JP7288570B1 - Mammal or Livestock Supplements - Google Patents

Abstract

A multifunctional supplement for maintaining or improving the health of mammals or livestock. The supplement comprises (A) one or more selected from the group consisting of glycyrrhizic acid, glycyrrhizic acid derivatives, glycyrrhetinic acid, and glycyrrhetinic acid derivatives, and (B) licorice saponins other than (A) above. (C) a licorice extract containing licorice flavonoids and at least an increase in dietary intake of mammals or livestock, an increase in total blood cholesterol levels, an increase in blood vitamin A levels, an increase in blood vitamin A levels, and improve the health condition by at least one selected from the group consisting of a decrease in the GOT value of the body, an increase in body weight, prevention of diarrhea, a reduction in the number of days for treatment of diarrhea, prevention of colds, and a reduction in the number of days for treatment of colds. It is a supplement for mammals. [Selection figure] None

Description

The present invention relates generally to supplements, and specifically to supplements for mammals or livestock.

Licorice has been conventionally used as one of the raw materials for food additives and pharmaceuticals. In particular, attention is paid to the action of glycyrrhizic acid and licorice flavonoids contained in licorice, and it is sometimes used for specific purposes.

For example, in Japanese Patent No. 6589102 (Patent Document 1), focusing on glycyrrhizic acid contained in licorice, a feed additive for mammals for the purpose of improving the quality of embryos obtained after superovulation treatment and improvement For the purposes of the method, it is described that Japanese Black cattle are fed continuously with licorice extract having a glycyrrhizic acid content of at least 13% for 60-90 days until embryo recovery.

In addition, for example, Japanese Patent Application Laid-Open No. 2-204417 (Patent Document 2) discloses that an extract obtained from pulverized licorice root using ethanol as an extraction solvent is used as an adsorption resin to provide a licorice hydrophobic flavonoid preparation. to obtain a purified licorice extract containing about 50% hydrophobic flavonoids, medium-chain fatty acid triglycerides are added to produce an emulsion, and the emulsion is dried and pulverized.

In addition, Japanese Patent Application Laid-Open No. 2015-70823 (Patent Literature 3) discloses a technique for obtaining the sugar content of fruits or vegetables using licorice flavonoids contained in the crystallization mother liquor after crystallizing glycyrrhizic acid from a licorice extract as an active ingredient. An improver, a method for producing the same, and a method for improving the sugar content are described.

Japanese Patent Application Laid-Open No. 2018-161144 (Patent Document 4) describes a health and obesity maintenance agent containing a processed licorice product as an active ingredient. It is described to contain G2, licorice saponin H2, liquiritin, liquiritigenin, isoliquiritin, isoliquiritigenin, and the like.

Japanese Patent Application Laid-Open No. 2009-203182 (Patent Document 5) provides a food composition having an excellent hyaluronidase inhibitory action by using a licorice extract containing licorice saponin H2, thereby solving problems such as acne and rough skin. described to be resolved.

Japanese Patent No. 6589102 JP-A-2-204417 JP 2015-70823 A JP 2018-161144 A Japanese Patent Application Laid-Open No. 2009-203182

However, conventional licorice extracts are not sufficiently effective in simultaneously performing multiple functions necessary for maintaining or improving the health condition of, for example, mammals or livestock.

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide a multifunctional supplement for maintaining or improving the health of mammals or livestock.

As a result of intensive research, the present inventors have found that instead of using glycyrrhizic acid and licorice flavonoids, which have been conventionally used as active ingredients, individually in high purity or at high concentration, glycyrrhizic acid and licorice are used. In addition to flavonoids, the complex action of licorice saponins other than glycyrrhizic acid makes it possible to obtain high effects in various applications that cannot be expected from the use of each alone, making licorice extract a multifunctional product. It was found that it can be used as a sexual raw material. Based on the above findings, the present invention is configured as follows.

The supplement according to the present invention comprises (A) one or more selected from the group consisting of glycyrrhizic acid, glycyrrhizic acid derivatives, glycyrrhetinic acid, and glycyrrhetinic acid derivatives, and (B) licorice saponins other than (A) above. and (C) a licorice extract containing licorice flavonoids, at least in mammals or livestock, increasing dietary intake, increasing blood total cholesterol levels, increasing blood vitamin A levels, blood improving health condition by at least one selected from the group consisting of: lowering the GOT value in the body, increasing body weight, preventing diarrhea, reducing the number of days for diarrhea treatment, preventing colds, and reducing the number of days for treatment of colds. It is a supplement for mammals or domestic animals for

By doing so, it is possible to provide a multifunctional supplement for maintaining or improving the health condition of mammals or livestock.

FIG. 10 is a diagram showing a comparison of average leftover amounts of 10 males in each group in Test 1; FIG. 10 is a diagram showing a comparison of average leftover amounts of 10 females in each group in Test 1; 1 is a diagram showing average total cholesterol levels of 10 males in each section of Test 1. FIG. 1 is a diagram showing average total cholesterol levels of 10 females in each section of Test 1. FIG. 1 is a diagram showing average total cholesterol levels of 8 males in each section of Test 1. FIG. FIG. 10 is a diagram showing average total cholesterol levels of 8 females in each section of Test 1; 1 is a diagram showing average vitamin A levels of 10 males in each group in Test 1. FIG. 1 is a diagram showing the average vitamin A value of 10 females in each section of Test 1. FIG. FIG. 10 is a diagram showing average vitamin A levels of 8 males in each section of Test 1; 1 is a diagram showing average vitamin A levels of 8 females in each group in Test 1. FIG. FIG. 10 is a diagram showing the average GOT values of 10 males in each section of Test 1; FIG. 10 is a diagram showing an average GOT value of 10 females in each section of Test 1; 1 is a diagram showing average GOT values of 8 males in each section of Test 1. FIG. FIG. 10 is a diagram showing average GOT values of 8 females in each section of Test 1; FIG. 10 is a diagram showing the average weight of 10 males in each section of Test 1 at the time of shipment to the auction market. FIG. 10 is a diagram showing the average weight of 10 females in each section of Test 1 at the time of shipment to the auction market. FIG. 10 is a diagram showing the average weight of 8 males in each section of Test 1 at the time of shipment to the auction market. FIG. 10 is a diagram showing the average weight of 8 females in each section of Test 1 at the time of shipment to the auction market. FIG. 10 is a diagram showing a comparison of average leftover amounts of 10 males in each group in Test 2; FIG. 10 is a diagram showing a comparison of average leftover amounts of 10 females in each group in Test 2; FIG. 10 is a diagram showing average total cholesterol levels of 10 males in each section of Test 2; FIG. 10 is a diagram showing average total cholesterol levels of 10 females in each section of Test 2; FIG. 10 is a diagram showing average total cholesterol levels of 8 males in each section of Test 2; FIG. 10 is a diagram showing average total cholesterol levels of 8 females in each section of Test 2; FIG. 10 is a diagram showing the average vitamin A value of 10 males in each group in Test 2; FIG. 10 is a diagram showing the average vitamin A value of 10 females in each group in Test 2; FIG. 10 is a diagram showing average vitamin A levels of 8 males in each section of Test 2; FIG. 10 is a diagram showing average vitamin A levels of 8 females in each group in Test 2; FIG. 10 is a diagram showing an average GOT value of 10 males in each section of Test 2; FIG. 10 is a diagram showing an average GOT value of 10 females in each section of Test 2; FIG. 10 is a diagram showing average GOT values of 8 males in each section of Test 2; FIG. 10 is a diagram showing average GOT values of 8 females in each section of Test 2; FIG. 10 is a diagram showing body weights at introduction of males in each group in Test 2. FIG. FIG. 10 is a diagram showing body weight at introduction of females in each section of Test 2. FIG. FIG. 10 shows arrival weights of males in each group in Study 2. FIG. FIG. 10 shows arrival weights of females in each group in Trial 2. FIG. FIG. 10 is a diagram showing the weight gain of males in each group in Test 2. FIG. FIG. 10 is a diagram showing the weight gain of females in each section of Test 2. FIG. FIG. 10 is a diagram showing the edible liver discard rate of males in each group in Test 2; FIG. 10 is a diagram showing the edible liver waste rate of females in each group in Test 2; FIG. 10 is a diagram showing carcass weights of males in each group in Test 2. FIG. FIG. 10 is a diagram showing carcass weights of females in each section of Test 2. FIG. FIG. 10 is a diagram showing the average carcass yield of 10 males in each section of Test 2. FIG. FIG. 10 is a diagram showing the average carcass yield of 10 females in each section of Test 2; FIG. 10 is a diagram showing average carcass yields of 8 males in each section of Test 2. FIG. FIG. 10 is a diagram showing average carcass yield of 8 females in each section of Test 2. FIG. FIG. 10 is a diagram showing the average amount of leftover food of 12 males in each group in Test 3; FIG. 10 is a diagram showing the average amount of leftover food of 12 females in each group in Test 3; FIG. 10 is a diagram showing the average number of days until completion of eating by 12 males in each group in Test 3. FIG. FIG. 10 is a diagram showing the average number of days until completion of eating by 12 females in each group in Test 3. FIG. FIG. 10 is a diagram showing a comparison of average leftover amounts of 10 males in each group in Test 4; FIG. 10 is a diagram showing a comparison of average leftover amounts of 10 females in each group in Test 4; FIG. 10 is a diagram showing average total cholesterol levels of 10 males in each section of Test 4. FIG. FIG. 10 is a diagram showing average total cholesterol levels of 10 females in each group in Test 4; FIG. 10 is a diagram showing average total cholesterol levels of 8 males in each section of Test 4; FIG. 10 is a diagram showing average total cholesterol levels of 8 females in each section of Test 4; FIG. 10 is a diagram showing the average vitamin A value of 10 males in each group in Test 4; FIG. 10 is a diagram showing average vitamin A levels of 10 females in each group in Test 4; FIG. 10 is a diagram showing average vitamin A levels of 8 males in each group in Test 4; FIG. 10 is a diagram showing average vitamin A levels of 8 females in each group in Test 4; FIG. 10 is a diagram showing the average GOT values of 10 males in each section of Test 4; FIG. 10 is a diagram showing the average GOT value of 10 females in each section of Test 4; FIG. 10 is a diagram showing average GOT values of 8 males in each section of Test 4; FIG. 10 is a diagram showing average GOT values of 8 females in each section of Test 4; FIG. 10 is a diagram showing the incidence rate of diarrhea in Test 5. FIG. FIG. 10 shows mean number of treatment days for diarrhea in Study 5. FIG. FIG. 10 is a diagram showing the rate of occurrence of colds in Test 5; FIG. 10 shows the average number of cold treatment days in Trial 5. FIG.

