RU2310338C2 - Feed additive for fish - Google Patents

Abstract

FIELD: feed processing industry.

SUBSTANCE: claimed additive contains purified flax oil and β-carotene and is introduced into fish feed in amount of 1-3 % based on feed mass, wherein ratio of flax oil and β-carotene is 8:1.

EFFECT: feed additive with high immunomodulating and biological activity.

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Description

The invention relates to the field of fish farming, in particular to feed products that increase the body's defenses, and can be used for the prevention and treatment of gill necrosis.

One of the main causes of gill necrosis is adverse environmental conditions: oxygen deficiency in water, water pollution with biogenic ammonia of exogenous or endogenous origin, as well as pollution of water bodies with organochlorine pesticides and heavy metals.

It is known that ammonia in fish is a product of nitrogen decay and 97-98% of it is excreted through the gills.

Ammonia in water is present in two forms: free ammonia (NH ₂ ) and low toxic ammonium ion (NH ₄ ). With increasing water temperature, pH, the occurrence of oxygen deficiency, the excretion of ammonia is greatly inhibited. In all cases, gills are affected as the main organ that stands in the way of toxin circulation, and this happens in the season (April-September) with a maximum in spring and summer.

In recent years, in the practice of aquaculture, subalin, prepared on the basis of the Bacillus subtilis spore bacillus mixed with food, has been used to combat gill necrosis.

The use of antibiotics is also known: chloramphenicol, tetracycline and streptomycin.

In order to increase the immune status, a complex of fat-soluble vitamins A, D, E and C is introduced into the diet [1].

However, these additives do not lead to the normalization of the condition of fish.

It is known that the drug linetol is included in the feed composition for the prevention and treatment of necrosis of Atlantic salmon fins. Linetol contains 51% linolenic acid ester [2].

Known feed additive containing β-carotene called Vitaton for American catfish, Russian sturgeon and rainbow trout, introduced into the diet, starting from the larva. Vitaton gives a growth-promoting effect against a background of a significant increase in survival [3]. However, this is not enough to prevent fish diseases.

The closest in technical essence and the achieved effect to the invention is the addition of carotenoids from purple ascidia to fish food for the prevention and treatment of nutritional diseases in juvenile Pacific salmon in aquaculture [4].

This supplement did not produce the expected results.

The aim of the present invention is to obtain a feed additive that contributes to the prevention and treatment of gill necrosis.

This goal is achieved by introducing purified flaxseed oil and β-carotene of microbial origin in the amount of 1-3% of the feed weight into the fish diet, while the ratio of linseed oil to β-carotene is 8: 1.

We have studied that with gill necrosis in the lipids of bester and carp, the levels of lysophosphatidylcholines increase by 14 and 44%, respectively, the ratio of phosphatidylethanolamines to phosphatidylcholines by 1.6 and 1.8 times and the ratio of ω3 / ω6 decreases by 4 and 2.5 times compared to healthy fish.

The revealed changes in the balance of lipids and fatty acids indicate an increased energy expenditure of sick fish due to membrane lipids, which leads to an imbalance of individual phospholipids and a deficiency of essential fatty acids of the ω3 series in the fish organism.

The considered complex of pathogenetic changes that occur with these diseases of fish is caused by significant disorders in lipid metabolism, the result of which is a violation of the antioxidant system of the body.

The unidirectionality of phospholipid and fatty acid metabolism in carp and bester with gill necrosis indicates the unified nature of this disease, which makes it possible to use common methods of treatment and prevention.

The proposed feed additive is a lipid preparation - a balanced mixture of refined linseed oil and β-carotene of microbial origin. It is the composition of these components, taken in a ratio of 8: 1, that enhances the beneficial effect on the fish organism of each of its components.

The high immunomodulatory and biological activity of the proposed feed additives is determined by the introduced ingredients and their relationship.

β-carotene is a well-known natural antioxidant, immunostimulant. Under natural conditions, fish, such as sturgeons, consume a significant amount of carotenoids contained in live food organisms. With intensive factory cultivation in the absence of natural feed, the diets of juveniles are almost completely devoid of these pigments, since dry artificial feed does not contain them or they contain in small quantities.

Flaxseed oil is a source of polyunsaturated fatty acids of the linolenic series.

It is known from the prior art that both β-carotene and flaxseed oil are used in fodder production, but in this invention their use is due to the enhancement of each other's properties, resulting in a symbiotic effect, which gives the right to declare this proposal as an invention. Flaxseed oil contributes to better absorption of β-carotene, and it, in turn, enhances the properties of flaxseed oil, contributes to its preservation from spoilage. Their complex use leads to increased adaptation of the fish organism to adverse environmental conditions.

Thus, the combination of essential features allows you to get in the inventive additive over-cumulative effect, which consists in enhancing the properties of these features, which allows us to conclude about the patentability of the claimed technical solution.

A feed additive is obtained by adding β-carotene of microbial origin to linseed oil, and then to the feed.

The method is as follows.

For prophylactic purposes, bester underyearlings and two-year-old carp are introduced into a standard compound feed a feed additive consisting of linseed oil + β-carotene of microbial origin taken in a ratio of 8: 1 in an amount of 1-3% of the feed weight. The feed additive is used for a month before the onset of high water temperature.

