成分の混合物をさらに３分間混合した。各配合（Ｓｏｌｕｔｅｉｎ^ＴＭおよびＡｐｐｅｔｅｉｎ^ＴＭ）を５バッチ製造した。

The dry ingredients in the formulations listed in Tables 2 and 3 were mixed with a 5 quart KitchenAid Mixer. Propionic acid and water (3 times the amount of water relative to Component 1 listed in Tables 2 and 3) were mixed in a 5 gallon bucket and the liquid amount was mixed for 30 seconds using a Myers Mixer. After 30 seconds, the dry mixture was added and the dry and liquid component mixture was mixed for an additional 3 minutes. Five batches of each formulation (Solutein ^™ and Appletein ^™ ) were produced.

  At weaning, pigs were sorted by weight and divided into 6 weight groups (blocks). Dietary treatment was randomly assigned to each pen (3-4 pigs per pen) within each weight group (block, 6 replicates / treatment). The same number of pigs were housed in the enclosure within one block. Three types of dietary treatment were evaluated, consisting of:

Ｔｅａｍ Ｌｅａｎ １０〜１５ペレットを７日間給餌し、Ｔｅａｍ Ｌｅａｎ１４〜２０およびＴｅａｍ Ｌｅａｎ ２５〜５０を各１４日間給餌した。全てのペレットを囲いの入り口に取り付けた金属製フィーダーで給餌した。ゲル飼料は、離乳後第０〜４日間クリープフィーダーで給餌し、ゲル混合（５０：５０）および乾燥飼料（Ｔｅａｍ Ｌｅａｎ １０〜１５ペレット）は、離乳後第４〜７日間クリープフィーダーで給餌した。

Team Lean 10-15 pellets were fed for 7 days, and Team Lean 14-20 and Team Lean 25-50 were fed for 14 days each. All pellets were fed with a metal feeder attached to the entrance of the enclosure. Gel feed was fed with a creep feeder for 0-4 days after weaning, and gel mix (50:50) and dried feed (Team Lean 10-15 pellets) were fed with a creep feeder for 4-7 days after weaning.

  The pigs were housed in a conventional infant breeding facility in a pen with nipple waterer, 4-hole feeder, and plastic slatted floor. Pigs were able to consume feed and water at any time. Pig body weight and intake (both gel feed and pellets) were measured at 0 days, 4 days, 14 days, 21 days and 35 days after weaning, average daily weight gain (ADG), daily average intake ( ADFI) and feed: weight gain ratios were evaluated. The intake of gel feed was measured during the first week after weaning. In addition, fecal color and hardness scores were collected twice a week.

  Data were analyzed with the complete randomized method, using enclosures for experimental units and blocks based on initial body weight. Mean separation for significant treatment effects was achieved by the least significant difference (LSD) method.

離乳後第０〜７日および第７〜１４日の間（表５）、各処置群間のＡＤＧに関する有意差（Ｐ≧０．１）は観察されなかった。しかし、ゲル飼料を給餌された豚は、ゲル飼料を給餌されなかった豚よりもＡＤＧの数値が高かった。離乳後第１４〜２１日および第２１〜３５日の間にゲル飼料を給餌された豚は、ゲル飼料を給餌されなかった豚よりも大きい（Ｐ＜０．１）ＡＤＧを継続して有した。同様に、３５日間の全試験期間にわたり、ゲル飼料を給餌された豚は、ゲル飼料を給餌されなかった豚よりも大きい（Ｐ＜０．１１）ＡＤＧを有する傾向があった。離乳後３５日までに、Ｓｏｌｕｔｅｉｎ^ＴＭおよびＡｐｐｅｔｅｉｎ^ＴＭ含有ゲルを給餌された豚は、ゲル飼料を給餌されなかった豚よりもそれぞれ２．６ポンド、３．３ポンド体重が増加した。