Hereinafter, the supplement using the licorice extract of the present invention will be described in detail with specific examples. The present invention is not limited to the embodiments shown below, and various modifications are possible without departing from the technical idea of the present invention.

In the present invention, licorice refers to plants belonging to the genus Glycyrrhiza. Glycyrrhiza is a leguminous perennial that grows naturally in the Mediterranean region, Asia Minor, southern Russia, central Asia, northern China, North America, and the like. In the present invention, for example, Glycyrrhiza acanthocarpa, G.aspera, G.astragalina, G.bucharica, G.echinata (Russian licorice), G.eglandulosa, G.foetida, G.foetidissima, G.glabra (Spanish licorice), G.gontscharovii, G.iconica, G.inflate, G.korshinskyi, G.lepidota (licorice), G.pallidiflora, G.squamulosa, G.triphylla, G.uralensis (Ural licorice), G.yunnanensis, G. inflata (Xinjiang licorice) can be used. These can be used singly or in combination of two or more.

The supplement according to the present invention comprises (A) one or more selected from the group consisting of glycyrrhizic acid, glycyrrhizic acid derivatives, glycyrrhetinic acid, and glycyrrhetinic acid derivatives, and (B) licorice saponins other than (A) above. and (C) a licorice extract containing licorice flavonoids, at least in mammals or livestock, increasing dietary intake, increasing blood total cholesterol levels, increasing blood vitamin A levels, blood improving health condition by at least one selected from the group consisting of: lowering the GOT value in the body, increasing body weight, preventing diarrhea, reducing the number of days for diarrhea treatment, preventing colds, and reducing the number of days for treatment of colds. It is a supplement for mammals or domestic animals for

In the present invention, the glycyrrhizic acid derivative is not limited, and is, for example, dipotassium glycyrrhizinate. The glycyrrhetinic acid derivative is, without limitation, dipotassium glycyrrhetinate, for example. In the licorice extract of the present invention, (A) is preferably glycyrrhizic acid. The licorice extract preferably contains 10% by mass or more, and preferably 14% by mass or more, of (A) one or more selected from the group consisting of glycyrrhizic acid, glycyrrhizic acid derivatives, glycyrrhetinic acid, and glycyrrhetic acid derivatives. More preferred.

In the licorice extract used in the supplement of the present invention, (B) preferably contains licorice saponin H2, licorice saponin G2 and macedonoside A. The licorice extract preferably contains 3% by mass or more of licorice saponins other than (A), more preferably 9% by mass or more. (B) preferably contains 2% by mass or more of licorice saponin H2, 0.5% by mass or more of licorice saponin G2, and 0.5% by mass or more of macedonoside A. (B) As a component, licorice saponin H2, licorice saponin G2, and licorice saponins other than macedonoside A may be included.

The licorice extract preferably contains (C) licorice flavonoids in an amount of 4% by mass or more, more preferably 19% by mass or more. (C) The licorice flavonoids preferably include liquiritin apioside, liquiritin, liquiritigenin, isoliquiritin apioside, isoliquiritin, and isoliquiritigenin. (C) As a component, other licorice flavonoids may be included.

The licorice extract used in the supplement of the present invention is a licorice extract such as a licorice extract obtained by extracting, separating and purifying components of licorice. The form of the licorice extract is not limited, and may be starch syrup, viscous liquid, liquid, suspension, powder, granules, tablets, spheres, dumplings, etc., and may be selected according to properties and applications. The form of the licorice extract is preferably powder.

As an example of the licorice extract used in the supplement of the present invention, an example of a method for producing a licorice extract will be described. The production process of the licorice extract used in the supplement of the present invention preferably includes at least one or more of steps A to C.

Process A
Step A is a step of obtaining an extract from licorice roots. One or more licorice roots are dried and crushed, and water and ammonia are added to obtain an extract from the licorice roots. Sulfuric acid is added to the extract for precipitation, and the viscous extract and the supernatant are separated. The viscous extract is dried, and the resulting primary extract is used as a licorice extract (concentrated licorice).

Process B
Step B is a separation and purification step. The concentrated licorice obtained in step A is dissolved in an aqueous ethanol solution and filtered to remove insoluble matter. Ammonia is added to the obtained extract to crystallize the licorice saponin as an ammonium salt, which is filtered to separate the crystals and the extract mother liquor. The extracted mother liquor is concentrated under reduced pressure, ethanol is recovered, and sodium carbonate is added to adjust the pH to 6-7. The resulting concentrate is dried by spray drying and mixed to obtain a licorice extract.

Process C
Process C is another separation and purification process. Activated charcoal is added to the extracted mother liquor obtained in step B to remove impurities, and the resulting liquor is dried by spray drying to obtain a licorice extract.

The licorice extract may optionally be packaged.

Extraction solvents for the licorice extract are not limited, and water, alcohols (eg, methanol, ethanol, n-propanol, n-butanol, etc.), acetone, ethyl acetate, and the like can be used. In addition, in the case of obtaining a dry powder, a known method such as drying under reduced pressure or spray drying can be applied to the licorice extract described above.

In the preparation of the licorice extract, steps A to C can be repeated and/or omitted so as to obtain the desired concentration of each component. Further, the licorice extracts obtained in the respective steps A to C can be mixed to obtain a new licorice extract so that each component has a desired concentration.

The licorice extract obtained in this way can be used as a supplement as it is or by adding other ingredients or additives to the licorice extract. For example, a licorice extract and licorice root powder obtained by pulverizing dried licorice root may be combined and used as a supplement as a processed licorice product. A supplement can be used by adding it to a feed as a feed additive.

Necessary for maintaining and improving the health of mammals or domestic animals by adding the licorice extract used in the supplement of the present invention as it is or by adding other ingredients and additives to feed as a feed additive. It is possible to impart multiple functions to the feed at the same time. The content of licorice extract in the supplement of the present invention may be 100% by mass.

In the present invention, mammals are, without limitation, monkeys, dogs, cats, goats, sheep, pigs, cows, guinea pigs, rabbits, mice, rats or humans, preferably cows. In the present invention, domestic animals include mammals as well as birds such as chickens, pigeons, and domestic ducks.

For the purposes of the present invention, feed means any compound, preparation, mixture or composition suitable or intended for ingestion by mammals or livestock. In the present invention, a feed additive is an additive that is added to a feed (feed) used for the purpose of providing nutrition for livestock and the like, and is used as a feed quality maintenance and supplementary nutrition.

The dosage form of the supplement is not limited, and may be starch syrup, viscous liquid, liquid, suspension, powder, granules, tablets, spheres, dumplings, etc., and may be selected according to properties and applications.

When the supplement of the present invention is used as a feed additive, the content of the licorice extract in the feed additive is not limited, and is preferably 1 g/day/head or more and less than 10 g/day/head. is preferred, and 5 g/day/head or less is more preferred. Conventionally, licorice extract used as a feed additive was added in an amount of, for example, 10 to 40 g/day/head. can be given.

The supplement may optionally contain soluble dietary fiber. Water-soluble dietary fiber forms a viscous sol when added to water. Examples of water-soluble dietary fiber include, but are not limited to, Plantago ovata seed coat (psyllium), carrageenan, xanthan gum, curdlan, pectin, gum arabic, alginic acid, chitin, chitosan, guar gum, glucomannan, gellan gum, tara gum, tamarind gum, tragacanth gum, Pullulan, indigestible dextrin, polydextrose and the like can be used, and glucomannan is preferably used. Glucomannan may be used after being purified with water or water-containing ethanol, and konjac flour may be used as the glucomannan-containing material. Common konjac powder has an average particle size of about 420 μm (through 35 mesh), which is relatively large, but the supplement of the present invention has an average particle size of about 177 μm (through 80 mesh). It is preferred to use powdered or powdered glucomannan. By doing so, the surface area of the particles is increased, the affinity with water is increased, and the swelling rate of glucomannan is increased. Addition of glucomannan can enhance the intestinal regulation effect of the processed licorice product.

