RU2073015C1 - Method of chitin-containing material preparing - Google Patents

Abstract

FIELD: biotechnology. SUBSTANCE: method involves the treatment of basidial fungi mycelial mass with alkali, washing off with water, treatment of the obtained fibrous mass before drying with organic solvents mixing with water, drying, impregnation with metal-ferromagnetic salt solutions followed by conversion of these salts to insoluble ferromagnetic state. EFFECT: improved method of preparing.

Description

 The invention relates to the field of chemical technology, specifically to a method for producing chitin-containing material from mycelial mass of fungi.

 Chitin-containing material can be used in the chemical industry and to solve environmental problems as a sorbent of heavy metal ions, including radioactive, transuranic and rare-earth elements, to extract them from aqueous solutions, suspensions, bottom sediments of water bodies, soil, sand, rocks and other complexes containing solid phase particles; for sorption cleaning of surfaces of concrete, asphalt and metal coatings, as well as for the removal of oil products and other high molecular weight compounds; in the paper industry for the manufacture of special grades of paper, cardboard and nonwoven materials; in medicine for the manufacture of enterosorbents, powders and dressings, as radiopaque substances and magnetically controlled drug carriers of prolonged action; in the textile industry for the manufacture of special varieties of threads, yarn and fabrics and in other fields.

 Chitin-containing materials made from the shells of crustaceans are known, capable of sorbing heavy metal ions (1). The main disadvantage of these materials as sorbents is the low sorption ability. This is due to the relatively small specific surface of the powders and granules made from crab chitin.

 Chitin-containing materials made from biomass of lower fungi are known, which have a large specific surface and are capable of sorbing heavy metal ions (2). The main disadvantages of the materials obtained by the prototype are poor mechanical properties that impede their widespread practical use. This is due to the fact that the mycelial fibers after processing and drying are firmly glued together and the material becomes brittle, crumbling into powder when handling it. Such material does not allow to obtain paper-like or non-woven products, for example, for filters or dressings without the use of additional additives. The chitin-containing material according to the prototype is not suitable for sorption purification of suspensions, sludges, soils and other systems with solid-phase particles, since its separation from solid-phase particles presents great technical difficulties. In medical use of chitin-containing material obtained by the prototype as an enterosorbent, an important disadvantage is the inability to purposefully control its movement inside the gastrointestinal tract.

 The aim of the invention is to obtain chitin-containing material consisting of separate strong and elastic fibers with magnetic properties.

 This goal is achieved by the fact that as a raw material use the mycelial mass of basidiomycetes having thick-walled hyphae. To prevent the fibers from sticking together and to maintain their elasticity before drying, the pulp is sequentially treated with water-miscible organic solvents in order to lower their boiling points, and after drying, they are impregnated with metal salts of ferromagnets with the subsequent transfer of these metals to an insoluble ferromagnetic state.

As a result, crystals of a ferromagnet are formed inside chitin-containing fibers, due to which the material acquires magnetic properties and at the same time maintains high sorption abilities. As metal ferromagnets, for example, iron, nickel, cobalt in the form of water-soluble salts can be used. By means of reduction or ferritization reactions, ferromagnets are converted into metallic form or ferrites are obtained, as well as through metal precipitation reactions from compounds such as carbonyls. It has been experimentally established that the optimal content of a ferromagnet in the fibers of a chitin-containing material can be from 5 to 60%
Example 1. The fruiting bodies of a basidiomycete fungus two-year-old crouton - Coltricia perennis (L. Fr.) Murr. grind to obtain a homogeneous hyphal mass. 200 g of dry mycelial mass is poured into 2 l of a 5% potassium hydroxide solution and incubated for 1.5 hours with constant stirring and a temperature of 60 ^o C. The alkaline solution is separated from the chitin-containing mass and washed for 20 minutes 5 times with 3 l of water in each shift. Chitin-containing material is squeezed from water, loosened and treated with water-miscible organic solvents in order to lower their boiling points. First, pour 1 l of ethanol for 15 minutes (t ^o bales 78.3 ^o C), alcohol is separated from the mass and fill it with 15 l 1 l acetone (t ^o bales 56.6 ^o C), the acetone is filtered off and the mass is filled for 15 minutes 1 l of ethyl ether (t ^o bale 34.5 ^o C). Processing is carried out with constant stirring. After treatment, the ether is separated, the mycelial mass is loosened and dried under vacuum.