During days 0-7 and 7-14 after weaning (Table 5), no significant difference (P ≧ 0.1) in terms of ADG between each treatment group was observed. However, pigs fed gel diet had higher ADG values than pigs not fed gel diet. Pigs fed gel diet between days 14-21 and 21-35 after weaning continued to have larger (P <0.1) ADG than pigs not fed gel diet. . Similarly, over the entire test period of 35 days, pigs fed gel diet tended to have a larger (P <0.11) ADG than pigs not fed gel diet. By 35 days after weaning, pigs fed Solutein ^™ and Appletine ^™ containing gel gained 2.6 pounds and 3.3 pounds, respectively, over pigs not fed the gel diet.

Further, the 0-4 days after weaning, the 4-7 day, and during the first 0-7 days, intake gel feed containing Solutein ^TM was similar to gel feed containing Appetein ^TM. Between days 0-7, the ADFI of the pellets was greater for pigs fed gel diet than for pigs not fed gel diet (P <0.03). This probably indicates the consumption of some dry feed when the pellet is mixed with the gel feed. Between days 7-14, pigs fed gel diet had higher ADFI values than pigs not fed gel diet. Between days 14-21, 21-35, and 0-35, pigs fed gel diet continued to have a larger (P <0.1) ADFI.

  During days 0-7 after weaning, pigs fed gel diet had lower values for weight gain: feed ratio (P <0.06) than pigs not fed gel diet. This probably indicates the consumption of some dry feed when the pellet is mixed with the gel feed. No significant difference in weight gain: feed ratio was observed between each treatment group between 7-14 days, 14-21 days, and 21-35 days after weaning.

  No significant differences in fecal color score and hardness were observed between treatment groups.

The results of this study show that during the first week after weaning, feeding a gel diet containing Solutein ^™ or Appletein ^™ (plasma protein) improved piglet growth. The improvement in weight gain was more apparent at a later stage. This suggests that gel intake during the first week after weaning may have a carry-over effect throughout the rest of the neonatal period. At the end of the study, pigs fed gel diet containing Solutein ^™ and plasma protein gained 2.6 pounds and 3.3 pounds body weight, respectively, compared to pigs not fed gel diet.

(Example 2)
A total of 270 weanling pigs with an average weight of 10.5 pounds were used in the 35-day growth study. At weaning, pigs were sorted by weight and divided into 11 weight groups (blocks). Each weight block consisted of 20 or 25 piglets of the same weight as much as possible. Five different dietary treatments were randomly assigned to each enclosure within each weight block. Each pen housed 4 or 5 piglets. Dietary treatment is shown in Table 6 below.

上記表６の４種類の処置用のゲル飼料を、バッチ処理を使用して混合した。各処置の組成物を、以下の表７に示す。最初に、水、ピロリン酸四ナトリウム、キサンタンガム、アルギネート、第二リン酸カルシウム、およびソルビン酸カリウムを、以下の表７に記載した割合で約２分半混合した。処置５（表６）は、ゲルを形成するために２種類のアルギネートを利用した。次いで、脂質、ビタミンおよびミネラル、Ｌｕｃｔａｒｏｍ（登録商標）、ならびにスクロースを、乾燥動物血漿、Ｓｏｌｕｔｅｉｎ^ＴＭ、または乾燥動物血漿および乾燥全卵のいずれかと共に混合した。その後、混合物を1分間混合した。

The four treatment gel feeds in Table 6 above were mixed using a batch process. The composition of each treatment is shown in Table 7 below. Initially, water, tetrasodium pyrophosphate, xanthan gum, alginate, dicalcium phosphate, and potassium sorbate were mixed for approximately two and a half minutes in the proportions listed in Table 7 below. Treatment 5 (Table 6) utilized two types of alginate to form a gel. Lipids, vitamins and minerals, Luctarom®, and sucrose were then mixed with either dried animal plasma, Solutein ^™ , or dried animal plasma and dried whole eggs. The mixture was then mixed for 1 minute.