The licorice extract and water-soluble dietary fiber are preferably contained in the supplement of the present invention at a mass ratio of licorice extract:water-soluble dietary fiber of 10:90 to 40:60.

The supplement of the present invention preferably further contains a starch hydrolyzate. When starch decomposition products are included, it is preferable that the licorice extract: water-soluble dietary fiber: starch decomposition products are contained at a mass ratio of 10:30:60.

When the supplement containing the licorice extract of the present invention is fed to mammals or domestic animals, it increases the dietary intake of mammals or domestic animals, increases the total cholesterol level in the blood, increases the vitamin A level in the blood, Health status is improved by at least one selected from the group consisting of a decrease in blood GOT value, an increase in body weight, prevention of diarrhea, reduction in the number of days for treatment of diarrhea, prevention of colds, and reduction in the number of days for treatment of colds. Can be paid to improve.

The mammals or livestock to which the supplement containing the licorice extract of the present invention is fed is preferably a livestock for meat production. Feed additives can be fed to improve carcass yield and/or reduce liver waste in meat animals.

(1) The supplement according to the present invention comprises (A) one or more selected from the group consisting of glycyrrhizic acid, glycyrrhizic acid derivatives, glycyrrhetinic acid, and glycyrrhetic acid derivatives, and (B) other than (A) above. A licorice extract containing licorice saponins and (C) licorice flavonoids for at least increasing dietary intake of mammals or livestock, increasing blood total cholesterol levels, and increasing blood vitamin A levels increase, decrease in GOT value in blood, increase in body weight, prevention of diarrhea, reduction in the number of treatment days for diarrhea, prevention of colds, and reduction in the number of treatment days for colds. A supplement for mammals or domestic animals to improve their condition.

(2) The supplement of (1) above is effective at least in increasing the dietary intake of mammals or livestock, increasing the total cholesterol level in the blood, increasing the vitamin A level in the blood, decreasing the GOT level in the blood, It is preferably a supplement for improving the health condition by increasing body weight, preventing diarrhea, reducing the number of days for diarrhea, preventing colds, and reducing the number of days for colds.

(3) In the supplement of (1) above, the mammals or livestock are preferably livestock for meat production.

(4) The supplement of (3) above is preferably a supplement for increasing carcass weight, improving carcass yield, and/or reducing edible liver waste rate.

(5) The supplement of (3) above is preferably a supplement for increasing carcass weight, improving carcass yield rate, and reducing edible liver waste rate.

(6) The supplement of (3) above is preferably a supplement for increasing feed efficiency.

(7) In the supplement described in any one of (1) to (6) above, (B) preferably contains licorice saponin H2, licorice saponin G2, and macedonoside A.

(8) In the supplement of (7) above, (C) licorice flavonoids preferably include liquiritin apioside, liquiritin, liquiritigenin, isoliquiritin apioside, isoliquiritin, and isoliquiritigenin.

(9) The supplement of (8) above preferably contains 10% by mass or more of (A) and/or 3% by mass or more of (B) and/or 4% by mass or more of (C).

(10) In the supplement of (9) above, (B) contains 2% by mass or more of licorice saponin H2, 0.5% by mass or more of licorice saponin G2, and 0.5% by mass or more of macedonoside A. preferable.

(11) The supplement described in (10) above preferably contains 14% by mass or more of (A), 9% by mass or more of (B), and 19% by mass or more of (C).

(12) Preferably, the supplement of (7) above optionally contains water-soluble dietary fiber.

(13) The supplement of (12) above preferably contains licorice extract and water-soluble dietary fiber in a weight ratio of licorice extract:water-soluble dietary fiber=10:90 to 40:60.

(14) In the supplement of (13) above, the water-soluble dietary fiber is preferably glucomannan.

(15) The method of improving the health of livestock for meat production according to the present invention comprises: (A) one or more selected from the group consisting of glycyrrhizic acid, glycyrrhizic acid derivatives, glycyrrhetinic acid, and glycyrrhizic acid derivatives; and (B) licorice saponins other than (A) above, and (C) licorice flavonoids. At least, increase in dietary intake of mammals or livestock, increase in blood total cholesterol level, increase in blood vitamin A level, decrease in blood GOT level, increase in body weight, prevention of diarrhea, treatment of diarrhea A method of improving the health of livestock for meat production by at least one selected from the group consisting of reduced days, cold prevention, and reduced cold treatment days.

(16) The method of (15) includes at least increasing the amount of food intake of mammals or domestic animals, increasing the total cholesterol level in the blood, increasing the level of vitamin A in the blood, decreasing the GOT level in the blood, It is preferable to improve the health of mammals or livestock by increasing body weight, preventing diarrhea, reducing days of diarrhea, preventing colds, and reducing days of colds.

(17) The method (15) or (16) is preferably a method for increasing carcass weight, improving carcass yield, and/or reducing edible liver waste rate.

(18) The method (15) or (16) above is preferably a method for increasing the carcass weight, improving the carcass yield rate, and reducing the edible liver waste rate.

(19) The method (15) or (16) above is preferably a method for increasing feed efficiency.

(20) In the method of (15) above, the feed is preferably 5 g/day/pig or less.

A licorice extract as an example of the supplement of the present invention and a method for improving the health of livestock for meat production using the licorice extract will now be described in more detail.

<Production of licorice extract>
Using glabra species, uralensis species and inflata species as licorice, a licorice extract was produced by the following steps. Examples 1, 2, 4, 5, 7, 8 and Comparative Example 1 used glabra species. Inflata species were used in Example 9. In Example 3, glabra and uralensis species were used. In Examples 6 and 10, glabra and inflata species were used.

Process A
One, two, or three licorice roots were dried and crushed. Approximately 8 to 10 L of normal temperature water and ammonia water were added to 1 kg of pulverized licorice root for extraction to obtain an extract. At that time, the amount of ammonia water to be added was adjusted so that the pH was around 9. Sulfuric acid was added to the obtained extract to precipitate the components, and the viscous extract and the supernatant (supernatant) were separated. At that time, the amount of sulfuric acid was adjusted so that the pH of the precipitated sludge was around 1.8. The separated viscous extract was dried, and the resulting primary extract was used as a licorice extract (concentrated licorice). Step A was repeated as necessary until the desired ingredient content was obtained.

Process B
600 to 800 mL of about 90% ethanol was added to 100 g of the concentrated licorice obtained in step A for extraction, and the mixture was filtered to remove unnecessary substances to obtain an extract. The extract was heated to 50-60° C. and ammonia was added to crystallize licorice saponin as an ammonium salt. After cooling to room temperature, the ammonium salt of licorice saponin was removed by centrifugation to obtain an extract mother liquor (licorice extract). At that time, the amount of ammonia water to be added was adjusted so that the pH of the crystallization sludge was around 5. The steps up to this point were repeated as necessary until the desired component content was obtained. The extracted mother liquor (licorice extract) was concentrated under reduced pressure, ethanol was recovered, and the remaining liquid was made about 100 mL. Sodium carbonate was added to the extract mother liquor (licorice extract) concentrated under reduced pressure to adjust the pH to 6-7. The resulting liquid was dried by spray drying to obtain a licorice extract.

Process C
Activated charcoal was added to the extracted mother liquor (licorice extract) obtained in step B to remove impurities, and this step was repeated once or twice to obtain an extracted mother liquor (licorice extract). The resulting liquid was dried by spray drying to obtain a licorice extract.

The licorice extracts obtained in each step of steps A to C were mixed as necessary so that the content of each component was the desired amount.

The licorice extracts of Examples 1-6 were produced by steps A and B. The licorice extracts of Examples 7 and 8 were produced by mixing the licorice extracts obtained in each of steps A to C. The licorice extracts of Examples 9 and 10 were produced by process A. The licorice extract of Comparative Example 1 was produced by steps AC.

<Measurement of components in licorice extract>
(A) glycyrrhizic acid selected from the group consisting of glycyrrhizic acid, glycyrrhizic acid derivatives, glycyrrhetinic acid, and glycyrrhetic acid derivatives of the licorice extract of each example and comparative example, and (B) Licorice saponin H2, Licorice saponin G2, and Macedonoside A were measured by HPLC analysis under the following conditions.

<Preparation of sample for measurement>
Samples for measurement were prepared according to (1) for the water-soluble licorice extract and (2) for the water-insoluble licorice extract.

(1) Licorice extract soluble in water About 200 mg of a sample was weighed, and water was added to make exactly 100 mL to prepare a sample solution. Separately, analysis was performed by liquid chromatography using a standard solution prepared using a glycyrrhizic acid standard. However, the sampling amount of the sample was corrected in terms of % of dry matter.

ＡＴ：試料溶液の面積 ＡＳ：標準溶液の面積
ＷＳ：標準溶液濃度 ＷＴ：乾燥物換算した試料溶液濃度 (2) Water-insoluble licorice extract 0.1 g of a sample was weighed out, and 3 drops of ammonia water (28%) and water were added to make exactly 50 mL to obtain a sample solution. Separately, a standard solution was prepared by adding dilute ethanol to a glycyrrhizic acid standard. Analysis was performed by liquid chromatography using standard solutions. However, the sampling amount of the sample was corrected in terms of % of dry matter by Equation (1).