 29 g of iron (III) chloride are dissolved in 200 ml of water, and 90 g of chitin-containing fibrous material is impregnated with this solution. 7 g of hydrazine hydrate are dissolved in 800 ml of water. The material impregnated with ferric chloride is transferred to a hydrazine solution, 200 ml of 96% ethanol are added and the mixture is kept under stirring for 1 hour at room temperature. Then the material is squeezed out, washed in three portions of water, 1 l each and dried. The dry material contains 10% iron and 90% chitin fibers.

Example 2. The fruiting bodies of the basidiomycete coriolus stiff-haired - Coriolus hirsutus (Wulf. Fr.) Quel. grind to obtain a homogeneous mycelial mass, pour 2 l of 10% sodium hydroxide solution and process for 1 hour at a temperature of 100 ^o C with constant stirring. The alkaline solution is separated from the chitin-containing mass and washed 5 times for 20 minutes in 3 l of water in each shift. After washing, the chitin-containing material is squeezed from water, loosened and poured for 15 min 1 l of ethyl alcohol (t ^o bale 78.3 ^o C), the alcohol is separated and the mass is poured for 15 min 1 l acetone (t ^o bale 58.6 ^o C) , acetone is filtered off and the material is poured for 15 min 1 l of ethyl ether (t ^o bale 34.5 ^o C). Solvent treatment is carried out with constant stirring. Ethyl ether is filtered off, the mass is loosened and dried under vacuum.

 58 g of iron (III) chloride are dissolved in 200 ml of water, and 80 g of chitin-containing fibrous material is impregnated with this solution. 14 g of hydrazine hydrate are dissolved in 800 ml of water. The material impregnated with ferric chloride is transferred to a hydrazine solution, 200 ml of acetone are added and the mixture is kept under stirring for 1 hour at room temperature. Then the material is squeezed out, washed in 3 shifts of water, 1 liter each and dried. The resulting 100 g of material contains 80% chitin fibers and 20% metallic iron.

 Example 3

 Fruit bodies of the basidiomycete coriolus multicolor Coriolus versicolor (L.Fr.) Quel. grind to obtain a homogeneous mycelial mass. 200 g of dry mycelial mass is poured into 3 l of a 5% sodium hydroxide solution and treated for 1 hour at room temperature with constant stirring. The alkaline solution is separated from the chitin-containing mass and washed for 20 minutes in 5 shifts of water of 3 l each. The chitin-containing material is squeezed out of the water and 1 liter of ethyl alcohol is poured for 15 minutes, the alcohol is filtered off, the mass is filled for 15 minutes with 1 liter of acetone, the acetone is separated and the material is filled for 15 minutes with 1 liter of ethyl ether. After separation of the ether, the chitin-containing material is loosened and dried.

 87 g of iron (III) chloride are dissolved in 200 ml of water, and 70 g of chitin-containing fibrous material is impregnated with this solution. 21 g of hydrazine hydrate are dissolved in 800 ml of water. The impregnated material is transferred to a hydrazine solution, 200 ml of 96% ethanol are added and the mixture is kept under stirring for 1 hour at room temperature. Then the material is squeezed out, washed in 3 shifts of water, 1 liter each and dried. The obtained 100 g of material consists of 70% of chitin fibers and 30% of metallic iron.

 Example 4. The fruiting bodies of the basidiomycete fungi coriolus zonal Coriolus zonatus (Nees. Fr.) Quel. grind to a homogeneous mass. 200 g of dry mycelial mass is poured into 2 l of 20% sodium hydroxide and treated for 1 hour at room temperature with constant stirring. The alkaline solution is separated from the chitin-containing mass and washed for 20 minutes 5 times with 3 liters of water in each shift. The washed material is squeezed from water and treated with organic solvents as in examples 1-3.

23 g of iron (II) chloride and hexahydrate are dissolved in 200 ml of water, and 90 g of chitin-containing fibrous material is impregnated with this solution. 20 g of hydrazine sulfate are dissolved in 800 ml of water and heated to 98 ^° C. The material impregnated with iron chloride is transferred to a solution of hydrazine sulfate and kept under continuous stirring for 1 hour. After that, the material is squeezed out, washed 3 times with water, 1 liter in each shift, squeezed out again and dried. The obtained 100 g of dry material consists of 90% of chitin-containing fibers and 10% of metallic iron.