  Each treatment was poured into a 5 gallon bucket. While stirring the mixture in each 5 gallon bucket using the Myers lab mixer, the proportions of fumaric acid, propionic acid and citric acid listed in Table 7 were added until the mixture began to gel (about 15 seconds). . Gel formation occurred in about 5 minutes.

豚は、各囲いの入り口に設置された金属製フィーダー内のペレット飼料を随時摂取できた。処置２、３、４および５のゲル飼料を、子豚がゲル型飼料を受けやすいように各囲いに追加された丸なべ型のクリープフィーダーで給餌した。ゲル飼料を随時供給し、その囲い内の全てのゲル飼料が摂取された場合、その後毎日ゲル飼料を追加した。また、子豚は水を無制限に摂取できた。処置２、３、４および５では、乾燥飼料（ペレット）を、第３〜７日の期間ゲル飼料に添加した。第３日に、ゲル飼料１ポンド当たり乾燥飼料０．１ポンドを添加した。第４日に、ゲル飼料１ポンド当たり乾燥飼料０．５ポンドを添加した。第５、６、および７日に、ゲル飼料１ポンド当たり乾燥飼料１ポンドを添加した。ゲル飼料摂取は、第７日の後、全ての処置で終了した。

Pigs were able to ingest pellet feed in metal feeders installed at the entrance of each pen at any time. The gel diets for treatments 2, 3, 4 and 5 were fed with a round-shaped creep feeder added to each pen to facilitate piglet access to the gel diet. Gel feed was fed from time to time, and when all gel feed in the enclosure was consumed, gel feed was added daily thereafter. In addition, piglets were able to consume unlimited water. In treatments 2, 3, 4 and 5, dry feed (pellets) was added to the gel feed for a period of 3-7 days. On the third day, 0.1 pound of dry feed was added per pound of gel feed. On the fourth day, 0.5 pounds of dry feed was added per pound of gel feed. On days 5, 6 and 7, 1 pound of dry feed was added per pound of gel feed. Gel feed intake was terminated for all treatments after day 7.

  Pig body weight and intake (gel feed and pellets) were measured on the day of weaning, on days 7, 14, 21 and 35 after weaning, average daily weight gain (ADG), average daily intake (ADFI) And the feed: weight gain ratio was evaluated. In addition, fecal color and hardness scores were collected twice a week.

  Data were analyzed by the complete randomized method using enclosures for experimental units and blocks based on initial body weight (see Table 8). The effects of initial body weight (less than 10 pounds and over 10 pounds), gel type, and initial body weight x gel type were evaluated.

離乳後第１週の間に、ＡＤＧに関する数値的改善が、最初の体重が１０ポンド未満で、かつ第１週にゲル飼料を給餌された豚に観察された。しかし、１０ポンド超の豚では、ＡＤＧに関する改善が観察されなかった。第２週の間に、処置群の間にＡＤＧに関する有意差は観察されなかった。第３週、第３〜５週、および５週間の全試験期間にわたり、ゲル飼料は、最初の体重が１０ポンド未満であった幼豚のＡＤＧを改善したが、最初の体重が１０ポンド超の豚には大して効果がなかった（最初の体重×ゲル相互作用、それぞれＰ＝０．０７、Ｐ＝０．１３、およびＰ＝０．０１）。離乳後第１週の間のゲル摂取は、残りの新生期間を通して持ち越し効果を有した。本試験の終了時には、体重が１０ポンド未満で、処置２、３、４、および５のゲル飼料を給餌された豚は、ゲル飼料を給餌されなかった豚よりも、それぞれ３．４４、１．６４、３．８３および４．１７ポンド体重が増加した。