AT: Area of sample solution AS: Area of standard solution WS: Standard solution concentration WT: Sample solution concentration converted to dry matter

<Measurement of glycyrrhizic acid>
The test conditions for measuring glycyrrhizic acid (high-pressure HPLC (LC1290 manufactured by Agilent Technologies)) were as follows.
Detector: UV absorption photometer (measurement wavelength 254 nm)
Column: Tosoh TSK Gel ODS80TsQA
Column temperature: constant temperature around 30 ° C. Flow rate: adjusted so that the retention time of glycyrrhizic acid was about 7 to 8 minutes Mobile phase: 2% acetic acid: acetonitrile = 60:40
Injection volume: 20 μL

<Measurement of licorice saponins>
The test conditions for measuring licorice saponins (high-pressure HPLC (LC1290 manufactured by Agilent Technologies)) were as follows.
Detector: UV absorption photometer (measurement wavelength: 254 nm)
Column: TSK Gel ODS80TsQA
Column temperature: constant temperature around 30°C Flow rate: 0.8 mL/min Mobile phase: Mobile phase A: 0.1% formic acid (water) / mobile phase B: 0.1% formic acid (acetonitrile)
Injection volume: 20 μL
The mobile phase concentration gradient varied the flow ratio A:B from 90:10 (0-3 min) to 10:90 (3-60 min).

<Measurement of licorice flavonoids>
The licorice flavonoids of each example and comparative example were measured by HPLC analysis under the following test conditions. Samples for measurement were prepared in the same manner as for the measurement of glycyrrhizic acid and other licorice saponins described above. Standard solutions include glycyrrhizic acid standard solution (measurement wavelength 254 nm), liquiritin standard solution (measurement wavelength 280 nm), isoliquiritigenin standard solution (measurement wavelength 355 nm), isoliquiritin standard solution (measurement wavelength 355 nm). was used to perform gradient analysis of the sample solution and standard solution by liquid chromatography to determine the flavonoid content. However, it was corrected by % of dry matter conversion of the sample.

The measurement conditions (HPLC for high pressure (LC1290 manufactured by Agilent Technologies)) were as follows.
Detector: UV absorption photometer (measurement wavelength: 280 nm, 355 nm)
Column: TSK Gel ODS80TsQA
Column temperature: constant temperature around 30°C Flow rate: 0.8 mL/min Mobile phase: Mobile phase A: 0.1% formic acid (water) / mobile phase B: 0.1% formic acid (acetonitrile)
Injection volume: 20 μL
The mobile phase concentration gradient varied the flow ratio A:B from 90:10 (0-3 min) to 10:90 (3-60 min).

Table 1 shows the main components of the obtained licorice extract. In addition, "%" in Table 1 means mass %.

In order to confirm the effects of the licorice extract of the present invention, the following tests were conducted on cattle, which are mammals or livestock for meat production.

Test 1. From the age of 5 days to about 240 days to about 270 days After birth, the calves are breast-fed with high-concentration milk replacer, and then gradually weaned from about 80 days after birth and switched to feed feeding. . High concentrations of milk replacer overwhelm the digestive system, leading to low and variability in feed intake. In addition, the reduction and variation in feed intake also occur due to the stress caused by environmental changes when moving from the suckling frame to the feed growing frame at the time of weaning, the stress caused by group feeding, and the stress caused by switching from milk replacer to compound feed or roughage. Such burden on the digestive tract, stress, reduced or uneven feed intake can delay the development of the digestive system, eg, the development of the rumen in the stomach. Decreased or uneven feed intake and delayed development of the digestive system retard growth and reduce feed efficiency.

Therefore, by feeding the licorice extract of the present invention as a supplement (feed additive) to calves from 5 days old to about 240 days old to about 270 days old, the amount of leftover feed at weaning can be reduced. The effects of the licorice extract of the present invention on reduction (increase in food intake), nutritional status (blood test total cholesterol, vitamin A, GOT) and body weight were investigated.

In general, weaning at about 90 days of age is a guideline, and from about 80 days of age, while gradually reducing the amount of milk replacer and feed, the feeding amount of rice straw, oat hay, and mixed feed is increased. However, in this study, the animals were completely weaned at about 80 days of age in order to clearly confirm the effect of the licorice extract.

Subjects are 30 Japanese black male calves and 30 female calves from the age of 5 to 10 days after birth to the age at the time of calf market shipment (241 to 261 days for males, 246 to 291 days for females). A total of 60 heads. They were divided into three groups shown in Table 2.

In the KS group, the licorice extract of Example 5 was added to the feed as a feed additive from about 5 days after birth, and in the K group, the licorice extract of Comparative Example 1 was added to the feed as a feed additive. No licorice extract was added to the diet of the non-feeding group. For feeds other than licorice extract (milk substitute, artificial milk, mixed feed, roughage such as pasture), the feeds shown in Table 3 (feed per male) and Table 4 (feed per female) are used. Divided into 3 times a day, after 81 days of age, mixed feed, rice straw and oat hay were given in that order, and the same amount was fed to each group at the same time. Feeding feed and oats hay were given from about 2 weeks after birth.

In the KS section, 1 g/day/head from about 5 days after birth, 2 g/day/head from about 41 days after birth, and 3 g/day/head from about 81 days after birth to about 240 days to about 270 days. The licorice extract was added to the feed as a feed additive and fed. In section K, 1 g/day/pig from about 5 days after birth, 2 g/day/pig from about 41 days after birth, and 3 g/day/pig from about 81 days after birth to about 240 days to about 270 days of Comparative Example 1. The licorice extract was added to the feed as a feed additive and fed.

1.1 Amount of leftover food As described above, after about 81 days of age, feed was fed in the order of compound feed, rice straw, and oats hay. Therefore, the remaining feed weight of the oats was measured as the amount of leftover food. The first day of weaning at about 81 days of age was defined as the first day, and changes in the amount of leftover food are shown in FIGS.

As shown in FIG. 1, in the KS group, the male continued to eat all the food without leftovers from the first day of weaning. In group K, the rats finished eating once in two days on the 8th and 9th days, but leftovers occurred again, and it took 11 days to continue eating. It took 14 days for the non-feeding group to continue eating completely.

As shown in Fig. 2, in the KS section, females completely ate on the 1st day (about 81 days old) and 3rd day of weaning, leftover food on the 2nd and 4th days, and finished eating from the 5th day. Continued. Group K continued to complete the meal from the 12th day, showing variation in the completion of the meal. In the non-feeding group, it took 15 days to continue eating.

In the KS group in which the licorice extract of Example 5 was fed from about 5 days after birth, the effect of feeding the licorice extract was apparent from the time of weaning at about 81 days of age. A high effect was confirmed even compared with the K section to which the licorice extract containing 13% or more of glycyrrhizic acid was fed. A synergistic effect of the contained glycyrrhizic acid, licorice saponins, and licorice flavonoids was confirmed.

As mentioned above, feed intake is thought to reflect calf stress, gastrointestinal burden, and the degree of gastrointestinal development. In the KS section, where cattle are completely fed immediately after weaning and the amount of feed intake is high, compared to the K section and the non-feeding section, the stress on the cows is reduced, the burden on the digestive organs is small, and the digestive organs are considered to be in a well-developed state. .

1.2 Blood test results (total cholesterol level, VA level, GOT level)
In order to understand the nutritional and metabolic conditions of the cows, blood tests were performed to measure total cholesterol, vitamin A (VA), and GOT levels. Total cholesterol levels reflect overall nutritional status. The VA value is related to growth and development, and vitamin A deficiency leads to developmental disorders and weakened immunity. The GOT value serves as a judgment material for acute liver damage and organ damage. Especially when the GOT value is high, liver disease is suspected.

Blood tests (total cholesterol level, VA level, GOT level) of all cows were performed twice at about 40 days and about 160 days after birth.

Figures 3 to 6 (total cholesterol level), Figures 7 to 10 (VA values), and shown in FIGS. 11 to 14 (GOT values).

As shown in FIGS. 3 to 6, in the KS group to which the licorice extract of the present invention was fed from about 5 days after birth before weaning, both males and females were about 40 days old and about 160 days old. However, the numbers are higher than in other districts. A high total cholesterol level is thought to indicate good nutritional intake and accelerated metabolism. On the other hand, malnutrition is suspected in the no-salary district. Malnutrition weakens the immune system and increases the risk of disease. It was found that the licorice extract of the present invention can improve nutritional status and metabolism.

As shown in FIGS. 7 to 10, VA values were high in both males and females in the KS section. Vitamin A is an essential ingredient for growth, and the VA value affects body weight gain (weight gain of livestock). However, since VA cannot be synthesized in the body, it must be taken into the body through food. When VA is extremely low, developmental disorders and a decrease in immunity may occur, and diseases such as colds and diarrhea may develop. In the KS section, the VA value was higher than the other sections at both about 40 days and about 160 days after birth, and it was especially higher at about 160 days after birth compared to the other sections, and the KS section increased body weight. has been shown to be advantageous for It was found that the licorice extract of the present invention can increase and maintain the VA value necessary for weight gain.

