RU2386641C2 - Method for synthesis of cross-linked retinol-modified salt of hyaluronic acid - Google Patents

Abstract

FIELD: chemistry.

SUBSTANCE: invention relates to synthetic polymer chemistry and more specifically to methods for synthesising cross-linked retinol-modified salts of hyaluronic acid (HA), which is a natural polymer from the polysaccharide class. The method involves chemical reaction of a salt of hyaluronic acid and retinol with at least one cross-linking agent, while subjecting the initial reagents to simultaneous reaction at pressure ranging from 5 to 1000 MPa and shear deformation in a mechanochemical reactor at temperature ranging from 20°C to 50°C. The reactor used is preferably a Bridgman anvil or an auger-type device, e.g. a double-screw extruder. The technical result is design of a universal environmentally safe method which enables production of a range of cross-linked retinol-modified salts of hyaluronic acid in a single-step process without a liquid medium, obtaining desired products with quantitative output.

EFFECT: method does not require large energy, labour and water inputs, enables use of a wide variety of initial reagents, including water-insoluble salts of hyaluronic acid.

19 cl, 18 ex

Description

The invention relates to natural polymers from the class of polysaccharides, and in particular to a fundamentally new method for producing chemically modified retinol cross-linked salt of hyaluronic acid. The invention also relates to a bioactive composition based on crosslinked salts of retinol-modified hyaluronic acid and can be used in various fields of medicine, in cosmetics, for example, in aesthetic dermatology and plastic surgery.

Unknown methods for producing chemically modified retinol crosslinked salts of hyaluronic acid, however, a number of methods are known for chemically unmodified crosslinked HA salts by reacting HA salts with various crosslinking agents in an organic and (or) aqueous medium [US Patent 7125860, publ. in 2006]. In another known method, HA salts are first reacted with cinnamic acid chloride in dimethylformamide medium and the subsequent crosslinking step is carried out under the influence of UV radiation [US Pat. No. 5,462,976, publ. in 1995]. The disadvantages of these methods are the two-stage chemical processes, the high toxicity of organic reagents and solvents, the time-consuming cleaning of the final products.

Known methods for producing crosslinked salts of HA in one chemical stage [US patent 6013679, publ. in 2000, US patent 6537979, publ. in 2003], or a method for producing cross-linked HA salts, comprising reacting the HA sodium salt with iron, aluminum, and chromium chlorides in an aqueous medium [US Pat. No. 5,532,221, publ. in 1996], or a method for producing cross-linked HA salts, comprising reacting the sodium salt of HA with divinyl sulfone in an alkaline environment [US Pat. No. 4,582,865, publ. in 1986]. The disadvantages of the above single-stage methods are the high toxicity of crosslinking and other agents, an increase in the volume of the reaction system and production facilities, as well as high water consumption.

Known methods for producing crosslinked salts of HA using low toxicity crosslinking agents [US patent 4716154, publ. in 1987; US patent 4716224, publ. in 1987; US patent 4963666, publ. in 1990]. This method has the following disadvantages: the use of a large excess of reagents, complicated methods of purification and isolation of the target products (dialysis, washing off excess reagents, etc.), a multi-stage process, an increase in the volume of the reaction system and production facilities, and a large consumption of energy and water.

There is also a simpler method for producing unmodified crosslinked HA salts, comprising the step of reacting the sodium salt of HA with diglycidyl esters of alkanediols in an acidic aqueous medium [US patent 4886787, publ. in 1989]. This method has the following disadvantages: the use of a large excess of cross-linking agents, an increase in the volume of the reaction system and production facilities, high water consumption, and the need to install bulky and expensive treatment facilities, which is associated with large energy, material, and labor costs. In addition, there is no information on the receipt of other crosslinked salts of HA, except for sodium. It should be specially noted that due to the fact that the interaction of the starting reagents is carried out in an aqueous medium, this method does not allow the use of water-insoluble salts of HA as the starting reagents.

Crosslinked HA salts chemically modified with retinol and methods for their preparation are not known, however, a method for producing crosslinked HA salts modified with antioxidants by chemical inoculation is known [RF Patent No. 2174985, publ. in 2001]. The crosslinking and grafting reactions are carried out using organic solvents (hexane, toluene, methylene chloride, N-methylpyrrolidone, acetone and very toxic methanol). Spatially hindered phenols (substituted 3,5-di-tert-butylphenols) are used as antioxidants. The disadvantages of this method are: multi-stage and long duration of the process (more than a day), the use of large quantities of toxic organic solvents and the difficulty of cleaning the final products. In addition, retinol was not used as antioxidants.

Compositions based on crosslinked HA salts modified with retinol are also unknown. However, compositions are known including retinol or retinoic acid and unmodified HA [RF application No. 97113248, publ. in 1999; RF application No. 2004118419, publ. in 2005]. These compositions are intended to be used as a cosmetic or dosage form (together with the medicine). The disadvantage of these compositions is that they include poorly compatible (or non-compatible) components, from which it is very difficult to prepare a homogeneous highly effective composition.

Closest to this invention are compositions comprising retinol or retinol palmitate and plant extracts and natural polysaccharides, including HA [US patent 6426080, publ. in 2002]. These compositions are intended to protect the skin from the harmful effects of free radicals and are used to prepare various gels and cosmetic creams, including sunblock. The description of the invention does not provide examples of the implementation of the composition containing HA, and there is no data on the resistance of the composition to its destruction in the presence of hydroxyl radicals. In addition, the method of obtaining the composition requires the addition of auxiliary components, such as surfactants, solvents, etc., contributing to the homogenization of the mixture of components.