Example 5. Fruit bodies of a basidiomycete oak sponge Daedalea quercina L. Fr. crushed into pieces and grind to obtain a homogeneous mycelial mass. 200 g of dry mycelial mass is poured into 2 l of a 5% sodium hydroxide solution and kept under stirring for 1 hour at 40 ^o C. Then the alkaline solution is separated from the mycelial mass and washed with 3 l of water for 20 minutes. Rinsing with water is repeated 5 times. After that, the mycelial mass is squeezed out of the water and 1 liter of ethyl alcohol is poured for 15 minutes, the alcohol is separated from the mass and 1 liter of acetone is filled for 15 minutes, the acetone is filtered off and the mycelial mass is filled for 15 minutes with 1 liter of ethyl ether. Processing with organic solvents is carried out with constant stirring. After treatment, the ether is filtered off. The chitin-containing material is loosened and dried under vacuum.

6.2 g of iron (II) nitrate, hexahydrate and 15.1 g of iron (III) nitrate, hexahydrate are dissolved in 200 ml of water. 95 g of chitin-containing fibrous material is soaked with this solution and incubated for 30 minutes. The wet material is placed on a tray in a thin layer and dried at 105 ^° C. The obtained 100 g of dry material contains 95% chitin fibers and 5% magnetite (a mixture of oxides of II- and III-valence iron).

Example 6. The fruiting bodies of a basidiomycetes fungus real Fomes fomentarius (L. Fr.) Gill. crushed into pieces and grind to obtain a homogeneous mycelial mass. 200 g of dry mycelial mass is poured into 2 l of a 30% sodium hydroxide solution and incubated for 1 hour with constant stirring at room temperature. The alkaline solution is filtered off and the mass is washed for 20 minutes 5 times with 3 L of water in each shift. After that, the mycelial mass is squeezed out of the water, loosened and filled with 1 l of propyl alcohol (t ^o bale 97.2 ^o C) for 15 minutes, propyl alcohol is separated from the mass and filled with methyl alcohol (t ^o bale 64.7 ^o C) 15 min, methyl alcohol in the same way replaced with ethyl ether (t ^o bale 34.5 ^o C). Processing is carried out with stirring. Ethyl ether is filtered off, the chitin-containing material is loosened and dried under vacuum.

In 1 liter of water, 74 g of iron (II) nitrate, hexahydrate and 181 g of iron (III) nitrate, hexahydrate, 40 g of chitin-containing fibrous material are dissolved, soaked in 200 ml of the solution, kept in a wet state for 30 minutes, and then placed on a pallet in a thin layer and placed in an oven. Drying is carried out at 105 ^o C. The dried material is again soaked in 200 ml of solution and re-dried at 105 ^o C. After that, the soaking and drying is carried out 3 more times. The final weight of the obtained material is 100 g. 40% of this weight is chitin-containing fibrous material, and 60% is magnetite.

Example 7. Fruit bodies of a basidiomycete larch sponge - Fomitopsis officinalis (Vill). Bond. et Sing. crushed and ground to a homogeneous mass. 200 g of dry weight is poured into 3 l of a 40% sodium hydroxide solution and treated for 1 hour with constant stirring at room temperature. The alkaline solution is filtered off, and the chitin-containing mass is washed with water for 20 minutes, 5 times, 3 liters in each shift. Then the chitin-containing material is squeezed out of water and poured for 15 min 1 l of dioxane (t ^o bp 101.3 ^o C), dioxane is separated from the mass and poured for 15 min 1 l of isopropyl alcohol (t ^o bip 82.2 ^o C). After separation of isopropyl alcohol, the chitin-containing material is poured for 15 minutes with 1 l of acetone (t ^o bale 56.6 ^o C). The acetone is filtered off, the material is loosened and dried.

4.7 g of iron (II) chloride and 11.7 g of iron (III) chloride are dissolved in 300 ml of water. This solution is impregnated with 95 g of chitin-containing fibrous material. Then the material is transferred into 800 ml of a 1% solution of sodium hydroxide heated to 40 ^o C. The material is maintained with constant stirring and maintaining the temperature for 1 hour. After that, the material is squeezed out, washed three times in water, 1 liter in each shift, squeezed out again and dried. 100 g of dry material consists of 95% of chitin-containing fibers and 5% of magnetite.

