JP2009291151A - Feed composition and drinking water for livestock or companion creature - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a feed composition to be supplied to livestock or companion creatures, capable of reducing stress to which the livestock or companion creatures are subjected under high temperature in summer. <P>SOLUTION: This feed composition for livestock or companion creatures is mixed with an organic acid composition and a magnesium salt and calcium salt-containing composition derived from seawater. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a feed composition and drinking water provided to livestock or companion animals. In particular, the present invention relates to a feed composition and drinking water for the purpose of reducing stress at high temperatures of domestic animals or companion animals.

  Forage animals such as cattle, horses, pigs, and chickens, and companion animals such as dogs and cats, are provided with feed, hay, beans, and the like. However, in Japan, it is difficult to secure enough grazing land and grassland. For this reason, a large amount of hay and beans are imported as livestock feed. Further, as feed for livestock, in addition to roughage such as hay, mixed feed and chemical feed are given.

In general, animals are subjected to various stresses (hot sensitization stress) at high temperatures in summer. For example, in livestock and the like, there is a problem that the amount of eating, fattening, egg production and the like is reduced due to heat sensitization stress.
Conventionally, commercially available general formula feeds and chemical feeds contain nutritional components such as carbohydrates, proteins, fats, fibers, ash, minerals, and moisture in a well-balanced manner. A sufficient effect was not obtained.

  For this reason, for the purpose of reducing the heat sensitization stress, for example, a blended feed with an increased chlorine content in the feed has been proposed (for example, see Patent Document 1). Moreover, the mixing feed which added sodium bicarbonate and organic chromium is proposed (for example, refer patent document 2).

JP 2003-325109 A JP 2006-61 A

However, there is a possibility that safety is not sufficient in the mixed feed in which the chlorine content is increased and the mixed feed in which sodium bicarbonate and organic chromium are added.
Of mineral sources such as magnesium and calcium used in livestock feed, inorganic calcium sources have low solubility in water and poor absorption in the body. For this reason, a calcium source is not fully metabolized in the body of livestock and is difficult to use efficiently.
Moreover, the method of utilizing the organic mineral whose absorption rate is higher than an inorganic calcium source is also considered. However, in this method, since it is necessary to synthesize by a chemical reaction between an inorganic mineral and an organic acid and mix the organic mineral with the feed, there is a problem that the manufacturing process becomes complicated.
As described above, the conventional mixed feed has a problem that the effect obtained as a measure against heat sensitization stress is not sufficient although the cost for production is high.

  In order to solve the above-described problems, the present invention provides a feed composition and drinking water provided to livestock or companion animals that can reduce the stress that livestock or companion animals receive under high temperatures in summer. Is.

The feed composition for livestock or companion animals of the present invention is characterized in that an organic acid composition and a seawater-derived composition containing a magnesium salt and a calcium salt are blended.
Moreover, the drinking water for domestic animals or companion animals of this invention contains the seawater origin composition containing an organic acid composition, magnesium salt, and calcium salt, It is characterized by the above-mentioned.

According to the feed composition and drinking water for livestock or companion animals of the present invention, it contains magnesium and calcium, and further contains an organic acid composition, so that the body can efficiently absorb magnesium and calcium. Is called.
For this reason, mineral metabolism is efficiently performed in the body for livestock or companion animals, and stress under high temperature for livestock or companion animals is alleviated.

  ADVANTAGE OF THE INVENTION According to this invention, it becomes possible to reduce the stress under the high temperature of livestock and a companion animal.

Hereinafter, specific embodiments of the present invention will be described.
The feed composition and drinking water for livestock or companion animals of the present embodiment are configured to include an organic acid composition and a seawater-derived composition containing magnesium salt and calcium salt originating from seawater. The feed composition for livestock or companion animals is prepared by mixing the above-mentioned organic acid composition and seawater-derived composition with conventional feed for livestock or companion animals. In addition, drinking water for livestock or companion animals is prepared by mixing and dissolving the above-mentioned organic acid composition and seawater-derived composition in water or the like, and is used as drinking water for livestock and companion animals.