As shown in FIGS. 11 to 14, in the KS group, the GOT values were lower than those in the other groups at both the time points of about 40 days after birth and about 160 days after birth. Furthermore, in the KS group, the GOT value was lower at about 160 days after birth than at about 40 days after birth. On the other hand, in the K section, the GOT values at about 40 days old and about 160 days old were almost the same. In the non-feeding group, a blood test at about 40 days after birth showed a higher GOT value than in the other groups, and a higher GOT value was confirmed at about 160 days after birth. It was found that the licorice extract of the present invention has the effect of enhancing liver function.

From the above results, the licorice extract of the KS section containing licorice flavonoids and licorice saponins other than glycyrrhizic acid (Example 5) was higher than the licorice extract of the K section containing a large amount of glycyrrhizic acid (Comparative Example 1). ) is not due to the effect of glycyrrhizic acid, but the combined effect of glycyrrhizic acid, other licorice saponins, and licorice flavonoids can improve nutritional status, metabolism (total cholesterol level), growth status (vitamin A level), liver function ( GOT value).

1.3 Body Weight Cattle must be weighed individually at the auction market before being shipped to the auction market. Figures 15 to 18 show the average weight of 10 males and females of each group measured at the time of shipment to the auction market, and the average values of 8 males and 8 females excluding the two highest and lowest values among the 10 males and females. In addition, there is a slight difference in the age at the time of shipment because the auction market is held only on certain days.

As shown in FIGS. 15 to 18, both males and females weighed more in the KS section than in the other sections. As described above, by feeding the licorice extract of the present invention as a feed additive, the KS group has a higher feed intake than the other groups, and the nutritional status, metabolism, growth status, and liver function are good. It is thought that this can prevent the occurrence of diseases without lowering strength, and can prevent, for example, anorexia and decreased food intake due to diseases, leading to body weight gain.

A high body weight gain shortens the age of shipment to the auction market, that is, shortens the breeding period, which leads to a reduction in expenses such as labor costs and feed costs. In addition, in the KS section, the K section, and the non-feeding section, although the same type and amount of feed other than the licorice extract were fed, the body weight gain was greater in the KS section than in the other sections. It can be seen that feed efficiency can be increased by feeding licorice extract as a feed additive.

From about 5 days old to about 240 days old to about 270 days old, there are a nursing period, a weaning period, and a subsequent growth process, and the type of feed, the contents of feeding, and the feeding method change. It is known that cows feel strong mental and physical stress due to minor changes in the environment, causing changes in their physical condition. were able to reduce the adverse effects on feed intake, nutritional status, metabolism, growth and liver function, and were able to increase body weight.

Test 2. From the introduction of fattening to carcass market shipment Calves that are shipped from breeding farmers to the auction market are then introduced to fattening farmers. During this period, the calves are transported by truck from the breeding farm to the calf auction venue, and after winning the bid to purchase the auction, the calves are transported by truck to the farm of the new fattening farm. It is stressed by environmental changes caused by Long-distance trips from markets in Hokkaido to farms in Kagoshima, Miyazaki, etc. are common. In addition, stress caused by changes in the type and amount of feed supplied from the day it was introduced to the fattening ranch, heat stress and cold stress (stress during hot and cold periods), group feeding, etc. There is also stress. These stresses can adversely affect a cow's feed intake, nutritional status, metabolism, development and liver function. In addition, at the time of introduction to the fattening farm, the digestive and visceral organs, especially the liver function, were damaged due to the high-concentration compound feed and various additives that were already being fed for the purpose of weight gain. many.

Therefore, by feeding the licorice extract of the present invention as a feed additive to cattle from the introduction of fattening to the time of shipment to the carcass market for the purpose of sale, the amount of leftovers at the time of introduction of fattening, the nutritional status (total blood test results) Cholesterol level, vitamin A level, GOT level), body weight, liver waste rate, carcass weight and carcass yield rate were investigated.

The subjects were 30 Japanese Black male cattle aged about 9 months to about 10 months (266 days to 308 days after birth) and about 9 months to about 10 months (274 days to 304 days after birth). age), 30 Japanese Black female cattle, 60 in total. Based on the results of body weight measured at the time of purchase at the calf auction market, the animals were divided into three groups shown in Table 5 so that individual body weights and ages in each section were approximately equal.

In the KS group, the licorice extract of Example 5 was added to the feed as a feed additive, and in the K group, the licorice extract of Comparative Example 1 was added to the feed as a feed additive. No licorice extract was added to the diet of the non-feeding group. Feeds other than licorice extract were divided into three times a day, and the same amount was given to each group as shown in Table 6 (feed per male) and Table 7 (feed per female). were paid at the same time. After introduction to the fattening farm, they were fed in the order of compound feed, rice straw, beer dregs, and oats hay until they were completely fed.

In the KS section, 3 g/day/head of the licorice extract of Example 5 was added to feed as a feed additive for about 19 months from the day of introduction to the fattening ranch. In group K, 3 g/day/head of the licorice extract of Comparative Example 1 was added to the feed as a feed additive for about 19 months from the day of introduction to the fattening ranch.

2.1 Amount of leftover food As described above, since the feeds were fed in the order of mixed feed, rice straw, beer dregs, and oats hay, oats became the leftover feed when leftover feed occurred. Therefore, the remaining feed weight of the oats was measured as the amount of leftover food. 19 to 20 show changes in the amount of leftover food.

As shown in FIG. 19, males took 5 days to complete feeding in the KS group, 9 days in the K group, and 14 days in the non-feeding group.

As shown in FIG. 20, females took 4 days to complete feeding in the KS group, 10 days to complete feeding in the K group, and 14 days to complete feeding in the non-feeding group, like males.

Even if the feeding of the licorice extract of the present invention was started after the introduction of fattening, a high effect was confirmed compared to the K section in which the licorice extract containing 13% or more of glycyrrhizic acid was fed. A synergistic effect of glycyrrhizic acid, licorice saponins, and licorice flavonoids contained in the licorice extract was confirmed.

In the KS area, where cattle are completely fed immediately after the introduction of fattening and the amount of feed intake is high, compared to the K area and the no-feed area, the stress on the cattle is reduced, the burden on the digestive organs is small, and the digestive organs are functioning and in good condition. Conceivable.

2.2 Blood test results (total cholesterol level, VA level, GOT level)
Blood test (total cholesterol level, VA level, GOT level) of all cattle was conducted three times at the time of introduction to the fattening farm, 6 months after introduction, and 12 months after introduction, total cholesterol level, GOT level, VA level was measured.

Figures 21 to 24 (total cholesterol level), Figures 25 to 28 (VA values), and shown in FIGS. 29 to 32 (GOT values).

As shown in FIGS. 21 to 24, the total cholesterol level was high in the KS section for both males and females. From these results, it can be seen that the amount of feed intake was higher in the KS section than in the other sections after the introduction of fattening, as described above, and in addition, the digestion and absorption and metabolism of the ingested feed were good.

As shown in FIGS. 25 to 28, the VA value was also high in the KS section for both males and females. Compared to the introduction of fattening, the VA value decreased in all plots after 6 months and 12 months, but in the KS plot, it remained almost the same or even improved after 6 months and 12 months. bottom. On the other hand, in the K section and the non-feeding section, the VA value further decreased from 6 months to 12 months later.

As shown in FIGS. 29 to 32, both males and females in the KS section had lower GOT values than those in the other sections at both 6 and 12 months after the introduction of fattening. In the K section and the non-feeding section, the GOT value increased 6 months after the introduction of fattening, and the GOT value further increased 12 months after the introduction.

From the above results, even if the supply of the licorice extract of the present invention is started after the introduction of fattening, the combined effects of glycyrrhizic acid, other licorice saponins, and licorice flavonoids will improve nutritional status and metabolism (total cholesterol level). , has a positive effect on the developmental state, immunity (vitamin A level), and liver function (GOT level).

2.3 Body Weight Body weight and weight gain were measured at the introduction of the fattening farm and upon arrival at the carcass market. The weight measured at the calf auction market was used as the weight at the introduction of the fattening farm. The body weight measured upon arrival at the carcass market from the fattening farm was taken as the body weight upon arrival. The difference between the body weight at introduction and the body weight at arrival was taken as the body weight gain.

As shown in Figures 32 to 38, both males and females had the highest body weight upon arrival and body weight gain in the KS section. The large weight gain is considered to be due to the following virtuous cycle. In other words, as described above, the KS group has a higher feed intake from an earlier period after the introduction of fattening than the other groups. Even if there is, it is difficult to be adversely affected by stress, and the state of internal organs such as the digestive system can be maintained in good condition. As a result, diseases can be prevented, and anorexia due to diseases can also be prevented. In this way, it is considered that the amount of feed intake is stably increased in the KS section, and a greater body weight gain than in the other sections can be obtained by the time of shipment to the carcass market.

As described in Test 1, in the KS group, the K group, and the non-feeding group, although the same type and amount of feed was fed except for the licorice extract, the KS group gained more weight than the other groups. From the above, it can be seen that the feed efficiency can be increased even if the feeding of the licorice extract of the present invention as a feed additive is started after the day of introduction to the fattening farm.

2.4 Waste rate of edible liver The waste rate of edible liver at the time of slaughter was confirmed. Discarding edible liver causes economic losses. Liver lesions such as shaving liver and liver hemorrhage at the time of carcass market shipment are caused by the increased burden on the liver during the fattening period. Fewer liver lesions indicate that liver function was maintained in a healthy state.