Example 8. The fruiting bodies of a basidiomycete fungus tinder fungus Ganoderma applanatum (Pers. Fr.) Pat. crushed and ground to a homogeneous mycelial mass. 200 g of dry weight is poured into 2 l of a 5% sodium hydroxide solution and treated for 2 hours at 80 ^o C with constant stirring. The alkaline solution is filtered off, and the chitin-containing mass is washed with water 5 times for 20 minutes, 3 liters per shift. Then the chitin-containing material is squeezed from water and poured for 15 min 1 l of propyl alcohol (t ^o bale 97.2 ^o C). Propyl alcohol is filtered off, and the material is poured for 15 minutes with 1 l of methyl alcohol (t ^o bale 64.7 ^o C). After separation of methyl alcohol, the material is poured with ethyl ether (t ^o bale 34.5 ^o C). Solvent treatment is carried out with stirring. The ether is separated by filtration, the material is loosened and dried.

23.5 g of iron (II) chloride and 58.5 g of iron (III) chloride are dissolved in 300 ml of water. This solution is impregnated with 75 g of chitin-containing fibrous material. The soaked material is transferred with stirring in 1 l of a 6% solution of ammonium hydroxide, heated to 50 ^o C and maintained with constant stirring for 1 hour. After that, the material is squeezed out, washed three times in water, 1 liter in each shift, squeezed out again and dried. 100 g of the obtained dry material consists of 75% of chitin-containing fibers and 25% of magnetite.

 Example 9. The fruiting bodies of a basidiomycetes fungus varnished - Ganoderma lucidum (Leyss. Fr.) Karst. crushed and ground to a homogeneous mycelial mass. 200 g of dry weight is poured into 2 l of a 10% sodium hydroxide solution and treated for 1.5 hours at room temperature with constant stirring. The alkali is separated from the chitin-containing pulp and washed with water 5 times for 20 minutes and 3 l in each shift. Then the chitin-containing material is squeezed from the water and 2 l of propyl alcohol are poured for 15 minutes. The alcohol is filtered off and the material is poured with 2 L of acetone for 15 minutes. Solvent treatment is carried out with stirring. After separation of acetone, the material is loosened and dried.

25 g of iron (II) sulfate, heptahydrate and 12 g of iron (III) chloride are dissolved in 300 ml of water. This solution is impregnated with 95 g of chitin-containing fibrous material. The soaked material is transferred with stirring in 1 liter of a 1% potassium hydroxide solution, heated to 40 ^o C and incubated for 1 hour with constant stirring. After that, the material is squeezed out, washed three times in water and dried. 100 g of dry material consists of 95% of chitin-containing fibers and 5% of magnetite.

Example 10. Fetal bodies of basidiomycete fence mushroom Gloeophyllum Sepiarium (Wulf. Fr.) Karst. crushed and ground to a homogeneous mycelial mass. 200 g of dry weight is poured into 3 l of a 5% sodium hydroxide solution and treated for 1 hour at 100 ^o C with constant stirring. The alkali is separated from the chitin-containing pulp and washed with it 5 times with water for 20 minutes and 3 l in each shift. Then the material is squeezed from the water and poured for 15 min 2 l of ethyl spit. The alcohol is filtered off and the mass is poured with 2 L of acetone for 15 minutes. Processing with organic solvents is carried out with stirring. The chitin-containing material filtered from acetone is loosened and dried.

50 g of iron (II) sulfate, heptahydrate and 24 g of iron (III) chloride are dissolved in 300 ml of water. This solution is impregnated with 90 g of chitin-containing fibrous material. The soaked fibrous material is transferred into 1 l of a 2% sodium hydroxide solution, heated to 45 ^o C and kept under stirring for 1 hour. Then the material is squeezed out, washed 3 times in water, squeezed out again and dried. 100 g of the obtained material consists of 95% of chitin-containing fibers and 10% of magnetite.

Example 11. The fruiting bodies of a basidiomycetes root sponge - Nonterobasidion annosum (Fr.) Bref. crushed and ground to a homogeneous mycelial mass. 200 g of dry weight is poured into 4 l of a 3% sodium hydroxide solution and treated for 1 hour at 80 ^o C with constant stirring. The alkaline solution is filtered off and the chitin-containing mass is washed 5 times with water for 20 minutes and 3 l in each shift. Then the material is squeezed from water and 2 liters of acetone are poured for 15 minutes. Acetone is filtered off, and chitin-containing fibrous material is poured for 15 min 2 l of ethyl ether. Processing is carried out with stirring. After ethyl ether has been separated, the chitin-containing fibrous material is loosened and dried.