During the first week after weaning, a numerical improvement on ADG was observed in pigs that initially weighed less than 10 pounds and were fed gel diet in the first week. However, no improvement on ADG was observed in pigs over 10 pounds. During the second week, no significant difference in ADG was observed between treatment groups. Over the entire study period of weeks 3, 3-5, and 5 weeks, gel diet improved ADG in young pigs that initially weighed less than 10 pounds, but the initial weight exceeded 10 pounds. Pigs were not very effective (initial body weight x gel interaction, P = 0.07, P = 0.13 and P = 0.01, respectively). Gel intake during the first week after weaning had a carry-over effect throughout the rest of the neonatal period. At the end of the study, pigs weighing less than 10 pounds and fed the diets of treatments 2, 3, 4, and 5 were 3.44, 1.. 64, 3.83 and 4.17 pounds gained weight.

During the first week after weaning, pigs fed gel diet consumed less (P <0.01) dry feed (pellets) than pigs not fed gel diet. Pigs fed gel diet with plasma consumed more gel diet but less dry diet (pellet). Pigs fed two types of alginate gel diet with Solutein ^™ had less intake of gel diet. During the second week, no significant difference (P> 0.01) in terms of ADFI was observed between treatment groups.

A significant interaction (P <0.05) of initial body weight × gel type was observed in ADFI at weeks 3, 3-5, and 0-5 weeks. During the third week, pigs that weighed less than 10 pounds at weaning and were fed gel containing Solutein ^™ , plasma and eggs, or Solutein ^™ plus two alginate were not fed gel diet More (P <0.05) of dry feed (pellets). In weeks 3-5, pigs weighing less than 10 pounds at weaning and fed Solutein ^™ or Solutein ^™ plus two alginate gels were larger than pigs that were not fed the gel (P <0. 05). Pigs weighing more than 10 pounds on weaning diet and fed Solutein ^™ plus two alginate gels consumed less dry feed than pigs not fed the gel (P <0.05). Similarly, at 0-5 weeks, pigs weighing less than 10 pounds at weaning and receiving Solutein ^™ , plasma plus eggs, or Solutein ^™ plus two alginate gels are more likely than pigs not fed the gel. A large (P <0.05) dry feed was ingested. Pigs that weighed more than 10 pounds at weaning and fed Solutein ^™ plus two alginate gels consumed less dry food than pigs fed other treatments (P <0.05).

  No significant difference in the feed: weight gain ratio was observed between the treatment groups during weeks 2, 3, 3-5, or weeks 0-5. However, during the third week, pigs fed gel diet (treatments 2, 3, 4, and 5) in the first week improved feed: weight gain compared to pigs that did not receive gel diet (P <0.1).

  The results of this study show that during the first week after weaning, feeding any of the gel diets (treatments 2, 3, 4, and 5) increased the growth of sows that weighed less than 10 pounds. Although improved, it was not very effective in growing piglets weighing over 10 pounds at weaning. At the end of the study (week 5), pigs weighing less than 10 pounds at weaning and fed gel diet (treatments 2, 3, 4 and 5) were not fed gel diet. More than gained weight. Pigs fed gel diet with plasma and eggs had a greater increase in numbers than pigs fed treatments 2 and 3.

Example 3
190 piglets with an average body weight of 12.2 pounds (MCG GPK35 maternal) are used in a 35-day growth study and are fed a standard breeding program by feeding gel diet in the first week after weaning The effect on growth was evaluated. At weaning, pigs were sorted by body weight and divided into 8 body weight groups (blocks) consisting of 20 or 25 animals per group. The average of the four weight groups was 10.6 pounds (representative of small pigs) and the average of the four weight groups was 13.8 pounds (representative of large pigs). The pigs in each weight group consisted of 5 equivalent smalls consisting of 5 or 4 pigs per pen (8 pens per treatment; 4 small pigs representative and 4 large pigs representative per treatment) Assigned to a group (enclosure). The number of pigs per pen in each block was kept constant. Dietary treatments were randomly assigned to enclosures (small groups) within each weight group (block). Five dietary treatments were evaluated during the first phase (1-7 days after weaning). The gels evaluated are listed in the table below.