As shown in FIGS. 39 to 40, in both males and females, the proportion of discarded edible liver in the KS section was significantly lower than in the other sections. The edible liver waste rate in the K group fed with licorice extract containing 13% or more of glycyrrhizic acid was almost the same as that in the non-feeding group. It was found that the licorice extract of the present invention is very effective in maintaining healthy liver function.

2.5 Carcass Weight/Yield Rate Carcass weight was measured at the carcass market. In addition, the carcass yield rate ((carcass weight/weight at carcass market arrival)×100) was calculated from the carcass weight and the carcass weight at the time of carcass market arrival. Carcass refers to a state in which the head, skin, internal organs, blood, etc. are removed from a living body, and is an edible part.

As shown in FIGS. 41 and 42, it can be seen that the carcass weight, which is the edible portion, is larger in the KS section than in the other sections. Furthermore, as shown in FIGS. 43 to 46, the carcass yield is higher in the KS section than in the other sections. Even if the weight gain is good, if the yield rate is not good, carcasses cannot be obtained for the weight. By feeding the licorice extract of the present invention, it is possible to maintain a stable high feed intake and the health of the digestive organs and liver from an early stage after the introduction of fattening. is considered to have brought about an improvement in

As described above, in the KS section, the K section, and the non-feeding section, although the same type and amount of feed was fed except for licorice extract, the carcass weight and carcass yield rate were lower in the KS section than in the other sections. From the large value, it was confirmed that the feed efficiency can be increased even if the feeding of the licorice extract of the present invention as a feed additive is started after the day of introduction to the fattening farm.

Test 3. Feed only for 10 days from the introduction of fattening As described in “Test 2. From the introduction of fattening to carcass market shipment”, calves at the time of introduction to the fattening farm are particularly stressed by movement and environmental changes. In addition, at the time of introduction to fattening farms, internal organs such as digestive organs, liver functions, etc. have already been damaged by the diet for the purpose of increasing body weight. Therefore, licorice extract was fed only for 10 days from the day of introduction to the fattening farm, and the amount of leftover feed, the number of days until the feed was completely consumed, and the nutritional status (blood test total cholesterol level, vitamin A level, GOT) were measured. value) was investigated.

The subjects were 36 Japanese Black male cattle aged between 9 and 10 months (275 to 308 days old) purchased at the calf auction market for the purpose of fattening and introduced to a fattening farm. There were 36 Japanese Black female cows aged 1 month to about 10 months (279 days to 309 days after birth). From the time of introduction to the fattening farm, both males and females were divided into three groups as shown in Table 8, 1 frame of 4 animals x 3 frames = 12 animals in each section.

In the KS group, the licorice extract of Example 5 was added to the feed as a feed additive, and in the K group, the licorice extract of Comparative Example 1 was added to the feed as a feed additive. No licorice extract was added to the diet of the non-feeding group. The feed other than licorice extract is 3.0 kg of mixed feed per head for males, 0.4 kg of rice straw, 2.0 kg of beer dregs (50% moisture content), 6.0 kg of oats hay, and 6.0 kg of mixed feed for females. 3.0 kg of rice straw, 0.4 kg of rice straw, 2.0 kg of beer dregs (50% moisture content), and 5.0 kg of oat hay were divided into three times a day, and the compound feed, rice straw, beer dregs, and oat hay were given in that order. Groups were fed the same amount at the same time. In order to confirm the increase in feed intake and foraging ability, the amount of feed additive (licorice extract) was increased more than usual.

In the KS section, 5 g/day/head of the licorice extract of Example 5 was added to the feed as a feed additive for 10 days from the day of introduction to the fattening farm. In group K, 5 g/day/head of the licorice extract of Comparative Example 1 was added to feed as a feed additive for 10 days from the day of introduction to the fattening farm. The study was terminated after 10 days.

3.1 Amount of leftover food and number of days until completion As described above, since the feeds were fed in the order of compound feed, rice straw and oat hay, when leftover feed was generated, oat hay was leftover feed. Therefore, the remaining feed weight of the oats was measured as the amount of leftover food. Figures 47 and 48 show changes in the amount of leftover food, and Figures 49 and 50 show the number of days to complete the meal.

As shown in FIGS. 48 to 52, it took 3 days for all 12 male fattening cattle to eat in the KS section, 8 days in the K section, and 10 days in the non-fed section. The average number of days until the males finished eating was 2.66 days in the KS group, 7.66 days in the K group, and 8.33 days in the non-feeding group. It took 4 days for all 12 female fattening cattle to finish eating in the KS section, and 9 days in the K section. The average number of days until completion of eating was 3.66 days in the KS group and 8.66 days in the K group (no feeding group did not finish eating in 10 days).

From these results, it can be said that the licorice extract of the present invention can improve the stress of calves at the time of introduction of fattening, and can improve internal organs and liver functions. Also, by reducing the amount of calf leftovers when fattening is introduced, body weight gain can be achieved from an early stage after the introduction of fattening.

Since Test 3 was conducted only for 10 days after the introduction of fattening, fattening was still in progress at the end of the test (10 days after the introduction of fattening). The weight-to-weight ratio (feed efficiency) is also unknown. However, as in Tests 1 and 2, in the KS group, the K group, and the non-feeding group, although the same type and amount of feed other than the licorice extract was fed, the KS group left more food than the other groups. Since the amount is small (the amount of food intake is large) and the number of days to complete the meal is short, even if the licorice extract of the present invention is fed as a feed additive only for 10 days after the introduction of the fattening ranch, the feed efficiency is improved. can be increased.

Test 4. From about 91 days of age to about 150 days of age As described above, calves are generally weaned at about 90 days of age. During the period from about 91 days after weaning to the time the calf is shipped to the market, the digestive system is overloaded, burdened, or stressed, which reduces feed intake and delays the development of the digestive system. . A vicious circle occurs in which feed intake decreases due to delayed development of the digestive system. This leads to weight gain and reduced feed efficiency.

Therefore, by feeding the licorice extract of the present invention as a feed additive to cattle aged from about 91 days to about 150 days after birth, the amount of leftover food and nutritional status (blood test totals) of the calves after weaning The effect of the licorice extract of the present invention on cholesterol level, vitamin A level, GOT level) was investigated.

Subjects were 30 Japanese Black male calves and 30 female calves from about 91 days old to about 150 days old, totaling 60 calves. They were divided into three groups shown in Table 9. Here, the first blood test was performed at the age of about 70 days after birth before weaning, and the animals were divided into 3 groups so that the average values of total cholesterol, VA, and GOT values measured by the blood test were equal. . Among these values, the section with the highest average GOT value was designated as the KS section.

In the KS group, the licorice extract of Example 5 was added to the feed as a feed additive, and in the K group, the licorice extract of Comparative Example 1 was added to the feed as a feed additive. No licorice extract was added to the diet of the non-feeding group. Feeds other than licorice extract (milk replacer, feeding feed, mixed feed, oat hay) were fed the feeds shown in Table 10 (feed per male) and Table 11 (feed per female) for one day. After about 91 days of age, the same amount was fed to each group at the same time in the order of compound feed and oats hay.

In the KS group, 3 g/day/head of the licorice extract of Example 5 was added to the feed as a feed additive and fed from about 91 days to about 150 days after birth. In group K, 3 g/day/head of the licorice extract of Comparative Example 1 was added as a feed additive to the feed from about 91 days to about 150 days after birth.

4.1 Amount of leftover food As described above, after about 91 days of age, the feed was fed in the order of compound feed and oats hay. Therefore, the remaining feed weight of the oats was measured as the amount of leftover food. 51 and 52 show changes in the amount of leftover food.

As shown in FIGS. 51 and 52, in the KS section, the males completely ate the whole meal on the 5th day, and the complete meal continued. In section K, it took 11 days to continue eating completely. In the non-feeding group, more days were required, and it took 14 days to continue eating completely. In the KS section, females finished eating on the 4th day, one day earlier than males, and continued to finish eating after that. In the K section, while showing variations from the 1st to the 9th day, the food was completely eaten on the 13th day and continued to be eaten after that. In the KS section, the number of days required to complete the meal was shorter than in the K section.

It was found that the feeding of the licorice extract of the present invention was effective in improving feed intake even after starting after weaning.

4.2 Blood test results (total cholesterol level, VA level, GOT level)
In order to understand the nutritional and metabolic conditions of the cows, blood tests were performed to measure total cholesterol, vitamin A (VA), and GOT levels.

Blood tests (total cholesterol level, VA level, GOT level) of all cows were performed twice, at approximately 70 days of age and approximately 150 days of age.

Figures 53 to 56 (total cholesterol level), Figures 57 to 60 (VA values), and shown in FIGS. 61 to 64 (GOT values).

As shown in FIGS. 53 to 56, the blood test at approximately 70 days of age before the start of licorice extract feeding showed almost no difference in total cholesterol levels between the groups for both males and females. On the other hand, blood tests at about 150 days of age showed the highest total cholesterol levels in the KS group for both males and females. In the K section, the total cholesterol level was almost the same between the 70-day-old and the 150-day-old, and the total cholesterol level in the non-feeding group was lower at about 150-day-old than at about 70-day-old.

As shown in FIGS. 57 to 60, the VA values in the blood test at about 70 days of age before the start of feeding of licorice extract showed almost no difference between each group for both males and females. had a lower value than On the other hand, blood tests at about 150 days of age showed the highest VA values in the KS section for both males and females. In section K, the VA values were almost the same at about 70 days old and about 150 days old, and the VA value in the non-feeding section was lower at about 150 days old than about 70 days old.