By using an organic acid composition for the above-mentioned feed composition and drinking water, the digestion and utilization efficiency of the feed can be improved, and stress (hot sensitization stress) of livestock at high temperatures can be reduced.
Moreover, by using the organic acid composition, it is possible to suppress harmful bacteria in the digestive tract and prevent bacterial contamination of feed and drinking water.

  As an organic acid composition applicable to a feed composition and drinking water, for example, citric acid can be used. Citric acid is not particularly limited, and commercially available citric acid can be used. Citric acid can also be used as a citric acid compound in feed compositions and drinking water. Examples of citric acid compounds include citrates such as calcium citrate, sodium ferrous citrate, sodium citrate, iron citrate, diiron citrate, ammonium iron citrate, and trisodium citrate. be able to.

In addition to citric acid and citric acid compounds, organic acids used in feed compositions and drinking water include, for example, malic acid, lactic acid, tartaric acid, fumaric acid, glucosamic acid, oxalic acid, propionic acid, butyric acid, valerin. Acid, isocitric acid, succinic acid, formic acid, acetic acid and the like, and these compounds can be used.
In particular, by using citric acid, succinic acid, fumaric acid, malic acid, etc. involved in the TCA cycle, the digestion and utilization efficiency of the feed can be improved, and the heat sensitization stress of livestock can be reduced.

When the acidity of citric acid is 100, the acidity of succinic acid is 110 to 120, the acidity of fumaric acid is 150 to 180, and the acidity of malic acid is 100 to 120. For this reason, by using citric acid having the lowest acidity, the deterioration of the taste of feed composition and drinking water can be reduced.
Moreover, since citric acid is produced in larger quantities than succinic acid, fumaric acid and malic acid, it can be obtained at a relatively low cost. For this reason, the cost of feed composition and drinking water can be reduced by using citric acid.

Moreover, the seawater origin composition containing magnesium salt and calcium salt contained in a feed composition and drinking water will not be specifically limited if it originates in seawater. However, when the above-mentioned seawater-derived composition is directly adjusted from seawater, it is preferable to use as clean seawater as possible and perform filtration, heat treatment, concentration, desalting, and the like as necessary.
For this reason, it is preferable that the seawater-derived composition is derived from deep ocean water. Deep ocean water has high cleanliness because there is less organic matter because sunlight does not reach and photosynthesis is not performed, and there are very few harmful artificial contaminants from bacteria and land and air compared to surface water. Very little contamination by microorganisms and chemicals. For this reason, deep sea water is suitable for use as feed or drinking water for livestock and companion animals.
Deep sea water is generally defined as seawater taken from a depth of 200 m or more. Table 1 shows the characteristics of ocean surface water and deep ocean water in Suruga Bay, Shizuoka Prefecture.

  From Table 1, it can be seen that deep ocean water has fewer viable counts and organic matter (TOC) than surface water and is highly clean. Moreover, the amount of minerals contained in deep water and surface water is almost the same. For this reason, it is preferable to use deep sea water with high cleanliness for the feed composition and drinking water.

Moreover, as a seawater origin composition containing magnesium salt and calcium salt, commercially available bitter juice, bitter powder, etc. can also be used.
Even when seawater bitter juice is used as the seawater-derived composition, since the bitter juice is a component that was originally dissolved in seawater, the step of dissolving in water again can be easily performed.

Moreover, it is preferable that the seawater-derived composition described above is a seawater-adjusted product in which seawater is prepared by electrodialysis or diffusion dialysis. In particular, the above-mentioned deep sea water preparation is preferable.
The seawater-derived composition containing magnesium salt and calcium salt contained in the above feed composition and drinking water is obtained by using operations such as desalination and concentration by electrodialysis and diffusion dialysis for seawater or deep seawater. If it is a preparation to be obtained, it can be obtained in a state where the mineral content is already dissolved. For this reason, the process etc. which melt | dissolve the seawater origin composition containing a magnesium salt and a calcium salt in water anew are not required.

  The main component of seawater is sodium chloride, but excessive intake of sodium chloride adversely affects animal health. For this reason, it is necessary to adjust the sodium chloride concentration of the seawater-derived composition to a suitable range by electrodialysis or diffusion dialysis. In particular, a diffusion dialysis method using a diffusion dialysis apparatus having a mosaic charged membrane can be suitably used because there is little modification of the components of the seawater-derived composition when an electrolyte such as sodium chloride is separated.