表９に記載したゲル飼料を、実施例２に記載したバッチ処理を使用して混合した。乾燥ペレット飼料、Ｌｅａｎ Ｍｅｔｒｉｃｓ新生仔、Ｌｅａｎ Ｍｅｔｒｉｃｓジュニア、およびＬｅａｎ Ｍｅｔｒｉｃｓシニアは、表１０に記載した豚の日齢（処置の日数）に基づき豚に給餌するために配合された市販のペレット飼料である。

The gel feed described in Table 9 was mixed using the batch process described in Example 2. Dry Pellet Feed, Lean Metrics Neonate, Lean Metrics Junior, and Lean Metrics Senior are commercial pellet diets formulated for feeding pigs based on the pig age (number of days of treatment) listed in Table 10. .

処置１〜４の豚は、囲いの入り口に設置された金属製フィーダー内のペレット食餌を随時摂取することができた。処置２、３および４の豚には、離乳後第１〜３日の間にゲル食餌を丸型のクリープフィーダー（各囲いに追加された）で給餌した。第４〜７日の間には、ゲルプラス乾燥飼料の組み合わせを、処置２〜４の豚にクリープフィーダーで給餌した。ゲル１ポンド当たり０．１、０．５、１および１ポンドの乾燥飼料を、それぞれ第４、５、６および７日にクリープフィーダーに添加した。処置５の豚には、第１〜２日に囲いの入り口の金属製フィーダーにゲルだけを給餌した。第３日に、ゲル１ポンド当たり乾燥飼料１ポンドを、囲いの入り口の金属製フィーダーに添加した。第４日から試験の残りの期間に、乾燥飼料のみを囲いの入り口の金属製フィーダーで給餌した。

The pigs of treatments 1 to 4 were able to take pellet food in a metal feeder installed at the entrance of the pen at any time. Treatments 2, 3 and 4 pigs were fed a gel diet with a round creep feeder (added to each pen) between days 1-3 after weaning. Between days 4-7, the combination of gel plus dry feed was fed to treatment pigs 2-4 with a creep feeder. 0.1, 0.5, 1 and 1 pound of dry feed per pound of gel was added to the creep feeder on days 4, 5, 6 and 7 respectively. Treatment 5 pigs were fed only the gel into the metal feeder at the entrance to the enclosure on days 1-2. On the third day, 1 pound of dry feed per pound of gel was added to the metal feeder at the entrance of the enclosure. From the 4th day for the remainder of the test, only dry feed was fed with a metal feeder at the entrance of the enclosure.

  Pig body weight and intake (pellet) were measured on the first weaning day, 7, 14, 21 and 35 days after weaning, average daily weight gain (ADG), average daily intake (ADFI), and feed : The weight gain ratio was evaluated. Gel intake was measured during the first week after weaning. In addition, fecal color and hardness scores were collected twice a week.

  Data were analyzed with the complete randomized method, using enclosures for experimental units and blocks based on initial body weight. The effects of initial body weight (large and small), representative (size), gel type, and initial body weight x gel type were evaluated.

  During the first week after weaning, no significant difference (P> 0.10) regarding ADG was observed between treatment groups. However, numerical improvements with respect to ADG were observed by supplementing weaned pigs with gel. The greatest effect was observed in the smallest pig. Pigs with an average weight of less than 10.6 pounds (9-12 pounds) and fed a gel containing 75% water and 0.5% alginate (Treatment 3) will receive 62% water and 0. ADG values were higher than pigs fed a gel containing 5% (treatment 4). However, the largest pigs (weight 12-17 pounds, average 13.8 pounds) are fed with a gel containing 62% water rather than being fed a gel containing 75% water. The growth was good. In addition, pigs fed gel with a normal feeder in the first 3 days after weaning had higher ADG values than pigs fed gel with a creep feeder. This may be because pigs fed the gel with a normal feeder for only 3 days and then fed only dry feed with a normal feeder consumed more dry feed.

