RU2056762C1 - Food addition enriched with trace elements for animals, fishes and poultry and a method of its preparing - Google Patents

Abstract

FIELD: agriculture. SUBSTANCE: microorganisms as components of foods were enriched with trace elements. This enrichment is carried out by growing or incubation yeast (for example, Candida utilis) in the presence of trace elements. Yeast (C. utilis) is grown in the presence of manganese salt which is added at the mean log-phase of growth at concentration 100 mg/l, or in the presence of cobalt salt (concentration at the level 10-12 mg/l), or in the presence of selenium salt which is added at the exponential growth phase up to the concentration 0.15 mg. Yeast C. utilis is incubated with iodide at concentration 800 mg/l and hydrogen peroxide at concentration 40 mg. Trace element content in proposed food addition is at least 2 g/kg. EFFECT: enhanced effectiveness of food addition proposed. 10 cl, 2 tbl

Description

 The invention relates to agriculture, in particular, to the field of feed production and for the enrichment of trace elements of feed for animals, poultry and fish.

 In modern industrial livestock breeding, as well as poultry and fish farming, a concentrated type of feeding is used with dry granular or loose compound feeds that fully satisfy the physiological need of the body for energy and nutritious and biologically active substances.

 Nutrient intake rates can vary significantly depending on the structure of the feed, temperature and humidity conditions, the type of animal, its age and a number of other factors.

 However, trace elements remain vital for any diet, with a lack of which there is a slowdown in the growth of young animals, a decrease in resistance to diseases, a decrease in productivity and the level of reproduction.

 The food components of compound feeds satisfy the need for trace elements only partially and require their additional introduction.

 For this reason, to increase the balance of feed, various sources of trace elements are introduced into their composition, most often as part of the so-called feed additives containing trace elements in inorganic form.

 Known, for example, is a mineral mixture for feeding animals, which contains sea salts that act as a carrier for mineral and fortifying additives. To prepare it, organic salts, such as phosphate, are added to the mixture of sea salts and oligoelements to a concentration exceeding the saturation point, and the precipitate is separated.

 A feed additive is described, which is a microelement concentrate containing a core from a granular mineral carrier, for example, from monocalcium phosphate, coated with a layer of a binding agent from the group of polyhydric alcohols, on which a layer of powdered trace mineral salts is applied.

 A mixture is patented that provides an adjustable amount of trace elements in water, which contains relatively insoluble compounds of trace elements in water and a binding agent, for example, gypsum, which holds only trace elements in the mixture. The mixture may take the form of tablets.

 A micronutrient concentrate for feed fortification can be obtained by fusing oxides, carbonates or other volatile salts of micronutrients with alkali metal phosphate. In this case, the compounds of trace elements will be included in a water-soluble polymetallic phosphate glass, which is quickly cooled and ground.

 One of the simplest in composition can be recognized as a feed additive enriched with trace elements, which is a mixture of trace elements precipitated from their neutralized solution with chalk.

 Accordingly, one of the simplest methods can be recognized as a method of obtaining an additive enriched with microelements, which consists in the fact that the salts of trace elements are dissolved in phosphoric acid, and chalk is added to this solution until it is completely neutralized and the resulting product is dried.

 A common disadvantage of the above-mentioned feed additives enriched with microelements is that microelements are present in them in an inorganic form.

 At the same time, it is well known that inorganic substances significantly enhance their physiological effect when they are included in organic complexes.

 A feed additive containing biologically permissible trace elements compounds is proposed; bio-inorganic elements that do not form precipitates with trace elements; cyclic and heterocyclic organic compounds with synergistic and absorption activity with respect to trace elements; amphoteric monoaminocarboxylic acid as a ligand; polyoxy compounds that increase the permeability of cell walls. Such a feed additive contains trace elements in the form of organic complex compounds.

 To prepare a mixture enriched with trace elements, intended for use as part of food components, dry ash is treated with a stream of reagents capable of dissolving and converting trace elements compounds into an assimilable form (for example, into complexes or salts of lactic acid).

 The feed additive enriched with microelements can be recognized as the closest to the one that contains the product of the interaction of trace elements with products contained in milk whey.

 The process of obtaining this trace element concentrate is that trace element compounds are dissolved in whey products that do not contain milk sugar. As whey products, whey concentrate or other products of its partial processing are used.

 The relative disadvantage of this feed additive is the need to use food raw materials for its production and in the absence of information on the possibility of long-term storage of the obtained concentrate and, therefore, on the feasibility of its large-scale production.

