Organometallic complex, powder intended for animal feed and preparation methods thereof

Abstract

The invention relates to an organometallic complex of the amino acid/metal type. The complex is a crystalline pluri-metal complex that can be obtained in the form of a homogeneous powder that can be used to optimise animal feed. More specifically, the invention relates to an organometallic complex that is characterised in that it is formed by at least one amino acid or amino acid derivative with at least two different metals. The invention also relates to a powder comprising the organometallic complex of the invention, as well as to methods for preparing such a powder.

Claims

1. An organometallic complex consisting of at least one amino acid or amino acid derivative with at least two different metals, wherein the organometallic complex consists of: at least two elements of the amino acid or amino acid derivative group, and at least two different metals, wherein the molar ratio of amino acid and/or amino acid derivative among the at least two elements of the amino acid or amino acid derivative group per metal anion the at least two different metals is 1-to-1, wherein the organometallic complex is in the form of a chain alternating the metals and the amino acids, wherein the metals are selected from the group consisting of zinc, copper, iron, manganese, cobalt, calcium, molybdenum, chromium and magnesium, and wherein each of the metals among the at least two different metals is bonded to a ligand, wherein the ligand is a sulfate.

2. The complex as claimed in claim 1, wherein each metal of the organometallic complex is bonded to two elements of the amino acid and/or amino acid derivative group and each element of the amino acid and/or amino acid derivative group is bonded to two metals.

3. The complex as claimed in claim 1, which comprises an amino acid derivative which is a hydroxy analog of an amino acid.

4. The complex as claimed in claim 1, wherein one of the amino acids is glycine.

5. The complex as claimed in claim 4, wherein the glycine is bonded to two different metals via the two oxygens of its carboxyl group.

6. The complex as claimed in claim 1, consisting of (i) glycine and at least one selected from the group consisting of methionine and lysine, with (ii) zinc sulfate, copper sulfate, iron sulfate and manganese sulfate.

7. A powder comprising particles each comprising at least one organometallic complex as claimed in claim 1.

8. The powder as claimed in claim 7, wherein the respective proportions of the metals are chosen so as to promote the optimization of the daily intakes planned for an animal.

9. A process for preparing a powder, comprising: a) preparing a first aqueous solution of at least one amino acid or amino acid derivative and of at least one first metal, the first aqueous solution comprising a molar ratio of amino acid and/or amino acid derivative per metal of 1-to-1; b) preparing a second aqueous solution of at least one amino acid or amino acid derivative and of at least one second metal, the second aqueous solution comprising a molar ratio of amino acid and/or amino acid derivative per metal of 1-to-1; c) optionally repeating step a) or b) with other metals in order to prepare other aqueous solutions; d) mixing together all the aqueous solutions prepared; e) producing a gaseous stream; f) spraying the mixture obtained in step d) into the gaseous stream; and g) recovering a powder obtained, wherein the recovered powder is the powder as claimed in claim 7.

10. A process for preparing a powder, comprising: h) preparing an aqueous solution in which at least one first amino acid or amino acid derivative, at least one second amino acid or amino acid derivative, at least one first metal and at least one second metal, optionally, other amino acid(s) or amino acid derivative(s), and, optionally, other metal(s), are mixed in the same container, the aqueous solution comprising a molar ratio of amino acid and/or amino acid derivative per metal of 1-to-1; i) drying the mixture obtained in step h); and j) recovering a powder obtained, wherein the recovered powder is the powder as claimed in claim 7.

11. A method of feeding animals, comprising administering a powder as claimed in claim 7 to the animals.

12. The complex as claimed in claim 2, which comprises an amino acid derivative which is a hydroxy analog of an amino acid.

13. The complex as claimed in claim 2, wherein the amino acid is glycine.

14. The complex as claimed in claim 13, wherein the glycine is bonded to two different metals via the two oxygens of its carboxyl group.

15. The complex as claimed in claim 2, wherein the metals are chosen from the group consisting of zinc, copper, iron, manganese, cobalt, calcium, molybdenum, chromium and magnesium.

16. The complex as claimed in claim 3, which comprises an amino acid derivative which is a hydroxy analog of methionine.

17. The complex as claimed in claim 12, which comprises an amino acid derivative which is a hydroxy analog of methionine.

18. The complex as claimed in claim 1, wherein the metals are bonded to the elements of the amino acid or amino acid derivative group via at least one oxygen of a carboxyl group of the amino acid or amino acid derivative group.

Description

(1) Other characteristics and advantages of the invention will now be described in detail in the following description which is given with reference to the appended FIGURE which diagrammatically represents:

(2) FIG. 1: a diagram representing the particle size distribution of the particles obtained using the process described in example 1.

DETAILED DESCRIPTION OF THE INVENTION

Complex According to the Invention

(3) The complex according to the invention consists in at least one amino acid or amino acid derivative with at least two different metals.

(4) As amino acids, mention may be made of methionine, lysine and glycine. It is the latter which is preferably chosen.

(5) The term “amino acid derivative” is intended to mean particularly a hydroxy analog of an amino acid, for instance a hydroxy analog of methionine.

(6) The metals are generally Cu, Co, Ca, Mg, Mo, Fe, Zn, Cr or Mn. Preferably, the two or more metals contained in the compound are chosen from the group consisting of Zn, Cu, Fe and Mn.

(7) These metals can be initially bonded to a ligand optionally present in the complex. It is generally a sulfate, which can be bonded to a metal present in several possible oxidation states (Cu I or II, Fe II or III, etc.).