  In addition, a diffusion dialysis apparatus having a mosaic charged membrane does not require energy such as heating, high pressure, and electricity, and thus can reduce manufacturing costs. Further, since a regeneration process such as an ion exchange resin is unnecessary, the structure of the apparatus can be simplified. Thus, since the initial investment and running cost can be kept low by using a diffusion dialysis apparatus having a mosaic charged membrane, it is very economical. For this reason, in producing a feed composition and drinking water, a diffusion dialysis method using a diffusion dialysis apparatus having a mosaic charged membrane can be particularly preferably used.

  The preferred sodium chloride concentration varies depending on the type of livestock and the stage of growth. For example, in the case of dairy cows, the sodium chloride concentration in the feed composition and drinking water is 0.1 to 0.5% by weight. Is 0.3-0.6 mass%.

As an example of the above-mentioned seawater preparation method, a diffusion dialysis method using a diffusion dialysis apparatus will be described with reference to FIG. FIG. 1 is an example of the configuration of a diffusion dialysis apparatus having a mosaic charged membrane.
In the diffusion dialysis apparatus having a mosaic charged membrane shown in FIG. 1, the raw water chambers 11, 12, 13 and the water chambers 14, 15, 16 are alternately connected. Further, mosaic charged membranes 17, 18, 19, 20, and 21 are interposed between the raw water chambers 11, 12, and 13 and the water chambers 14, 15, and 16, respectively.

  Mosaic charge membrane is a diffusion of ions by cationic and anionic ion exchange membranes composed of cationic polymer component and anionic polymer component penetrating each other between both sides of the membrane. It is a charged membrane that can be dialyzed. Ion permeation is performed by the difference in osmotic pressure between raw water and dialysed water.

  The mosaic charged membrane is a unique separation membrane in which ions such as salts that easily pass through the ion channel of the membrane and nonionic or high molecular weight molecules that are difficult to dialyse are easily separated. The mosaic charged membrane is used for diffusion dialysis under normal pressure and pressure dialysis under pressure as a method for adjusting sodium chloride. For this reason, in the diffusion dialysis method using a mosaic charged membrane, there is little modification | denaturation of a component. For this reason, the sodium chloride concentration can be adjusted without missing minerals derived from seawater such as magnesium salts and calcium salts.

  Seawater is supplied from the raw water supply line 22 to the raw water chambers 11, 12, and 13 as raw water. This raw water contains an electrolyte (sodium chloride: NaCl) contained in seawater. Further, distilled water is supplied from the distilled water supply line 23 to the water chambers 14, 15, and 16 as dialysis water.

Then, from the raw water supplied to the raw water chambers 11, 12, 13, cations (Na ⁺ ) and anions (Cl ⁻ ) pass through the mosaic charged membranes 17, 18, 19, 20, 21, Move to 15,16. Thereby, salt moves from raw | natural water to dialysis water, and the sodium chloride density | concentration of raw | natural water can be adjusted.
For this reason, the raw water in which the sodium chloride concentration is adjusted is discharged from the raw water chambers 11, 12, and 13 through the raw water discharge line 24. From the water chambers 14, 15, and 16, dialysis water containing salt is discharged through a dialysis water discharge line 25.

Next, as another example of the seawater adjustment method described above, an electrodialysis method will be described with reference to FIG. FIG. 2 is an example of a configuration of an electrodialysis apparatus having an electrodialysis membrane.
In the electrodialysis apparatus using the electrodialysis membrane shown in FIG. 2, a water chamber 31, a water chamber 32, a raw water chamber 35, a water chamber 33, a raw water chamber 36, and a water chamber 34 communicate with each other. A cation exchange membrane 37 is interposed between the water chamber 31 and the water chamber 32. An anion exchange membrane 39 is interposed between the raw water chamber 35 and the water chamber 32, and a cation exchange membrane 38 is interposed between the raw water quality 35 and the water chamber 33. Further, an anion exchange membrane 40 is interposed between the raw water chamber 36 and the water chamber 33, and a cation exchange membrane 41 is interposed between the raw water chamber 36 and the water chamber 34.