5 g of cobalt (II) chloride and 12 g of iron (III) chloride are dissolved in 250 ml of water. This solution is impregnated with 95 g of chitin-containing fibrous material. The soaked material is transferred with stirring in a 1.5% solution of ammonium hydroxide with a volume of 1 liter. The mixture was heated to 40 ^° C. and held for 1 hour with stirring. After that, the material is squeezed out, washed three times with water, 1 liter in each shift, squeezed out again and dried. The obtained 100 g of dry material consists of 95% of chitin-containing fibers and 5% of cobalt ferrite CoFe ₂ O ₄ .

Example 12. The fruiting bodies of a basidiomycetes fungus edged - Fomitopsis pinicola (Sw. Fr.) Karst. crushed and ground to a homogeneous mycelial mass. 200 g of dry weight is poured into 2 l of a 20% sodium hydroxide solution and treated at 60 ^° C. for 1 hour with stirring. Then the chitin-containing fibrous material is separated from the alkali and washed 5 times with water for 20 minutes and 3 l in each shift. The water is squeezed out, and the chitin-containing material is treated with organic solvents as in Example 1 and dried.

24 g of cobalt (II) chloride and 58.5 g of iron (III) chloride are dissolved in 300 ml of water. This solution is impregnated with 75 g of chitin-containing fibrous material. The impregnated material is transferred into 1 l of 6% ammonium hydroxide, heated to 45 ^o C and maintained with constant stirring for 1 hour. After that, the material is squeezed out, washed three times in water, 1 liter in each shift, squeezed out again and dried. 100 g of the obtained dry material consists of 75% of chitin-containing fibers and 25% of cobalt ferrite CoFe ₂ O ₄ .

Example 13. The fruiting bodies of a basidiomycete fungus oak tinder, Inonotus dryophilus (Berk.) Murr. crushed and ground to a homogeneous mycelial mass. 200 g of dry weight is poured into 3 l of 30% sodium hydroxide and treated for 1 hour at 40 ^o C with stirring. Then the alkali is filtered off, and the material is washed 5 times with water for 20 minutes and 3 l in each shift. After separation of the water, the chitin-containing material is treated with organic solvents as in Example 1, and then dried.

13.2 g of nickel sulfate are dissolved in 300 ml of water, and 95 g of chitin-containing fibrous material is impregnated with this solution. Separately, 22.5 g of Rochelle salt, 13.5 g of sodium hydroxide, 0.4 g of sodium carbonate, 5.7 ml of formalin and 8 ml of ethyl alcohol are dissolved in 700 ml of water. The soaked chitin-containing material is transferred to the prepared solution, mixed and heated to 95 ^° C. The mixture is kept at this temperature with constant stirring for 30 minutes, then it is cooled, washed 3 times with a 10-fold volume of water, squeezed and dried. The obtained 100 g of material consists of 95% of chitin-containing fibers and 5% of metallic nickel.

Example 14. The fruiting bodies of a basidiomycete fungus tinder fungus Inonotus radiatus (Sow. Fr.) Karst. crushed and ground to a homogeneous mycelial mass. 200 g of dry weight is poured into 2 l of 40% sodium hydroxide and treated at 60 ^o C for 1 hour with stirring. The alkali is filtered off, and the chitin-containing material is washed 5 times with water for 20 minutes and 3 l in each shift. After squeezing the water, the chitin-containing fibrous material is treated with organic solvents as in Example 1, and then dried.

53 g of nickel sulfate are dissolved in 250 ml of water, and 80 g of chitin-containing fibrous material is impregnated with this solution. Separately, 750 g of Rochelle salt, 54 g of sodium hydroxide, 1.6 g of sodium carbonate, 23 ml of formalin and 32 ml of ethyl alcohol are dissolved in 750 ml of water. Soaked chitin-containing material is transferred to the prepared solution, mixed and heated to 98 ^° C. With constant stirring, the mixture is kept at this temperature for 30 minutes, then cooled, washed three times with a 10-fold volume of water and dried. The obtained 100 g of dry material consist of 80% of chitin-containing fibers and 20% of metallic nickel.