As a remedy for gill necrosis, the proposed feed supplement is introduced into standard food in the same amount and ratio of components for 15 days, after which recovery of the gills is noted.

Examples of specific performance of the method.

Example 1. Bester yearlings with an initial average weight of about 3 g and a planting density of 700 ind./m ^{2 were} kept in plastic pools with a circular flow of water, two-year-old carp with an average weight of 90 g were kept in live fish cages with an area of 0.05 ha of 1.5 thousand copies in each.

1 month before the expected summer water temperature increase above 26 ° С, the bester’s yearlings and two-year-old carp were fed with standard compound feed with the addition of a lipid preparation (linseed oil + microbial β-carotene in a ratio of 8: 1) for 1 month in the amount of 1% of mass of feed. The control was a standard compound feed without additives.

When the temperature of the water increased, 2 pcs. Bester and 1 carp were found signs of gill necrosis.

Example 2. Analogously to example 1, the bester underyearlings and two-year-old carp were introduced into the standard compound feed lipid preparation in an amount of 2% by weight of the feed.

No gill necrosis was observed during the fish season.

Example 3. Analogously to example 1, the bester underyearlings and two-year-old carp were introduced into the standard compound feed feed additive in the amount of 3% by weight of the feed.

Gill necrosis was not observed during the summer.

In control 32 pcs. Bester yearlings and 30 pcs. two-year-old carp fell ill with gill necrosis.

Example 4. For experiments on the therapeutic effect of the feed additive were selected yearlings of bester and two-year-old carp with pronounced signs of the disease. In control, fish with healthy gills were observed.

A lipid supplement was introduced into the feed in an amount of 1% (with a ratio of components of 8: 1). Recovery of the gills during visual examination was noted after 20-25 days of feeding.

Example 5. Analogously to example 4, in the feed was introduced a lipid supplement in an amount of 2%.

After 12-14 days of feeding, the gills recovered from the fish (the gills cleared of necrotic tissue, healing, color restoration).

Example 6. Analogously to example 4, a lipid supplement was introduced into the feed in the amount of 3% by weight of the feed.

After 12-14 days of feeding, a complete recovery of the gills was noted.

In the control, the total number of diseased fish was 48.

Example 7. Analogously to example 5, the bester underyearlings and two-year-old carp in the standard compound feed was injected with a lipid preparation in an amount of 2% by weight of the feed, while the ratio of components in the lipid preparation was 7: 1.

After 12-14 days of feeding, the recovery of the gills was noted, however, hydration of the tissues was observed in the fish.

Example 8. Analogously to example 5, the ratio of components in the lipid preparation was 7: 2.

After 12-14 days of feeding, the gills recovered, however, the erythropoiesis decreased in fish.

Example 9. Analogously to example 5, the ratio of components in the lipid preparation was 6: 1.

After 12-14 days of feeding, the fish showed complete recovery, but hydration of the tissues was observed.

Example 10. Analogously to example 5, the ratio of components in the lipid preparation was 6: 2.

After 12-14 days of feeding, the fish fully recovered, but a decrease in the intensity of erythropoiesis was noted.

In the control, the number of cases amounted to 48 pcs.

The results of the experiments are summarized in table 1.

Table 1 The number of fish infected with gill necrosis during prophylactic and therapeutic feeding with a lipid supplement Example No. Fish species LD,% LD, ratio of components The number of diseased fish, pcs. Prophylaxis. Bester 0 ⁺ one 8: 1 3 one. Carp 2 ⁺ 2. - "- 2 - "- 0 3. - "- 3 - "- 0 The control - "- - - 62 4.Treatment - "- one 8: 1 0 5. - "- 2 - "- 0 6. - "- 3 - "- 0 The control - "- - - 48 7. - "- 2 7: 1 0 8. - "- 2 7: 2 0 9. - "- 2 6: 1 0 10. - "- 2 6: 2 0 The control - "- - - 48

Thus, the most effective in the treatment of gill necrosis, including in the temporary and economic aspect, is the addition of a lipid preparation to the feed in an amount of 2% with a ratio of components of 8: 1.

Information sources

1. Vasilyeva L.M., Noyaksheva T.A. Medical and preventive measures for sturgeon cultivation. (To help ichthyopathologists, fish farmers) // Astrakhan. - 2000. - P.10-11.

2. Prevention and treatment of necrosis of the fins of Atlantic salmon / Korenev ON and others // 3 All. conference on salmon-like fish. Thes. doc. - Moscow. - 1988. - S. 161-162.

3. The effectiveness of feed additives containing β-carotene when growing juvenile fish / Kiselev A.Yu., Avchieva PB, Tyurenkov VA, Tyurenkov AA // Pisces. x-in. - 2004. - No. 2. - S.50-52.

4. Ways to increase the vitality of juvenile Pacific salmon during artificial cultivation / Valova V.N. // International symposium on mariculture. Krasnodar, Nebug, Sept. 24-27, 1995: Abstract. doc. - M. - 1995. - P.51-52 (prototype).

Claims (1)

A fish feed additive comprising β-carotene, characterized in that it additionally contains purified linseed oil and is introduced into the fish diet in an amount of 1-3% of the feed weight, while the ratio of linseed oil to β-carotene is 8: 1.