  In the water chamber 31, a cathode 42 is provided on the opposite side of the cation exchange membrane 37. The water chamber 34 is provided with an anode electrode 43 on the opposite side of the cation exchange membrane 41. Therefore, in the electrodialysis apparatus using the electrodialysis membrane, the cathode electrode 42 and the anode electrode 43 are provided at the position of the counter electrode in the apparatus.

  Seawater as raw water is supplied from the raw water supply line 44 to the raw water chambers 35 and 36. This raw water contains an electrolyte (NaCl). Also, distilled water is supplied from the distilled water supply line 45 to the water chambers 31, 32, 33, 34 as dialysis water.

Then, cations (Na ⁺ ) are attracted to the cathode electrode 42 from the raw water supplied to the raw water chamber 35, pass through the anion exchange membrane 39, and move to the water chamber 32. Further, anions (Cl ⁻ ) are attracted to the anode electrode 43, pass through the cation exchange membrane 38, and move to the water chamber 33.
Similarly, cations (Na ⁺ ) are attracted to the cathode electrode 42 from the raw water supplied to the raw water chamber 36, pass through the anion exchange membrane 40, and move to the water chamber 33. In addition, anions (Cl ⁻ ) are attracted to the anode electrode 43, pass through the cation exchange membrane 41, and move to the water chamber 34.

As described above, cation (Na ⁺ ) and anion (Cl ⁻ ) pass through the anion exchange membranes 39 and 40 and the cation exchange membranes 38 and 41 from the raw water supplied to the raw water chambers 35 and 36, Move to chamber 32, 33, 34. In this way, the salt moves from the raw water to the dialysis water, and the sodium chloride concentration of the raw water can be adjusted.
For this reason, from the raw water chambers 35, 36, the raw water whose sodium chloride concentration is adjusted is discharged by the raw water discharge line 46. Further, dialysis water containing salt is discharged from the water chambers 31, 32, 33, and 34 through a dialysis water discharge line 47.

  By adjusting the sodium chloride concentration of the seawater-derived composition to a suitable range using the above-mentioned electrodialysis method or diffusion dialysis method using a mosaic charged membrane, the seawater-derived component containing magnesium salt and calcium salt is converted into the feed composition and Can be added to potable water.

  Table 2 shows the results of adjusting the sodium chloride concentration by the diffusion dialysis method using the above-described mosaic charged membrane and the electrodialysis method using the electrodialysis membrane. Seawater used was deep sea water in Suruga Bay, Shizuoka Prefecture shown in Table 1 above. In addition, a mosaic charged membrane dialysis device manufactured by Dainichi Seika Co., Ltd. was used as a diffusion dialysis device using a mosaic charged membrane, and an electrodialysis device manufactured by Astom was used as an electrodialysis device.

  Moreover, it is preferable that the above-mentioned feed composition and drinking water for domestic animals or companion animals contain a trehalose compound. By adding a trehalose compound to the feed composition and drinking water containing the magnesium salt and calcium salt derived from seawater as described above, the trehalose compound and the mineral derived from seawater are combined to be easily absorbed in the body. For this reason, absorption of the mineral in an animal body is accelerated | stimulated by putting a trehalose compound in the above-mentioned feed composition and drinking water.

  The trehalose compound is not particularly limited, and for example, glucosyl trehalose, maltosyl trehalose, maltotreosyl trehalose, etc., in which glucose is α-1.4 bonded to the trehalose skeleton can be used for the feed composition and drinking water.

It has been estimated by studies using NMR that a metal ion such as calcium or magnesium derived from seawater and a hydroxyl group in the molecule of a trehalose compound form a complex. The amount of the complex formed between the trehalose compound and the metal ion depends on the amount of trehalose added. Further, it has been reported that a sucrose compound does not form a complex with the above metal ions.
For this reason, by adding a trehalose compound to a feed composition and drinking water, the mineral content derived from seawater is combined with the trehalose compound and stabilized, and the absorption rate of the mineral in the body is improved. Accordingly, it is possible to further improve the health maintenance effect of the livestock or companion animals by the feed composition and drinking water.