As shown in FIGS. 61 to 64, the GOT value was higher in the KS group than in the other groups in both males and females in a blood test at about 70 days of age before the start of feeding of licorice extract. On the other hand, blood tests at about 150 days of age showed the lowest GOT values in the KS section for both males and females. In section K, the GOT values were almost the same at about 70 days old and about 150 days old, and the GOT value in the non-feeding group was higher at about 150 days old than about 70 days old.

From the above results, even if feeding of the licorice extract of the present invention is started after weaning, the licorice extract of the KS section containing licorice flavonoids and licorice saponins other than glycyrrhizic acid (Example 5) does not contain glycyrrhizin. The combined effects of glycyrrhizic acid, other licorice saponins, and licorice flavonoids, rather than the effects of acids, improve nutritional status, metabolism (total cholesterol level), growth status (vitamin A level), and liver function (GOT level). found to have a positive effect.

Since Test 4 was conducted only from about 91 days of age to about 150 days of age, neither the amount of meat produced nor the weight ratio of the given feed to the amount of meat produced (feed efficiency) is known at the end of the test. However, as in Tests 1 and 2, in the KS group, the K group, and the non-feeding group, although the same type and amount of feed other than the licorice extract was fed, the KS group left more food than the other groups. Since the amount is small (the amount of food intake is large) and the number of days until completion is short, the feeding efficiency can be increased even if the licorice extract of the present invention is fed as a feed additive after weaning. it is conceivable that.

Test 5. Approximately 2 months from about 5 days to about 60 days after birth If the internal organs such as the digestive organs and liver function are overloaded during the suckling period, immunity and metabolism will decrease, and diarrhea and colds will occur. Burden on visceral organs and liver function may be caused by ingestion of high-concentration milk replacers and mixed feeds during the lactation period. In addition, the stress caused by being separated from the mother cow immediately after birth and raised by breeders, the stress caused by changing the type and amount of feed according to growth, the heat stress/cold stress during hot and cold seasons, Stress on the body due to environmental changes such as temperature differences may put a load on internal organs and liver functions, and may lower immunity and metabolism. In particular, calves are underdeveloped, so they are prone to loss of appetite due to stress and stress on internal organs and liver functions, leading to malnutrition, and a vicious cycle of increasing stress and stress on internal organs and liver functions. Yes, it is easy to get diarrhea and colds.

When symptoms of diarrhea occur, treatment such as administration of drugs, administration of antibacterial agents, continuous administration of probiotic agents, etc. is often performed. Diarrhea can deprive the body of water and cause dehydration, and if treatment is prolonged, it can lead to a decline in immunity and resistance, often resulting in the onset of a cold at the same time.

Diarrhea frequently seen in calves is generally classified into two types. One is the ingestion of high-concentration milk and feed, weather conditions such as hot/cold periods and temperature differences, lack of colostrum intake, and changes in diet, etc., which puts a load on the internal organs and digestive organs, resulting in metabolic capacity and immunity. Diarrhea due to indigestion due to weakness. The other is that bacteria, viruses, parasites, etc. are mixed in with good quality drying and feed, and this can be prevented by frequently changing feed, etc., so hygiene management in the barn is the cause. It can also be said that

Therefore, by feeding the licorice extract of the present invention as a feed additive to calves aged from about 5 days to about 60 days after birth, the incidence of diarrhea due to indigestion, the number of days treated for diarrhea due to indigestion, and the number of colds and the effect of the licorice extract of the present invention on the incidence of colds and the number of days of treatment for colds.

The subjects were 150 Japanese black cows and 30 Holstein calves, aged from about 5 days to about 60 days after birth. It was divided into three sections shown in Table 12.

In the KS group, the licorice extract of Example 5 was added to the feed as a feed additive, and in the K group, the licorice extract of Comparative Example 1 was added to the feed as a feed additive. No licorice extract was added to the diet of the non-feeding group. Feeds other than the licorice extract (milk replacer, feeding feed, oat hay) were fed to each group in the same amount at the same time three times a day for both males and females. Feeding feed and oats hay were given from about 2 weeks after birth.

In the KS group, 2 g/day/head of the licorice extract of Example 5 was added as a feed additive to feed from about 5 days after birth to about 60 days after birth. In group K, 2 g/day/head of the licorice extract of Comparative Example 1 was added as a feed additive to feed from about 5 days after birth to about 60 days after birth.

Table 13 and FIG. 65 show the number of cases of diarrhea due to dyspepsia in a total of 180 cattle, and Table 14 and FIG.

As shown in Table 13 and FIG. 65, in the KS section, the incidence of diarrhea up to about 60 days of age was about 52% in the K section and about 42% in the non-feeding section. In addition, in the KS section, the incidence of diarrhea was lower than in the other sections in almost all weeks. It was only in the KS lot that the majority of cows did not have diarrhea.

As shown in Table 14 and FIG. 66, the number of treatment days was shorter in the KS section than in the other sections. It was found that by feeding the licorice extract of the present invention as a feed additive, the occurrence of diarrhea is suppressed, and even if diarrhea occurs, it is less likely to become severe, and recovery is achieved in a relatively short treatment period.

Traditionally, licorice has been used in the herbal medicine Daiokanzoto, and is known to have a laxative effect (cause/cause diarrhea). However, it was confirmed that the licorice extract of the present invention has a new effect that cannot be predicted from the conventional technical common sense of not causing diarrhea.

The licorice extract of the present invention contains not only glycyrrhizic acid but also licorice saponins other than glycyrrhizic acid and licorice flavonoids. As mentioned above, the synergistic effect of these ingredients makes cattle less susceptible to stress, increases feed intake, improves digestion and absorption, immunity and metabolism, and increases body weight. is also thought to be one of the factors that made diarrhea less likely.

Table 15 and FIG. 67 show the number of cold occurrences (number of cows) for a total of 180 cows, and Table 16 and FIG. 68 show the number of cold treatment days.

As shown in Table 15 and FIG. 67, in the KS section, the incidence of colds up to about 60 days of age was about 33% in the K section and about 22% in the non-feeding section. In addition, the number of colds occurring in the KS ward was lower than in the other wards in almost all weeks.

As shown in Table 16 and FIG. 68, the number of treatment days was shorter in the KS section than in the other sections. It was found that by feeding the licorice extract of the present invention as a feed additive, the occurrence of colds is suppressed, and even if a cold does occur, it is less likely to become severe and the patient recovers in a relatively short treatment period.

In addition, both diarrhea and colds occurred over the entire period in the K section and the non-feeding section, but it can be seen that the increase and decrease in the number of occurrences are similar between diarrhea and colds. Cows with weak immunity and resistance tend to develop colds and diarrhea at the same time. By feeding the licorice extract of the present invention as a feed additive, it is possible to prevent both diarrhea and colds, prevent aggravation even when symptoms occur, and reduce the number of treatment days.

Colds in calves are caused by factors such as reduced immunity transferred from mother cows, stress caused by climate and environmental changes, and inadequate hygiene management in cattle barns such as inhalation of ammonia gas and dust due to poor ventilation. Due to these causes, immunity and resistance are weakened and infected with viruses and bacteria to catch a cold. A healthy calf has a body temperature of 38.5-39°C, but when it catches a cold, it shows symptoms such as fever of 39.5-40°C or higher, cough, runny nose, and rapid breathing. In addition, it causes loss of energy, inability to stand up, difficulty in feeding, weakness, and anorexia. In severe cases, death may occur, and even after recovery, stunting may occur, so early treatment and prevention are necessary.

Conventionally, as one method of prevention, colostrum has been given to increase immunity and resistance. However, cows who do not receive enough colostrum or do not eat feed become malnourished. In addition, as mentioned above, ingestion of high-concentration milk and high-concentration feed for the purpose of weight gain puts a burden on internal organs such as digestive organs and liver function, which reduces immunity and resistance. I sometimes catch a cold.

As shown in the results of Tests 1 to 5, the licorice extract of the present invention increases feed intake, improves nutrient digestion and absorption and metabolism, improves growth and immunity, and improves liver function. , and weight gain. By feeding the licorice extract of the present invention as a feed additive, it is possible to prevent nutritional deficiencies and weakened immunity that cause colds, prevent colds, prevent aggravation, and reduce the number of treatment days.

The licorice extract of the present invention increases feed intake, improves digestion and absorption of nutrients and metabolism, improves growth and immunity, improves liver function, increases body weight, increases carcass weight, and improves carcass yield rate. It can be used as a raw material for multifunctional feed additives for the purpose of preventing diarrhea, reducing the number of days treated for diarrhea, preventing colds, and/or reducing the number of days treated for colds.

Test 6. 6. Supply of feed additives containing licorice extract and water-soluble dietary fiber 6.1 Incidence of diarrhea 60 Japanese Black male calves and Japanese Black female calves aged about 5 days to about 60 days after birth A total of 120 pigs, 60 pigs, were examined for the occurrence rate of diarrhea for about 60 days after birth and the number of treatment days until complete recovery.

The subject cattle were divided into feeding and non-feeding groups shown in Table 17. Feed additive A and feed additive B containing the licorice extract of Example 5 were added to the feed and fed to the cattle in the feeding group. No licorice extract was added to the diet of the non-feeding group.

