JPH1198966A - Glass eluting trace nutrients for feed additive - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a mineral elements-containing glass that is fed to domestic animals as a feed additive, gradually elutes mineral elements at a prescribed site in the body and the eluted mineral elements are efficiently absorbed into the animal body. SOLUTION: This trace elements-eluting glass as a feed additive is a glass that elutes trace minerals in the body of animals and contains 16 50 wt.% of SiO2 , one or two of <=45 wt.% of K2 O; and/or <=45 wt.% of Na2 O; in addition, one or two of <=30 wt.% of MnO and/or <=30 wt.% of ZnO and, when necessary, <=30 wt.% of at least one selected from Fe2 O3 , P2 O5 and B2 O3 .

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to glass used as a feed additive for supplementing minerals necessary for artificially bred animals, and this glass is contained in a fed body. The present invention relates to a glass in which minerals are sealed, which elutes a small amount of minerals one by one and helps to generate and adjust living tissue.

[0002]

2. Description of the Related Art The growth of animals requires vitamins and minerals in addition to proteins, carbohydrates and lipids, which are said to be three major nutrients. Conventionally, artificially reared animals are increasingly using compound feeds in addition to raw feeds so that these nutrients are not biased. For example, in the aquaculture fishery, 100% compound feed is used as a fish feed for freshwater fish. On the other hand, saltwater fish is mainly made of raw feed, but compound feed is gradually used from raw feed recently.However, in consideration of the nutritional requirements of fish, fish meal and fish meal are the main raw materials. Plant feed is used. However, such feed is not always sufficient in terms of balance.

In order to maintain the living body of animals, phosphorus (P), calcium (C)
a), minerals such as iron (Fe) and zinc (Zn) are essential. Since these elements cannot be synthesized in the body, they must be taken in through feed or the like. However, when a certain component among the above-mentioned mineral components is deficient, or the balance or action between the components is lost,
Growth failure and illness are more likely to occur.

For example, iron and copper restrict absorption of zinc into the body, and calcium inhibits absorption of zinc into the body. Calcium and copper and calcium and zinc have an action of canceling each other's effects, that is, an antagonistic action. As mentioned above, despite the fact that fish meal, which is the main raw material of fish feed, contains trace minerals necessary for the body, the balance of the components it contains is poor,
It produces antagonism and hinders fish growth.
Therefore, in order to maintain the mineral content balance, the fish compound feed is replenished with the insufficient mineral content and strengthened.

On the other hand, in order for mineral components to be efficiently absorbed into the body, it is necessary that the mineral elements be ionized in the body. In general, compounded feeds with enhanced mineral content include plant feeds such as soybeans, and their fibers are easily combined with ionized mineral elements, so the enhanced mineral elements are combined with fibers and excreted as they are Sometimes. For example, plant fiber bran and cellulose combine with iron, calcium or magnesium to reduce absorption in the body.

[0006] Phytic acid contained in plant feed such as cereals is present in a state of being bound to metal ions or proteins, and this complex is further bound to a mineral element to become insoluble, and the mineral content is reduced. Absorption into the body is impaired. For example, if the ratio of phytic acid to iron is 1:
The complex of 1 is soluble in water, but when the proportion of iron is increased, it becomes difficult to dissolve in water and is excreted as it is. There is a problem that the thus reinforced mineral is combined with other substances and becomes insoluble, resulting in poor absorption efficiency.

On the other hand, Japanese Patent No. 2577319 discloses that
Constructed as a seaweed bed breeding material or artificial reef using glassy material containing mineral components, dissolve metal ions dissolved from glassy material in the sea, and increase planting of seaweeds and phytoplankton growing in the sea. It is disclosed to be useful. However, this patent invention relates to the cultivation of marine plants and is not used for animal feed.

[0008]

As described above, there are various types of compound feed, but when purifying a compound feed that supplements and enhances mineral components, the mineral elements are sufficiently and efficiently removed. A device that can be absorbed into the body is required. The present invention is based on such a viewpoint, and is supplied to an animal as a feed additive, and is fed and gradually ionizes and elutes the mineral element at a predetermined site in the body, so that the mineral element can be efficiently removed. It is an object of the present invention to provide a mineral element-containing glass that can be absorbed into the body.

[0009]

Means for Solving the Problems When the animal replenishes the body with mineral components, the present inventors do not ionize the mineral elements all at once, but adjust the time required for the feed to pass through the body. It was predicted that if it was eluted gradually and continuously, it would be efficiently absorbed into the body. In order to realize this prediction, it has been found that a mineral component should be contained and eluted gradually, that is, a water-soluble glassy material capable of adjusting the elution rate of the contained mineral should be used.