  Over the second, third, and whole periods, the smallest pigs supplemented with gel maintained higher ADG values than pigs that were not supplemented with gel. By 35 days after weaning, the smallest pigs in treatments 2, 3, 4 and 5 were 0.86, 1.53, 2.01 and 3.3, respectively, than pigs that were not fed gel (treatment 1). 43 pounds gained weight.

  As expected, during the first week, pigs in treatment 5 (fed with gel for only 3 days) had less gel intake (P <0.05) but in treatments 2, 3, and 4 More (P <0.05) dry feed was consumed from normal feeders than pigs. Treatment 5 pigs received the same amount of dry feed as treatment 1 (control) pigs. Treatment 2, 3 and 4 pigs had higher daily pellet intake than Treatment 1 or Treatment 5 pigs. This is a lower daily pellet intake from normal feeders in pigs fed treatments 2, 3 and 4 compared to pellet intake of treatment 1 and 5 pigs (P <0.05). This may indicate that some feed has been consumed when the pellets are mixed with the gel. In the second week, the smallest pig fed the gel had a higher pellet intake (statistically insignificant) than the pigs not fed the gel.

  In the first week after weaning, treatment 2, 3 and 4 pigs had a higher feed: weight gain ratio (P <0.05) than treatment 1 or treatment 5 pigs. This will be an indication of feed depletion when the pellet is mixed with the gel. During the second week, Treatment 5 pigs used feed more efficiently than Treatment 2 pigs. No significant difference (P> 0.1) regarding the feed: weight gain ratio was observed between the treatment groups at week 3 or weeks 3-5.

  The results of this study show that feeding the plasma containing eggs and plasma in the first week after weaning improved the growth of young pigs that weighed 9-12 pounds at weaning, It shows that there was not much effect on the growth of young pigs that were 12-17 pounds. As in the previous experiment, gel supplementation in the first week after weaning had a carry-over effect throughout the rest of the neonatal period, with the greatest effect in the smallest pig representative. By 35 days after weaning, treatment 2 (plasma containing 75% water and 1% alginate: egg gel), treatment 3 (plasma containing 75% water and 0.5% alginate: egg gel), treatment 4 ( Plasma with 62% water and 0.5% alginate: egg gel) and the smallest pigs in treatment 5 (similar to treatment 2 but fed the gel with regular feeders for only 3 days) Representatives gained 0.86, 1.53, 2.01 and 3.43 pounds body weight, respectively, compared to pigs that were not fed the gel (treatment 1).

Example 4
A gel with or without flavoring for the growth of young pigs using an average weight of 7.5 pounds of weaned pigs (MCG) in a 40-day growth study and fed standard feeding program for newborn pigs The effects of feeding were evaluated. At weaning, the pigs were sorted by body weight and divided into 6 body weight groups (blocks) consisting of 9 pigs per body weight group. Dietary treatments were randomly assigned to enclosures (small groups) within each weight group (block). Three dietary treatments were evaluated in the first phase (1-7 days after weaning) for (1) control (no gel), (2) flavored gel, and (3) no flavored gel.

  Gel feed (plasma and eggs) was mixed using a batch process as described in Example 2. Lean Metrics Premier, Lean Metrics Neonate, Lean Metrics Junior, and Lean Metrics Senior on Dry Pellet Feed are commercially available formulated to feed pigs based on the pig age (number of days of treatment) listed in Table 11 It is a pellet feed.