The amount of the organic acid composition, the seawater-derived composition, and the trehalose compound to be blended in the feed composition and drinking water can be arbitrarily set within a range that does not adversely affect the health of the animal fed the feed. . Preferably, the organic acid composition preferably includes 0.01 to 2.0 mass%, the magnesium salt derived from seawater 0.1 to 1.0 mass%, and the trehalose compound 0.1 to 3.0 mass%. .
By setting it as the above-mentioned mixing | blending, the bad intake of the intake of a domestic animal or a companion animal does not generate | occur | produce, but an appropriate intake can be given to a domestic animal or a companion animal.

Moreover, when the compounding amount of the organic acid compound is less than 0.01% by mass, the desired effect cannot be obtained because the compounding amount is small.
When the compounding amount of the organic acid compound exceeds 2.0% by mass, the organic acid is not efficiently used in the body and the amount excreted increases. Moreover, when there are many compounding quantities of an organic acid compound, acidity will become large and taste property will deteriorate. Furthermore, the use of a large amount of the organic acid composition increases the cost of the feed composition and drinking water.

  In addition to the above-mentioned organic acid compound, seawater-derived composition, and trehalose compound, various nutritional components such as minerals other than seawater-derived minerals, proteins, and vitamins may be added to the feed composition and drinking water. it can.

As minerals other than the seawater origin mentioned above, inorganic or organic salts, such as iron, copper, manganese, zinc, iodine, potassium, selenium, can be used, for example.
As said protein, corn, wheat, barley, soybean meal, rapeseed oil cake etc. can be used as vegetable protein, for example. Moreover, meat-and-bone meal, fish meal, chicken meal, etc. can be used as animal protein. In recent years, since there is a concern about the safety of animal raw materials, it is preferable to use vegetable protein.
Examples of the above-mentioned vitamins include vitamin A, vitamin B1, vitamin B2, vitamin B3, vitamin B6, vitamin B12, vitamin C, vitamin D, vitamin E, niacin, vitamin K, biotin, riboflavin, nicotinic acid, folic acid, and pantothene. Acid, choline, etc. can be used.

The above-mentioned organic acid composition, seawater-derived composition, trehalose compound, and nutrient components can be blended at an arbitrary ratio, and a feed composition and drinking water can be produced by a conventional method.
It is preferable that the amount of each component is determined in consideration of the nutrient component requirements of the domestic animal or companion animal.
If the amount of each component is too large compared to the required amount of nutritional components of livestock or companion animals, surplus components are discharged out of the livestock and cannot be used effectively. On the other hand, when there are few compounding quantities compared with a request | requirement amount, the component required for livestock will run short.

The shape of the feed composition is not particularly limited, and may be any shape such as liquid, paste, powder, fine granule, granule, pellet and the like.
Moreover, the domestic animal or companion animal which provides a feed composition and drinking water is not specifically limited. Examples of domestic animals include cows, horses, pigs, sheep, chickens, and ducks. Examples of companion animals include dogs and cats.

  Next, an example of blending water for pigs and chickens, and drinking water for dogs or cats using the feed composition and drinking water described in this embodiment will be shown.

(Feed composition for pigs)
The feed is blended so as to be 66 parts by mass of corn, 23 parts by mass of soybean oil meal, 4 parts by mass of rapeseed oil meal, 2 parts by mass of fish meal, and 5 parts by mass of rice bran. And in the blended feed, 0.8 parts by mass of calcium citrate as the organic acid composition, 1 part by mass of seawater-derived deep sea water as a composition derived from seawater, amino acids (DL-methionine, L-lysine hydrochloride, L-tryptophan, L -Mixing 0.02 parts by mass of sodium glutamate, nicotinamide, aminoacetic acid) and 0.01 parts by mass of vitamins (mixture of vitamin A, vitamin D, vitamin E, biotin, folic acid, pantothenic acid) A feed composition for pigs was prepared.
This feed composition for adult pigs contains a sufficient amount of the organic acid composition and the magnesium salt and calcium salt of the seawater-derived composition. For this reason, it is effective in reducing the heat sensitization stress of pigs.