 Example 15. The fruiting bodies of a basidiomycete fungus, the bristle-haired tinder fungus - Inonotus hispidus (Bull. Fr.) Karst. crushed and ground to a homogeneous mycelial mass. 200 g of dry weight is poured into 3 l of a 5% sodium hydroxide solution and treated for 1.5 hours at room temperature with constant stirring. Then the alkali is filtered off and the chitin-containing material is washed with water similarly to the previous examples. After squeezing out the water, the chitin-containing fibrous material is treated with the organic solvents of Example 1 and then dried.

14 g of nickel sulfate are dissolved in 200 ml of water. This solution is impregnated with 95 g of chitin-containing fibrous material. Dissolve in 800 ml of water: sodium hypophosphate 22 g, ammonium chloride 14 g and lead (II) chloride 50 mg. The temperature of the solution was adjusted to 45 ^° C. and, with constant stirring, fibrous chitin-containing material impregnated with nickel sulfate was transferred to the solution. In this state, the material is kept for 0.5 hours, and then squeezed out, washed three times with water, 1 liter in each shift, squeezed out and dried again. 100 g of the obtained dry material is 95% composed of chitin-containing fibers and 5% metallic nickel.

 Example 16. The fruiting bodies of the basidiomycete fungus irpex milky Irpex lacteus Fr. grind to a homogeneous mycelial mass. 200 g of dry weight is poured into 3 l of a 10% potassium hydroxide solution and treated for 1 hour at a constant temperature and with constant stirring. Then the alkali is separated, and the chitin-containing material is washed with water and treated with organic solvents as in Example 1, and then dried.

42 g of nickel sulfate are dissolved in 300 ml of water. This solution is impregnated with 85 g of chitin-containing material. 66 g of sodium hypophosphite, 42 g of ammonium chloride and 150 g of lead (II) chloride are dissolved in 700 ml of water. The solution is heated to 40 ^o C and transferred into it with constant stirring chitin-containing fibrous material impregnated with Nickel sulfate. In this condition, the material is kept for 1 hour, and then squeezed out and washed three times with water of 1 liter in each shift, after which the material is again squeezed and dried. The dry material consists of 85% of chitin-containing fibers and 15% of metallic nickel.

 Example 17. The fruiting bodies of a basidiomycete fungus lenzites birch - Lenzites betulina (L. Fr.) Fr. grind to a homogeneous mycelial mass. 200 g of dry weight is poured into 2 l of a 3% sodium hydroxide solution and treated for 2 hours at room temperature with stirring. The alkali is filtered off, and the chitin-containing material is washed with water and treated with organic solvents as in Example 1, after which the material is loosened and dried.

50 g of nickel sulfate, heptahydrate are dissolved in 300 ml of water, and 90 g of chitin-containing fibrous material is soaked in this solution. 20 g of sodium hypophosphite, 50 g of ammonium chloride, 70 g of sodium citrate are dissolved in 700 ml of water, and 80 ml of a 25% solution of ammonium hydroxide are added. The temperature of the solution was brought to 80 ^o C and transferred to it chitin-containing fibrous material soaked in Nickel sulfate. For an hour, the material is kept under these conditions and with constant stirring, then squeezed out, washed three times with 1 liter of water in each shift, squeezed out and dried again. The resulting 100 g of material consists of 90% of chitin-containing fibers and 10% of metallic nickel.

Example 18. The fruiting bodies of a basidiomycete fungus tinder fungus Phellinus igniarius (L. Fr.) Quel. crushed and ground to a homogeneous mycelial mass. 200 g of dry weight is poured into 3 l of a 5% sodium hydroxide solution and treated for 1 hour at 40 ^o C with constant stirring. The alkali is filtered off, the chitin-containing material is washed with water and treated with organic solvents as in Example 1, after which the material is loosened and dried.

50 g of nickel sulfate, heptahydrate are dissolved in 300 ml of water, and 90 g of chitin-containing fibrous material is soaked in this solution. 120 g of sodium hypophosphite, 13 g of citric acid, 75 g of ammonium chloride and 5 mg of thiocarbomide are dissolved in 700 ml of water. This solution is heated to 90 ^° C. and the chitin-containing material soaked in nickel sulfate is transferred into it. For 20 minutes the material is intensively mixed, then separated from the liquid, washed three times with water, 1 liter in each shift, squeezed and dried. 100 g of the obtained dry material is 90% composed of chitin-containing fibers and 10% of metallic nickel.