That is, the present invention is based on such findings, and is a glass which elutes a trace amount of a mineral element in the body of an animal, wherein SiO ₂ : 15 to 50% by weight and K ₂ O: 45% by weight % Or less and Na ₂ O: 45% by weight or less, and MnO: 3
Any one of 0% by weight or less and ZnO: 30% by weight or less
It is a trace element eluting (containing) glass for feed addition characterized by containing one or two kinds as main components. In addition to the above-mentioned components, Fe ₂ O ₃ : 30% by weight or less, P ₂ O ₅ :
30 wt% or less, B ₂ O _3: any one of 30 wt% or less
A trace element eluting (containing) glass for feed addition, characterized by containing one or more species.

The above-mentioned glass of the present invention has an average diameter of 2
It is preferable that the particles have a particle size of 000 μm or less, whereby the absorption of minerals can be more efficiently performed. However, the glass particle size can be changed depending on the type of animal,
Granules having a maximum size of about 5 mm may be used.

In the above glass, a very small amount of A as an impurity which is inevitably mixed from a refractory of a melting furnace during production.
It contains at least one of l ₂ O ₃ , CaO and MgO.

As described above, the glass of the present invention that elutes trace mineral elements has the following features. In other words, this glass is a material that encloses mineral components and elutes a small amount of mineral elements gradually and continuously in the animal body. A variety of mineral components with respective purposes can be added at once. Since the dissolution rate can be controlled by changing the particle size and mineral components of the glass, it can be dissolved in organs such as the stomach and intestine.

[0014]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described below in detail.
The present invention focuses on the vitreous amorphous structure, and by allowing the vitreous material to contain a mineral component, enables the mineral element to be slowly and stably released in the body in an ionic state.

[0015] That is, the vitreous material is composed of a silicon-based quality network structure which forms an amorphous network structure by binding strongly to oxygen, and a network modifier such as sodium or potassium which enters into the network structure. And manganese and zinc which function as a network component or a network modifier. The modified network has a weak bond with oxygen, and its oxide has the effect of cutting the network.In the body, it gradually breaks the network structure of the glass material by contact with secretory fluid, so it is contained in the vitreous material. Components (minerals) are ionized and gradually elute over a long period of time.

The vitreous material of the present invention further contains, if necessary, phosphorus and boron which function as a network component, and iron which functions as a network component or a network modifier. The dissolution rate can be adjusted appropriately.

The glass of the present invention may contain silicon (Si), potassium (K) and / or sodium (Na), manganese (Mn) and / or zinc (Zn) as an ion eluting source, and iron as an optional element. Mineral components such as (Fe), phosphorus (P) and boron (B) are combined in composition. These mineral compounds are contained as glassy components and nutrients in the following ranges.

Si is a basic component for forming an amorphous network structure, and is contained in a weight ratio of 15 to 50% as SiO ₂ . If it is less than 15%, the strength as a glass material is insufficient,
On the other hand, if it exceeds 50%, the network structure becomes too strong, so that the mineral is not eluted in the animal body at a desired time, and the mineral cannot be efficiently absorbed.

K and Na are contained mainly for controlling the elution rate of glass. On the other hand, it is effective to adjust the pH in the body, and it is effective to increase the potassium and sodium content when it is desired to bring the mixture of the eluted substance and the body fluid to the alkali side in the body. The eluted potassium ions and sodium ions control the biological functions such as forming ion balance in the body, and contain either or both of 45% by weight or less as K ₂ O and Na ₂ O according to the purpose. Let it.

Mn and Zn elute manganese ions and zinc ions. It is said that if these are insufficient, it causes growth deficiency and causes infertility (Mn). Depending on the purpose, one or both of them are contained as MnO and ZnO in an amount of 30% by weight or less, respectively.

Further, Fe, P and B are iron ions,
Elutes phosphorus ions and boron ions. Iron acts on blood, and phosphorus plays an important role in skeleton formation. On the other hand, boron is contained rather than as a nutrient for adjusting the dissolution rate of glass, and also serves for pH adjustment in the body. That is, when it is desired to bring the mixture of the eluate in the body and the body fluid to the acidic side, it is preferable to contain a large amount of boron. One or both of the components are contained in an amount of 30% by weight or less as Fe ₂ O ₃ , P ₂ O ₅ , and B ₂ O ₃ depending on the purpose.

The vitreous material of the present invention is prepared by blending ordinary raw materials containing elements such as silicon, potassium / sodium and zinc / manganese in an appropriate component range, and heating at a high temperature (for example, 1300 in a reducing atmosphere). (1500 ° C. × 20 minutes or more), melted, and then quenched. Further, it goes without saying that a vitreous material can be produced by the above method by mixing one or more of materials containing iron, phosphorus and boron.

The vitreous material (bulk) produced in this way is crushed and, in some cases, ground to a granular form. The particle size varies depending on the target animal and cannot be unambiguously determined, but the dissolution rate can be adjusted to a preferable range by setting the particle size to 2000 μm or less and 10 μm or more. If the thickness is less than 10 μm, the mineral is eluted in the body too quickly to achieve efficient absorption, and if it exceeds 2000 μm, it is excreted as insoluble particles. But,
Depending on the animal, a granular material having a maximum diameter of about 5 mm may be used.