Feed additive A contains 10% by mass of licorice extract of Example 5, 30% by mass of glucomannan (average particle size 150-200 mesh) as water-soluble dietary fiber, and starch decomposition product (Matsutani Chemical Industry Co., Ltd., PA Index #1) was prepared by uniformly mixing 60% by weight.

Feed additive B was prepared by uniformly mixing 40% by mass of the licorice extract of Example 5 and 60% by mass of glucomannan (average particle size: 150-200 mesh) as a water-soluble dietary fiber.

The components of feed additives A and B were as shown in Table 18.

From about 5 days after birth to about 30 days after birth, feed additive A is uniformly dispersed in milk replacer, and 5 g/head is fed twice in the morning and evening, for a total of 10 g/day/head. bottom. From about 31 days after birth to about 60 days after birth, add an appropriate amount of water to feed additive B and form a ball. Paid day/head.

Table 19 shows the number of diarrhea cases (number of animals) and the incidence rate.

As shown in Table 19, the occurrence of diarrhea was suppressed to about 1/3 of the non-feeding group in the feeding group.

6.2 Diarrhea Treatment Days Feed additive A and feed additive B were fed to calves with diarrhea, and the number of treatment days was investigated. Subjects were 36 male calves and 28 female calves with diarrhea, irrespective of age after birth, for a total of 64 calves.

From about 5 days after birth to about 30 days after birth, feed additive A is uniformly dispersed in milk replacer, and 5 g/head is fed twice in the morning and evening, for a total of 10 g/day/head. bottom. From about 31 days after birth to about 60 days after birth, add an appropriate amount of water to feed additive B and form a ball. Paid day/head.

Table 21 shows the number of treatment days for diarrhea and the average number of treatment days.

As shown in Table 21, it was possible to shorten the number of days for treatment of diarrhea to less than 1/3 of the non-feeding group in the feeding group. The feed additive of the present invention, in which glucomannan is added to the licorice extract of the present invention, adds the effects of the licorice extract and the intestinal regulation action of glucomannan, effectively suppressing the occurrence of diarrhea, and reducing the number of treatment days. was made.

As described above, the supplement for mammals or domestic animals of the present invention provides at least an increase in dietary intake of mammals or domestic animals, an increase in total blood cholesterol level, an increase in blood vitamin A level, an increase in blood The health condition can be improved by at least one selected from the group consisting of a decrease in the GOT value of , an increase in body weight, prevention of diarrhea, reduction in the number of days for treatment of diarrhea, prevention of colds, and reduction in the number of days for treatment of colds. was confirmed.

(A) one or more selected from the group consisting of glycyrrhizic acid, glycyrrhizic acid derivatives, glycyrrhizic acid, and glycyrrhizic acid derivatives; (B) licorice saponins other than (A) above; and (C) licorice By feeding mammals or livestock a supplement for mammals or livestock containing a licorice extract containing flavonoids, at least the increase in dietary intake of mammals or livestock and the reduction of total cholesterol levels in the blood. increase, increase in blood vitamin A level, decrease in blood GOT level, increase in body weight, prevention of diarrhea, reduction in diarrhea treatment days, cold prevention, and reduction in cold treatment days At least one selected has been confirmed to improve the health of livestock for meat production.

In addition, as described above, in the tests conducted at any stage of nursing, weaning, and fattening, in the KS group, the K group, and the no feeding group, although the same type and amount of feed was given except for the licorice extract, In the KS section, the amount of leftovers was smaller than in the other sections (the amount of food intake was greater), and the effects of increased body weight and carcass weight, increased carcass yield rate, and decreased edible liver waste rate were observed. It was confirmed that by feeding mammals or livestock with the supplement of the present invention, the weight ratio of fed feed to meat production (feed efficiency) can be increased.

It should be considered that the embodiments and examples disclosed above are illustrative in all respects and not restrictive. The scope of the present invention is indicated by the scope of the claims rather than the above description, and includes all modifications within the scope and meaning equivalent to the scope of the claims.

Claims (19)

(A) one or more selected from the group consisting of glycyrrhizic acid, glycyrrhizic acid derivatives, glycyrrhetinic acid, and glycyrrhetinic acid derivatives;
(B) licorice saponins other than (A);
(C) containing licorice flavonoids,
(B) contains at least licorice saponin H2, licorice saponin G2, and macedonoside A;
(C) is provided by feeding a supplement for mammals or livestock containing a licorice extract containing at least liquiritin apioside, isoliquiritin apioside, and isoliquiritin to mammals or livestock,
mammals or domestic animals,
0.02 g/day/head or more of licorice saponin H2, 0.005 g/day/head or more of licorice saponin G2, and 0.005 g/day/head or more of macedonoside A, and
By giving 0.024 g/day/pig or more of liquiritin apioside, 0.004 g/day/pig or more of isoliquiritin apioside, and 0.003 g/day/pig or more of isoliquiritin,
At least, increase in dietary intake of mammals or livestock, increase in blood total cholesterol level, increase in blood vitamin A level, decrease in blood GOT level, increase in body weight, prevention of diarrhea, treatment of diarrhea A method of improving the health of mammals or livestock by at least one selected from the group consisting of reduction in days, prevention of colds, and reduction in days of cold treatment. Giving 0.10 g/day/head or more of (A), 0.03 g/day/head or more of (B), and 0.04 g/day/head or more of (C) to mammals or domestic animals 2. The method of claim 1, comprising : Giving 0.14 g/day/head or more of (A), 0.09 g/day/head or more of (B), and 0.19 g/day/head or more of (C) to mammals or livestock 2. The method of claim 1, comprising: 0.063 g/day/head or more of licorice saponin H2, 0.008 g/day/head or more of licorice saponin G2, and 0.026 g/day/head or more of macedonoside A to mammals or livestock, and
0.056 g/day/pig or more of liquiritin apioside, 0.018 g/day/pig or more of isoliquiritin apioside, and 0.027 g/day/pig or more of isoliquiritin Item 1. The method according to item 1 . 0.145 g/day/head or more of (A), 0.097 g/day/head or more of (B), and 0.198 g/day/head or more of (C) for mammals or livestock, and
0.063 g/day/head or more of licorice saponin H2, 0.008 g/day/head or more of licorice saponin G2, and 0.026 g/day/head or more of macedonoside A, and
0.056 g/day/pig or more of liquiritin apioside, 0.018 g/day/pig or more of isoliquiritin apioside, and 0.027 g/day/pig or more of isoliquiritin Item 1. The method according to item 1 . At least, increase in dietary intake of mammals or livestock, increase in blood total cholesterol level, increase in blood vitamin A level, decrease in blood GOT level, increase in body weight, prevention of diarrhea, treatment of diarrhea 6. The method of any one of claims 1-5, wherein the reduction in days, cold prevention, and reduction in cold treatment days improves the health of a mammal or domestic animal. 6. The method of any one of claims 1 to 5, wherein the mammal or livestock is a meat-producing livestock . 8. The method of claim 7 , further for increasing carcass weight, improving carcass yield and/or reducing edible liver waste. 8. The method of claim 7 , further for increasing carcass weight, improving carcass yield and reducing edible liver waste. 8. The method of claim 7 , further for increasing feed efficiency. The supplement is
10% by mass or more of (A), and/or
3% by mass or more of (B), and/or
6. The method according to any one of claims 1 to 5, comprising 4% by mass or more of (C) . The supplement is
14% by mass or more of the (A),
9% by mass or more of the (B),
12. The method according to claim 11, comprising 19% by mass or more of (C) . The (B) licorice saponins other than (A) include at least 2% by mass or more of licorice saponin H2, 0.5% by mass or more of licorice saponin G2, and 0.5% by mass or more of macedonoside A. A method according to any one of claims 1 to 5 . The (C) licorice flavonoids contain at least 2.4% by mass or more of liquiritin apioside, 0.4% by mass or more of isoliquiritin apioside, and 0.3% by mass or more of isoliquiritin. 14. The method of claim 13 . (B) contains at least 6.3% by mass or more of licorice saponin H2, 0.8% by mass or more of licorice saponin G2, and 2.6% by mass or more of macedonoside A;
The claim wherein (C) contains at least 5.6% by mass or more of liquiritin apioside, 1.8% by mass or more of isoliquiritin apioside, and 2.7% by mass or more of isoliquiritin. 6. A method according to any one of claims 1-5 . 14.5% by mass or more of (A), 9.7% by mass or more of (B), and 19.8% by mass or more of (C),
(B) contains at least 6.3% by mass or more of licorice saponin H2, 0.8% by mass or more of licorice saponin G2, and 2.6% by mass or more of macedonoside A;
The claim wherein (C) contains at least 5.6% by mass or more of liquiritin apioside, 1.8% by mass or more of isoliquiritin apioside, and 2.7% by mass or more of isoliquiritin. 6. A method according to any one of claims 1-5 . 6. The method of any one of claims 1-5, wherein the supplement comprises water-soluble dietary fiber . 18. The method according to claim 17, wherein the licorice extract and the water-soluble dietary fiber are contained in a weight ratio of licorice extract:water-soluble dietary fiber=10:90 to 40:60. 18. The method of claim 17, wherein said water-soluble dietary fiber is glucomannan .

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