(Feed composition for chicken)
A feed comprising 60 parts by weight of mylo, 10 parts by weight of corn gluten meal, 5 parts by weight of rapeseed oil cake, 10 parts by weight of fish soluble, 5 parts by weight of corn gluten feed, and 10 parts by weight of fat for feed is blended. And to this mixed feed, as an organic acid composition, 1 part by mass of calcium citrate, 0.2 part by mass of malic acid, 1 part by mass of marine deep sea water bite, amino acids (DL-methionine, L-lysine hydrochloride, L-tryptophan) , L-sodium glutamate mixture) 0.02 parts by weight, vitamins (vitamin A, vitamin D3, tocopherol acetate, biotin, folic acid, pantothenic acid, phytase) 0.01 parts by weight and trehalose 1.2 parts by weight A feed composition for adult chickens was prepared.
This feed composition for adult chickens contains a sufficient amount of citric acid, malic acid, calcium, magnesium, and trehalose. For this reason, it is effective in reducing the heat sensitization stress of chickens.

(Drinking water for dogs or cats)
To 100 parts by mass of deep sea water prepared by diffusion dialysis using a mosaic charged membrane shown in Table 2 above, 1 part by mass of calcium citrate as an organic acid composition, amino acids (DL-methionine, L-lysine hydrochloride, L -Mixture of tryptophan and sodium L-glutamate) 0.01 parts by mass was prepared to prepare drinking water for dogs or cats.
This drinking water for dogs or cats contains a sufficient amount of citric acid, calcium, and magnesium, and is effective in reducing the heat sensitization stress of dogs or cats.

  As described above, the feed composition and drinking water for livestock or companion animals of the present embodiment includes an organic acid composition and a seawater-derived composition containing a magnesium salt and a calcium salt. Stress such as mineral supplementation and heat sensitization to companion animals can be reduced. Furthermore, by adding a trehalose compound, the absorption rate of minerals in the body is improved, and the health maintenance effect can be further improved.

  The present invention is not limited to the above-described configuration, and various other configurations can be employed without departing from the gist of the present invention.

It is a figure which shows an example of a structure of the diffusion dialysis apparatus which prepares seawater for manufacturing the feed composition and drinking water of this invention. It is a figure which shows an example of a structure of the electrodialysis apparatus which prepares seawater for manufacturing the feed composition and drinking water of this invention.

Explanation of symbols

  11, 12, 13, 35, 36 Raw water chamber, 14, 15, 16, 31, 32, 33, 34 Water chamber, 17, 18, 19, 20, 21 Mosaic charged membrane, 22, 44 Raw water supply line, 23, 45 Distilled water supply line, 24, 46 Raw water discharge line, 25, 47 Dialysis water discharge line, 37, 38, 41 Cation exchange membrane, 39, 40 Anion exchange membrane, 42 cathode electrode, 43 anode electrode

Claims (12)

An organic acid composition;
A feed composition for livestock or companion animals, comprising a seawater-derived composition containing magnesium salt and calcium salt.   The feed composition for livestock or companion animals according to claim 1, wherein the seawater-derived composition is a preparation of deep sea water.   2. The livestock or companion animal according to claim 1, wherein the seawater-derived composition is a seawater preparation prepared by at least one method selected from electrodialysis and diffusion dialysis. Feed composition.   The feed composition for domestic animals or companion animals according to claim 3, wherein the diffusion dialysis method is performed by a diffusion dialysis apparatus having a mosaic charged membrane.   The feed composition for livestock or companion animals according to claim 1, wherein the organic acid composition is at least one selected from citric acid, succinic acid, fumaric acid, and malic acid.   The feed composition for livestock or companion animals according to claim 1, comprising a trehalose compound. An organic acid composition;
A drinking water for domestic animals or companion animals, comprising a seawater-derived composition containing a magnesium salt and a calcium salt.   The drinking water for livestock or companion animals according to claim 7, wherein the seawater-derived composition is a preparation of deep sea water.   8. The livestock or companion animal according to claim 7, wherein the seawater-derived composition is a seawater preparation prepared by at least one method selected from electrodialysis and diffusion dialysis. Drinking water.   The drinking water for domestic animals or companion animals according to claim 9, wherein the diffusion dialysis method is performed by a diffusion dialysis apparatus having a mosaic charged membrane.   The drinking water for domestic animals or companion animals according to claim 7, wherein the organic acid composition is at least one selected from citric acid, succinic acid, fumaric acid, and malic acid.   The drinking water for domestic animals or companion animals according to claim 7, comprising a trehalose compound.

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