Further, the glassy material of the present invention may have an uneven surface or a porous surface in order to increase the surface area.

The glass of the present invention contains, in addition to the above components, 10% by weight or less of each of F (fluorine) and V _2.
O ₅ , Cr ₂ O ₃ , CoO, NiO, CuO, As ₂ O
_3, Se _{(selenium), MoO, Sn 2 O,} I ( iodine)
To elute one or more trace mineral components such as fluorine, vanadium, chromium, cobalt, nickel, copper, arsenic, selenium, molybdenum, tin, iodine, etc. It does not exclude that.

The present invention will be described below based on experimental examples. [Experiment 1] For the purpose of grasping the elution rate of the trace mineral components of the glass of the present invention, the elution amounts of the glasses having the components shown in Table 1 were measured. That is, 100 mg of each sample shown in Table 1 was put into 100 ml of pure water, and 1
After standing for a day, the samples were analyzed by the atomic absorption method to measure the amounts of Mn and Zn as elution components. The average particle size of the sample used was 500 μm. Table 2 shows the measurement results.

As is apparent from Table 2, since the amount of eluted elements differs depending on the amounts of MnO and ZnO contained in the sample, it is necessary to determine the glass to be added to the feed in consideration of the required amount of the target animal. It becomes possible.

[0028]

[Table 1]

[0029]

[Table 2]

[Experiment 2] For rainbow trout, fish meal,
A glass that elutes zinc was added to a feed mainly composed of soybean oil cake and corn gluten meal. The glass components are as shown in the sample of Table 1 above, and the average particle size was 500 μm.
m and adjusted to dissolve about 20% per day (the dissolution rate is calculated from the remaining amount of the sample). For comparison, zinc sulfate, which is considered to be highly available to fish among zinc, was used. The amount of zinc added was adjusted to be 20 mg and 40 mg per kg of feed as Zn, respectively, and 40 rainbow trout per case were bred in 4 cases for 12 weeks. Table 3 shows the results of measuring the weight and intake of rainbow trout after rearing for 12 weeks.

[0031]

[Table 3]

The SGR (daily growth rate (%)) was determined by the following equation. SGR = {ln (weight at the end of the experiment) −ln (weight at the start of the experiment)} / days of breeding × 100 ALP (alkaline phosphatase activity) is a phosphate monoesterase that contains zinc and has an alkaline pH optimum. is there. ALP values indicate zinc sufficiency. The measurement is automatically measured by sampling blood and applying it to a biochemical analyzer.

As shown in Table 2, the rainbow trout bred with the zinc-eluting glass-added feed of the present invention had better SGR (daily growth rate) than those bred with the zinc sulphate-added feed of the comparative example. ALP (alkaline phosphatase activity), which is an index indicating that E. coli is used efficiently, showed a value of 1.5 times or more.

It is said that rainbow trout excretes the fed substance in about one day. Some of the zinc-eluting glasses used in this test bind to dietary fiber and phytic acid because they control the dissolution rate and always elute zinc, but they are efficient intestines. It was found that zinc was absorbed.

[0035]

As described above, the glass containing trace minerals to be added to the animal feed of the present invention is made of Si, Ka, N
By appropriately combining compounds that elute mineral components such as a, Mn, Zr, and Fe, P, and B into a fine water-soluble glass, the mineral elution rate can be adjusted.
As a result, minerals are ionized and eluted from feeding the feed to reaching the absorption site, and the mineral component is constantly and continuously eluted, that is, the mineral component is gradually and slowly eluted, so that the ion state at the absorption site is Can be absorbed efficiently.

 ──────────────────────────────────────────────────続 き Continued on the front page (72) Inventor Kiichi Hirose 1-21-2-5 Inayoshi Minami, Chiyoda-cho, Shinji-gun, Ibaraki B101

Claims (4)

[Claims] 1. A glass that elutes trace minerals in the body of an animal, comprising: SiO ₂ : 15 to 50% by weight; K ₂ O: 45% by weight or less; and Na ₂ O: 45% by weight or less. A trace element eluting glass for feed addition, characterized in that it contains, as a main component, at least one of two or more kinds, and one or two kinds of MnO: 30% by weight or less and ZnO: 30% by weight or less. 2. The composition according to claim 1, further comprising: at least one of Fe ₂ O ₃ : 30% by weight or less, P ₂ O ₅ : 30% by weight or less, and B ₂ O ₃ : 30% by weight or less. A trace element eluting glass for feed addition, characterized by containing at least one species. 3. The glass for eluting trace elements for feed addition according to claim 1, wherein the glass is particles having an average diameter of 5000 μm or less. 4. The glass for eluting trace elements for feed addition according to claim 3, wherein the glass comprises particles having an average diameter of 2000 μm or less.