(8) The compounds which have been found to be particularly advantageous are those based on glycine, on zinc sulfate, on copper sulfate, on iron sulfate or on manganese sulfate.

(9) According to the invention, the ratios between the various weight contents of the metals can be very varied.

(10) By way of example, mention may be made of a compound having the following weight ratios: weight of Cu/weight of Fe: 0.1111 weight of Zn/weight of Fe: 0.8888 weight of Mn/weight of Fe: 0.5555.

(11) One of the advantages provided by the invention is that it is possible to define, during the preparation of the complex, particular proportions of the metals that it is desired for said complex to contain. These particular proportions can be those required in order to cover the daily intakes required for a given animal, or else they can be fixed according to specifications provided by a user or for a special use.

(12) Furthermore, the molar ratio between the amino acid(s) and/or amino acid derivative(s) and the metal is advantageously 1-to-1. Specifically, in the complex according to the invention, a metal is thus bonded to two amino acids (and/or amino acid derivatives) and one element of the amino acid and amino acid derivative group is bonded to two metals.

(13) The result is therefore a molecule which is in the form of a chain alternating a metal and an amino acid or amino acid derivative. This molecule integrates the various metals chosen, in their initially predefined proportion.

(14) Choosing a molar ratio of one to one between the metal and the amino acid (and/or derivative thereof) has the following advantages: this makes it possible to avoid obtaining a surplus of metals or of amino acids in the final complex, which would be free and might cause poor distribution of the metal in the product; this makes it possible to obtain 100% of active elements through the formation of a single compound; this makes it possible to obtain an economic advantage for the formulation, the preparation and the spraying, and facilitates its transportation.

Processes for Preparing the Powder According to the Invention

a) First Preparation Process

(15) The powder according to the invention can be prepared according to the first process, which makes it possible to obtain it from multiple bases.

(16) This process has the advantage that it can be carried out at ambient temperature.

(17) The preparation of the aqueous solutions mentioned in steps a), b) and, optionally, c) is carried out in a manner known to those skilled in the art, for example according to the teachings of the abovementioned international application No. WO 03/049850 or of European patent application No. EP 2 843 752. The molar ratio of one metal to one element of the amino acid and/or amino acid derivative group is advantageously adhered to in these aqueous solutions.

(18) The gaseous stream is advantageously a stream of air.

(19) The spraying is carried out in a manner known to those skilled in the art.

b) Second Preparation Process

(20) This process makes it possible to start from a single base.

(21) The mixing of step h) can advantageously be carried out at ambient temperature.

(22) The drying can be carried out in an incubator and in the open air.

(23) Regardless of the process used, the respective proportions of the metals are advantageously chosen in such a way as to supplement the feed intake such that the latter covers the needs of the animal.

(24) Furthermore, regardless of the preparation process used, the product obtained is in the form of a homogeneous powder consisting of particles resulting from a complexation of at least one amino acid with all the metals and their derivatives used.

(25) In the particular case where glycine is used, the metals are organically bonded to the glycine. Specifically, the glycine is finally bonded to the metals via the two oxygens of its carboxyl group. Two different metals can thus be bonded to the same glycine. This is potentially advantageous since the absorption of each metal by the animal could be improved thereby. Furthermore, this polymer crystallizes in the form of a polymer crystal. This has the advantage of making it possible to identify its structure and optionally to improve its stability.

Uses

(26) The powder according to the invention is intended for the feeding of animals, in particular ruminants, monogastric animals and aquaculture species.

(27) It can be used in a proportion of from 1 to 1000 g per metric tonne of animal feed, either for the purpose of providing a daily intake of metals, for example, to promote the growth of the animal, or, in a more isolated manner, with a view to compensating for a metal deficiency observed in the animal, or in the context of a specific diet.

EXAMPLES

Example 1

(28) In this example, a powder is prepared according to the first process, i.e. the process with multiple bases.

(29) Aqueous solutions of Mn glycinate, Zn glycinate and Cu glycinate are prepared separately.

(30) The 3 aqueous glycinate solutions are then combined in a single container and mixed.

(31) The content of the container is then taken so as to be sprayed into a stream of air.

(32) The equipment is adjusted so as to obtain a powder composed of particles of which the formulation after analysis is the following:

(33) TABLE-US-00001 Content as weight % in the Compound measured particle Zn sulfate•H.sub.2O 40.83 Mn sulfate•H.sub.2O 23.11 Cu sulfate•5 H.sub.2O 6.67 Glycine 29.39 Total 100
The particle size distribution of the particles is represented on the diagram of FIG. 1. Its characteristic values are as follows: 10% of the particles have a size less than 164.42 μm; the median size of the particles is 247.85 μm; and 90% of the particles have a size less than 388.29 μm.

(34) X-ray diffraction analyses of the powder show that the product contains various crystalline structures.

Example 2

(35) In this example, a powder was prepared according to the second process, i.e. the one with a single base.

(36) An aqueous solution is prepared in which Mn sulfate, Fe sulfate, Zn sulfate, Cu sulfate and glycine are mixed in a container.

(37) The base formulation is the following:

(38) TABLE-US-00002 Compound measured Content as weight % Fe sulfate•7 H.sub.2O 24.32 Zn sulfate•H.sub.2O 15.09 Mn sulfate•H.sub.2O 14.68 Cu sulfate•5 H.sub.2O 20.96 Glycine 24.95 Total 100

(39) The content of the container is dried in an incubator.

(40) Crystals of 0.5 to 3 mm which are clearly visible to the naked eye (of the salt crystal type) are thus obtained. The crystalline structures are close to those of the particles of example 1.