 The purpose of the invention is the preparation of a micronutrient-rich feed additive that is to be stored for a long time without loss of quality, in which micronutrients are present in organic form, as well as the development of a method for preparing such an additive characterized by sufficient manufacturability.

 The goal was achieved as a result of the fact that a method was developed for enriching microbial biomass with microelements and the microbial biomass obtained by this method was used as a source of microelements in the feed additive.

 Recently, as the main protein component of compound feeds, along with animal and vegetable, a protein of microbial origin is most often used yeast biomass.

 As a rule, the microbial biomass obtained by growing the corresponding microorganisms in artificial conditions, contains the number of microelements that do not cover the physiological needs of animals, fish and birds when usually accepted portions of the microbial protein are introduced into the feed.

 The applicant experimentally showed that when microorganisms are grown in the presence of elevated concentrations of the relevant trace elements or when microorganisms are incubated with sources of trace elements, the biomass of microorganisms can accumulate trace elements in such quantities that an acceptable addition of such biomass to the feed makes them complete in terms of trace elements.

 The applicant found that under optimal cultivation conditions it is possible to achieve a very high level of incorporation of microelements into the microbial cell, as shown, in particular, in the table. 1 results.

 In order to show that the level of micronutrient accumulation in the yeast cell is sufficient to use biomass as a micronutrient-rich feed additive, in table. 2 shows the calculation of the effective dose received by the applicant feed additives.

 The presented calculations clearly show that the proposed feed additive is quite applicable for the preparation of feeds, since, according to accepted standards, the content, for example, of yeast proteins of airborne or haprin in poultry feeds should be 1-5% i.e. per 1 ton of feed, it is recommended to add 10-50 kg of yeast protein.

 The essence of the proposal is as follows.

 A microorganism, the biomass of which can serve as a source of protein in the composition of animal feed, is grown under conditions usually accepted for its cultivation on a nutrient medium enriched with microelements, or the grown microorganism is additionally incubated with sources of microelements.

 The specific concentration of the trace element in the medium, the time it was introduced into the cultivation medium, the chemical form of the trace element are selected individually, which depends, in particular, on the type of microorganism used.

 It is most expedient to use yeast, for example, of the genera Candida, Saccharomyces, the technique of large-scale cultivation of which is well developed, but other microorganisms can be used to obtain a feed additive of the required quality.

The resulting biomass usually contains from 2 to 70 g of trace elements per 1 kg of dry biomass, and the level of inclusion of trace elements can range from 50 to 90%
For the preparation of animal feed, you can get portions of biomass enriched with individual trace elements or groups of trace elements.

 Microbial biomass containing increased amounts of trace elements is normally separated from the fermentation medium and dried.

 Practice shows that, for example, yeast biomass obtained in significant quantities can be stored for a long time without losing its consumer properties.

 Obtained by the proposed method, the feed additive has the form of a dry fine powder and contains, in addition to completely trace elements in organic form, protein, vitamins and other biologically active substances.

 The essence of the proposal is illustrated in more detail by the following examples.

PRI me R 1. Candida utilis yeast was grown in a Bioflo fermenter with a working volume of 230 ml in a medium containing (g / l) monosubstituted ammonium phosphate (10.0), magnesium sulfate (0.7), disubstituted sodium phosphate ( 7.0), monosubstituted potassium phosphate (6.0), under the conditions of the accumulative regime with a growth rate of 0.2 h ^-1 . On Wednesday, a fractional (every hour) solution of labeled cobalt sulfate with a specific activity of 490 imp / μg was supplied and the cobalt concentration was maintained at 10 mg / L.

 Cultivation was carried out at a temperature of 28 degrees for 6 hours.

 A total of 2.3 g of yeast biomass was obtained with a cobalt content of 9 mg / g of dry biomass, determined by the radioisotope method.

 The inclusion of cobalt in yeast cells amounted to 98% of its content in solution.

 Analysis of the distribution of cobalt between the components of yeast cells by differential centrifugation and gel filtration on Sephadex G-50 and G-10 showed that all cobalt was associated with the organic structures of the cell, with 72% cobalt being associated with low molecular weight soluble proteins, 8% with high molecular weight soluble proteins , 10% with cell walls and 6% with membrane structures.

 A study of plasmolysis for 60 minutes at 90 degrees biomass showed the absence of unbound cobalt. Associated with low molecular weight proteins (5000-10,000 Da), cobalt was 80%, while only 20% of cobalt was associated with high molecular weight compounds.