豚は、囲いの入り口に設置された金属製フィーダー内のペレット食餌を随時摂取することができた。処置２および３の豚には、離乳後第１〜３日の間にゲル食餌を丸型クリープフィーダー（各囲いに追加された）で給餌した。第４〜７日の間には、ゲルプラス乾燥飼料の組み合わせを、処置２および処置３の豚にクリープフィーダーで給餌した。ゲル１ポンド当たり０．１、０．５、１および１ポンドの乾燥飼料を、それぞれ第４、５、６および７日にクリープフィーダーに添加した。豚の体重および摂取量（ペレット）を、離乳開始日、離乳後第７、１４、２８および４０日に測定し、１日平均増体重（ＡＤＧ）、１日平均摂取量（ＡＤＦＩ）、および飼料：体重増加比を評価した。離乳後第１週にゲルの摂取量を測定した。

Pigs were able to ingest pellet food in metal feeders installed at the entrance of the pen at any time. Treatment pigs 2 and 3 were fed a gel diet with a round creep feeder (added to each pen) between days 1-3 after weaning. Between days 4-7, the combination of gel plus dry feed was fed to treatment 2 and treatment 3 pigs with a creep feeder. 0.1, 0.5, 1 and 1 pound of dry feed per pound of gel was added to the creep feeder on days 4, 5, 6 and 7 respectively. Pig body weight and intake (pellet) were measured on the first weaning day, 7, 14, 28 and 40 days after weaning, average daily weight gain (ADG), average daily intake (ADFI), and feed : The weight gain ratio was evaluated. Gel intake was measured in the first week after weaning.

  Data were analyzed with the complete randomized method, using enclosures for experimental units and blocks based on initial body weight.

  In the first week after weaning, pigs fed a flavored gel or a gel without flavor have a higher ADG (P <0.05) than pigs not fed the gel and fed the flavored gel. The pigs that were made had higher ADG than the pigs fed the unflavored gel. Pigs fed a flavored gel consumed more gel than pigs fed a flavored gel. Similarly, pigs fed gels had higher numbers of pellet intake than pigs not fed gels. By day 40 after weaning, pigs in treatment 2 (flavored gel) and treatment 3 (gel without flavor) were each 2. more than pigs that were not fed gel (treatment 1; Table 12). 1. 1.8 pounds gained weight.

（実施例５）
離乳の３日前および離乳後７日間のゲル（血漿および卵）の給餌が幼豚の成長に与える影響を評価するために、試験を実施した。１０組の同腹の子豚は、離乳の３日前に、分娩枠内のクリープフィーダーで、またはマット内でゲルを給餌された。離乳時に、各同腹の子豚のうち１／３には、表１３に記載の処置１用の給餌プログラムを供給し、１／３には、処置２用に記載の給餌プログラムを供給し、および１／３には、処置３用に記載の給餌プログラムを供給した。平均体重１０．９ポンドの離乳豚、計９０匹を使用した。処置３の豚だけが、授乳中ゲルを給餌され、かつ各囲いに追加された丸なべ型クリープフィーダーで給餌された。第４日に、ゲル１ポンド当たり乾燥飼料０．５ポンドを添加した。第５，６および７日に、ゲル１ポンド当たり乾燥飼料１ポンドを添加した。

(Example 5)
A study was conducted to evaluate the effects of feeding gel (plasma and eggs) on weanling growth 3 days before weaning and 7 days after weaning. Ten litters of piglets were fed gel with a creep feeder in the delivery frame or in the mat 3 days prior to weaning. At weaning, 1/3 of each litter piglet is fed the feeding program for Treatment 1 listed in Table 13, 1/3 is fed the feeding program described for Treatment 2, and In 1/3, the feeding program described for treatment 3 was supplied. A total of 90 weaned pigs with an average weight of 10.9 pounds were used. Only the treatment 3 pigs were fed gel during lactation and fed with a round pan-type creep feeder added to each pen. On the fourth day, 0.5 pounds of dry feed per pound of gel was added. On days 5, 6 and 7, 1 pound of dry feed per pound of gel was added.

  Gel feed (plasma and eggs) was mixed using a batch process as described in Example 2. The dry pellet feed is a commercial pellet feed formulated for feeding pigs based on the age of the pig (days of treatment) as described in Table 13.