Example 19. The fruiting bodies of the basidiomycetes fungus oak false - Phellinus robustus (Karst.) Bourd. et Galz. crushed and ground to a homogeneous mycelial mass. 200 g of dry weight is poured into 2 l of a 3% sodium hydroxide solution and treated for 1 hour at 60 ^o C with stirring. The alkali is separated, and the chitin-containing material is washed with water and treated with organic solvents as in Example 1. After that, the chitin-containing material is loosened and dried.

40 g of nickel (II) chloride, heptahydrate are dissolved in 200 ml of water, and 90 g of chitin-containing fibrous material is impregnated with this solution. 20 g of hydrazine sulfate are dissolved in 800 ml of water and heated to 98 ^° C. The chitin-containing material impregnated with nickel chloride is gradually transferred to a hydrazine sulfate solution and kept under stirring for 40 minutes. After that, the material is separated from the liquid, washed three times in a 10-fold volume of water, squeezed and dried. 100 g of the obtained dry material consists of 90% of chitin-containing fibers and 10% of metallic nickel.

Example 20. The fruiting bodies of a basidiomycete fungus pine sponge Fomitopsis pinicola (Sw. Fr.) Karst. crushed and ground to a homogeneous mycelial mass. 200 g of dry weight is poured into 3 l of a 40% sodium hydroxide solution and treated at 100 ^° C. for 1 hour with stirring. The alkali is separated from the chitin-containing material, washed with water and treated with organic solvents as in Example 1. After that, the chitin-containing material is loosened and dried.

14.5 g of dicobaltocarbonyl are dissolved in 200 ml of toluene. This solution is impregnated with 95 g of chitin-containing fibrous material. The material is heated in a water bath to 100 ^o C and maintained with stirring until dry (complete disappearance of the smell of toluene). 100 g of dry material consists of 95% of chitin-containing fibers and 5% of cobalt metal.

Example 21. The mycelial mass of the basidiomycetes fungus winter polyporus - Polyporus brumalis Pers. Fr obtained by culturing in a fermenter on a sterile liquid nutrient medium of the following composition, g / l: starch 20; corn extract 15; K ₂ HPO ₄ 0.5; KH ₂ PO ₄ - 0.5; MgSO ₄ • 7H ₂ O 0.25 at a pH of 4.5. Air flow rate is 0.5 l / l / min. Stirring of the medium is carried out at 80 rpm and a temperature of 25 ^o C. the Growth time of 5 days. The mycelial mass is separated from the culture medium by filtration and washed with water. Then, the mycelial mass is poured with a 5% sodium hydroxide solution based on the ratio of the dry weight of mushroom mycelium to the liquid volume as 1:15. The alkali treatment is carried out for 1 hour with stirring at room temperature. The chitin-containing fibrous material is separated from the alkaline solution, washed with water and treated with organic solvents as in Example 1. Then, the material is loosened and dried.

43.5 g of dicobaltocarbonyl are dissolved in 200 ml of toluene. This solution is impregnated with 85 g of chitin-containing fibrous material. The material is heated in a water bath to 100 ^o C and maintained with constant stirring until completely dry. 100 g of dry material consists of 85% of chitin-containing fibers and 15% of cobalt metal.

 Example 22. The mycelial mass of the basidiomycetes oak sponge - Daedalea quercina L. Fr. obtained by culturing in a fermenter on a liquid nutrient medium as in Example 21. The mycelial mass is poured with 10% sodium hydroxide solution based on the ratio of dry weight of mushroom mycelium to liquid volume as 1:20. Treatment with alkali is carried out for 1 hour with constant stirring and room temperature. The chitin-containing fibrous material is separated from the alkaline solution, washed with water and treated with organic solvents as in Example 1. Then, the material is loosened and dried.

87 g of dicobaltocarbonyl are dissolved in 450 ml of toluene. This solution, divided into three parts of 150 ml, is washed successively with 70 g of chitin-containing fibrous material. After soaking with each part of the solution, the material is dried in a water bath at 100 ^o C and impregnated once again. After three operations of impregnation of drying, 100 g of material is obtained consisting of 70% of chitin-containing fibers and 30% of cobalt metal.