 Example 2. Candida utilis yeast was grown in a fermenter with a working volume of 6.4 L under the conditions described in Example 1, but an unlabeled cobalt salt was used, the concentration of which in the medium was maintained at 12 mg / ml.

 A total of 240 g of biomass was obtained with a cobalt content of 5 mg / g of dry biomass, which was determined by atomic absorption spectrometry.

Disposal of cobalt from the medium was 70%
PRI me R 3. The yeast Candida utilis was grown in 2 flasks with a working volume of 100 ml on a temperature-controlled shaker in a nutrient medium containing 1 ethanol.

 In the middle of the logarithmic growth phase, 50 mg of labeled manganese sulfate was introduced into the medium. 4 hours after the introduction of the isotope, the cultivation process was stopped.

500 mg biomass with a manganese content of 20 mg / g dry biomass was obtained. The degree of utilization of manganese from the medium was 90%
After plasmolysis of biomass, 14% of labeled manganese was found in the soluble fraction and 82% in sediment after centrifugation for 30 minutes at 10,000 g.

 By gel filtration on Sephadex G-10, it was found that all the manganese of the soluble fraction is bound to low molecular weight proteins.

 PRI me R 4. The yeast Candida utilis was grown in a Fermatron fermenter with a working volume of 100 l in the cumulative mode as described in example 1.

 The collected biomass in an amount of 500 g was additionally incubated for 30 minutes at a temperature of 80 degrees in a medium containing 8.0 potassium iodide and 40 mm hydrogen peroxide.

After completing the additional incubation, the iodine content in the biomass was 7.8 mg / g dry biomass, and the degree of iodine utilization from the medium was 47%
50% of utilized iodine was associated with polysaccharides, 24% with high molecular weight proteins, 26% with low molecular weight proteins.

 After lyophilization of biomass, the iodine content did not decrease.

 PRI me R 5. The yeast Candida utilis was grown in flasks on a temperature-controlled shaker at a temperature of 28 degrees in a liquid nutrient medium containing 1% ethanol and 1.5 mm ammonium sulfate.

 In the lag phase, 0.15 mM labeled sodium selenite was added to the culture medium. The total length of the growing cycle was 18 hours.

 By radioindication, it was shown that 90% of selenium was consumed from the medium by yeast cells and the selenium content was 4.5 mg per 1 g of dry biomass.

 All selenium consumed was bound to proteins and free amino acids.

 The materials presented confirm that the proposed method allows to obtain a feed additive containing significant amounts of trace elements converted into organic form.

 The applicant does not have information about the popularity of the proposed method of feed fortification with microelements due to their enrichment of the protein component of the feed of microbial biomass, nor about the popularity of the proposed method of enrichment of microbial biomass with trace elements for these purposes.

 It is known, however, that in some cases sources of microelements are introduced into the composition of media for the cultivation of microorganisms, including yeast, but this is not done to enrich their biomass with microelements, but to cover the microorganisms' own needs for these microelements or to stimulate the biosynthesis of certain metabolites.

 In this regard, the applicant believes that the feed additive enriched with microelements and the method for its preparation, as technical solutions, meet the requirements of the invention.

Claims (9)

 1. A micronutrient-rich feed additive for animals, fish and birds, containing micronutrients associated with an organic carrier, characterized in that the carrier of micronutrients is yeast biomass, and the micronutrient content of the feed additive is at least 2 g / kg.  2. A method of obtaining a feed additive, providing for the binding of trace elements with an organic carrier, characterized in that the trace elements are included in the composition of the biomass of yeast.  3. The method according to claim 2, characterized in that the biomass is grown in the presence of trace elements.  4. The method according to claim 3, characterized in that the Candida utilis yeast is grown in the presence of trace elements.  5. The method according to claim 2, characterized in that the Candida utilis yeast is incubated with sources of trace elements.  6. The method according to claim 4, characterized in that the Candida utilis yeast is grown continuously with fractional addition of cobalt salt and the concentration of cobalt salt is maintained at a level of 10-12 mg / l.  7. The method according to claim 4, characterized in that the Candida utilis yeast is grown in the presence of a manganese salt, introduced in the middle of the logarithmic growth phase at a concentration of 100 mg / L.  8. The method according to claim 4, characterized in that the Candida utilis yeast is grown in the presence of a selenium salt, introduced in an exponential growth phase to a concentration of 0.15 mmol.  9. The method according to claim 5, characterized in that the yeast Candida utilis is incubated with iodide salt at a concentration of 800 mg / l and with hydrogen peroxide at a concentration of 40 mmol.

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