データは、最初の体重に基づき囲いを実験ユニットおよびブロックに使用して、完全乱塊法で解析した。

Data were analyzed with the complete randomized method, using enclosures for experimental units and blocks based on initial body weight.

  During the first week after weaning, pigs fed the gel 3 days before weaning (within the delivery frame) and during the neonatal period (treatment 3) only within the delivery frame (no feeding of gel during the neonatal period, treatment 1 and treatment 2) ADG was higher than pigs fed gel (P <0.05). Between 0-28 days after weaning, pigs fed treatment 3 had higher ADG (P <0.10) and ADFI (P <0. 0) than pigs fed diet treatment 2 (Table 14). 05). Over the entire 39-day study period, pigs fed Treatment 3 had higher ADFI than pigs fed Treatment 2 (P <0.05).

Claims (21)

A method of weaning a piglet,
Feeding the piglet with a gel feed containing nutrients for 7 days immediately after weaning. The method of claim 1, wherein the weight of the piglet on the weaning day is less than 10 pounds. At least one of the nutrients, including blood-derived protein, The method of claim 1. 4. The method of claim 3 , wherein the blood derived protein is in the form of plasma or serum. The method of claim 1, wherein the gel feed is an alginate-based gel matrix, the main component of which is water, and contains the nutrients. The gel feed is
Mixing the nutrients, water, alginate and a calcium component that is initially water-insoluble or initially inhibited from reacting with the alginate to form a feed mixture;
Once the feed mixture is formed, the calcium component is solubilized or the inhibition of reactivity between the calcium component and the alginate is removed, so that the gel comprising a gel matrix containing the nutrients Feed is formed
6. The method of claim 5, wherein the method is first prepared by: 7. The method of claim 6 , further comprising adding an acid or acidic substance to the formed feed mixture to lower the pH and solubilize the calcium component. 8. The method of claim 7 , wherein the acid is either citric acid, fumaric acid or propionic acid, or any combination thereof. PH during mixing prior Symbol feed nutrients, is 6.0 or more, The method of claim 6. 8. The method of claim 7 , wherein sufficient acid or acidic material is added to lower the pH to at least 4.5 or less. The method of claim 6 , wherein the calcium component is a calcium salt. The method of claim 11 , wherein the calcium salt is dicalcium phosphate, calcium carbonate, calcium gluconate, calcium iodate or calcium sulfate, or any combination thereof. Wherein the calcium salt is become soluble at a selected pH, and the pH of the feed mixture is lowered to pH below is the selected method of claim 11. The gel feed contains an antibiotic or a chemotherapeutic agent The method of claim 1. The antibiotic or chemotherapeutic agent is apramycin, bacitracin methylenedisalicylate, zinc bacitracin, bambermycin, chlortetracycline, lincomycin, neomycin, oxytetracycline, penicillin, tiamulin, tylosin, virginiamycin, arsanilic acid, carbodox, 15. The method of claim 14 , comprising loxalson, sulfamethazine, sulfathiazole, or any combination thereof. The gel feed of claim 1, wherein the gel feed comprises 25-90% water, 2-25% protein, 3-40% carbohydrate, 0-10% lipid, and less than 2% fiber. Method. The gel feed containing protein derived from blood, The method of claim 1. Livestock feed comprising water as a major component and an alginate-based gel matrix comprising up to 25 weight percent blood-derived protein. 19. Livestock feed according to claim 18, wherein the blood derived protein is in the form of plasma or serum. The livestock feed of claim 18 further comprising an antibiotic or chemotherapeutic agent. The antibiotic or chemotherapeutic agent is apramycin, bacitracin methylenedisalicylate, zinc bacitracin, bambermycin, chlortetracycline, lincomycin, neomycin, oxytetracycline, penicillin, tiamulin, tylosin, virginiamycin, arsanilic acid, carbodox, 21. The livestock feed of claim 20, comprising loxarsone, sulfamethazine, sulfathiazole, or any combination thereof.