Example 23. The mycelial mass of the basidiomycetes fungus real - Fomes fomentarius (L. Fr.) Gill. obtained by culturing in a fermenter on a sterile liquid nutrient medium Norkrans with the addition of beer wort (10%) at pH 5.8 and a temperature of 28 ^o C. Air flow rate was 0.5 l / l / min. Growing time 5 days. The mycelial mass is separated from the culture fluid by filtration and washed with water. Then the mycelial mass is poured with a 5% sodium hydroxide solution based on the ratio of the dry weight of mushroom mycelium to the liquid volume as 1:10. The alkali treatment is carried out for 1 hour with stirring and a temperature of 60 ^o C. The chitin-containing fibrous material is separated from the alkaline solution, washed with water and treated with organic solvents as in example 1, and then loosened and dried.

23 g of cobalt (II) chloride are dissolved in 200 ml of water, and 90 g of chitin-containing fibrous material is impregnated with this solution. 23 g of sodium hypophosphite, 23 g of ammonium chloride and 0.5 g of urotropin are dissolved in 800 ml of water. The solution is heated to 45 ^° C. and a chitin-containing material soaked in cobalt chloride is transferred into it. With constant stirring, the material is kept for 30 minutes, then squeezed out, washed in three shifts of water, 1 liter each, squeezed out again and dried. 100 g of dry material consists of 90% of chitin-containing fibers and 10% of cobalt metal.

Example 24. The mycelial mass of the basidiomycete coriolus multicolor
Coriolus versicolor (L. Fr.) Quel. obtained by culturing in a fermenter on a sterile Pelzer nutrient medium at a pH of 5.8 and a temperature of 28 ^o C for 5 days. Stirring of the medium is carried out at a speed of 80 rpm, the air flow rate is 0.5 l / l / min. The grown mycelial mass is separated from the culture medium and washed with water. Treatment with alkali, washing and processing with organic solvents is carried out analogously to example 1. After that, the chitin-containing material is loosened and dried.

33 g of cobalt (II) chloride are dissolved in 200 ml of water, and 85 g of chitin-containing fibrous material is impregnated with this solution. 110 g of sodium citrate and 22 g of sodium hypophosphite are dissolved in 800 ml of water. The solution is heated to 90 ^° C. and the chitin-containing material soaked in a solution of cobalt chloride is transferred into it. For an hour, the material is stirred, then squeezed out, washed three times in water, 1 liter per shift, squeezed out again and dried. 100 g of dry material is 85% composed of chitin-containing fibers and 15% of metallic cobalt.

Example 25. Fruit bodies of a basidiomycetes fungus winter fungus Polyporus brumalis Pers. Fr grown on solid nutrient medium containing 2% agar-agar, 10% beer wort, 1% glucose and 0.4% yeast extract. Cultivation is carried out at a temperature of 18-20 ^o C for 2 weeks with a light-periodic mode of 12:12 and illumination of 1500 lux. Mature fruit bodies are ground to a homogeneous mycelial mass. Alkaline treatment, washing and treatment with organic solvents are carried out analogously to example 1. Chitin-containing fibrous material is loosened and dried.

26 g of cobalt (II) sulfate are dissolved in 200 ml of water, and 90 g of chitin-containing fibrous material is soaked in this solution. 110 g of sodium tartrate, 90 g of ammonium sulfate and 25 g of sodium hypophosphite are dissolved in 800 ml of water. The solution is heated to 90 ^o C and transferred to it chitin-containing material, impregnated with a solution of cobalt sulfate. The material is stirred for an hour, then squeezed, washed three times with water, 1 liter in each shift, then squeezed and dried. 100 g of dry material consists of 90% of chitin-containing material and 10% of cobalt metal.

Claims (1)

 A method for producing chitin-containing material, including alkaline treatment of the fungal mycelial mass, washing the product with water and drying, characterized in that the basidiomycetes mycelial mass is used as the fungal mycelial mass, the fibrous mass obtained after alkaline treatment and the washed product are subsequently treated with water miscible before drying organic solvents in order to lower their boiling points, and after drying they are impregnated with solutions of metal salts of ferromagnets with the subsequent transfer of these salts to an insoluble ferromagnetic state by reduction to a metal or obtaining a ferromagnetic compound.