The objective of this invention is to create an environmentally friendly fundamentally new method that allows you to get previously unknown cross-linked salts of HA modified with retinol in a single-stage technological mode in the absence of a liquid medium, without large energy, labor and water costs, while obtaining the target products in high yield, and also to use as starting reagents the most diverse, including water-insoluble, salts of HA.

The task is also to create a wide assortment for various applications, compositions based on more stable cross-linked HA and at the same time modified with retinol HA, which can be in the body for a long time (more than a week) without significant destruction. In addition, prolong the action of retinol due to the formation of a strong chemical bond with it and the additional introduction of various antioxidants as a functional additive, which quickly interact with hydroxyl radicals responsible for the destruction processes. In addition, to simplify the composition and the method of mixing its components is to exclude the addition of excipients, such as surfactants, solvents.

The problem is solved by creating a universal environmentally friendly method for producing a crosslinked salt of hyaluronic acid modified with retinol, which consists in the chemical interaction of the salt of hyaluronic acid, retinol with at least one cross-linking agent, subjecting the starting reagents to simultaneous pressure in the range from 5 to 1000 MPa and shear strain in the mechanochemical reactor at a temperature of from 20 ° to 50 ° C.

As a salt of hyaluronic acid, you can use a salt selected from the series: tetraalkylammonium, lithium, sodium, potassium, calcium, magnesium, barium, zinc, aluminum, copper, gold or a mixed salt of hyaluronic acid from the above series or hyaluronic acid hydrosalt.

In particular, the salt of hyaluronic acid is a sodium salt or a mixed salt or a sodium salt.

A crosslinking agent is at least one of the following ethers: ethylene glycol diglycidyl ether, diethylene glycol diglycidyl ether (DEG-1), triethylene glycol diglycidyl ether, polyethylene glycol diglycidyl ether, diglycidyl ether, propylene glycol di-1-diglycidyl ether, diglycidyl ether 6-hexanediol.

The molar ratio of the salt of hyaluronic acid or the sum of its salts to the crosslinking agent or to the sum of the crosslinking agents is from 50: 1 to 5: 1.

The molar ratio of the salt of hyaluronic acid to retinol is from 100: 1 to 10: 1, and the molar ratio of retinol to the crosslinking agent or to the sum of the crosslinking agents is in the range from 1:10 to 1: 2.

The duration of pressure and shear deformation, in particular, is in the range from 0.1 to 10 minutes.

As a mechanochemical reactor, it is possible to use, in particular, Bridgman anvils or a screw type apparatus.

In the case of a process where the Bridgman anvils are a mechanochemical reactor, the reaction mixture is sheared by changing the angle of rotation of the lower anvil, in particular in the range of 50 to 350 degrees. Moreover, for a better implementation of the method, it is preferable to pre-homogenize the starting reagents in a mixer at a temperature of from 20 to 50 ° C until a homogeneous powder mixture is obtained. In this case, a mill or a screw type mixer, for example a twin screw extruder, can be used as a mixer.

In particular, a mechanochemical reactor is a screw type apparatus, for example, selected from the series: twin-screw extruder with unidirectional rotation of screws, twin-screw extruder with oppositely directed rotation of screws, twin-screw extruder with a set of cams of various types, for example, transport, locking, grinding.

The method can be implemented, in particular in stages, for example, first, the hyaluronic acid salt is chemically reacted together with a crosslinking agent, after which the resulting crosslinked hyaluronic acid salt is reacted with retinol together with a crosslinking agent added to the reaction mixture. In this case, the molar ratio of the salt of hyaluronic acid to the crosslinking agent or to the sum of the crosslinking agents is in the range from 50: 1 to 5: 1, and the ratio of retinol to the obtained crosslinked salt of hyaluronic acid based on the initial amount of hyaluronic acid and additionally introduced into the reaction mixture at least one cross-linking agent or to the sum of cross-linking agents is in the range from 1: 100 to 1:10 and from 1:10 to 1: 2, respectively.

In particular, at least one functional additive, for example, an antioxidant, food, stabilizing, modifying, drug, can be added to the reaction mixture.

The solution of this problem became possible due to the fact that the reaction process of the starting reagents is carried out, in contrast to the known methods for the preparation of crosslinked HA salts (US patent, US 4886787) and chemically modified HA salt, by grafting (RF patent No. 2174985) not in solution but by reacting the starting reagents in a solid powder state under the influence of pressure and shear strain. This allowed us to achieve a new technical result, which consists in creating a universal environmentally friendly method that allows you to get a number of crosslinked salts of HA, modified with retinol, in a single-stage technological mode in the absence of a liquid medium, with the target products in high yield. The method does not require large energy, labor and water costs, allows you to use as source reagents the most diverse, including water-insoluble, salts of HA.

The problem is also solved by the fact that a bioactive composition based on a retinol-modified crosslinked HA salt obtained by the above method is created, including a modified crosslinked HA salt and at least one functional additive, for example, an antioxidant, a food, stabilizing, modifying, medicinal product with a molar ratio of components: modified cross-linked salt of HA to the functional additive in the range from 100: 1 to 1: 1.

As a functional additive, depending on the desired result and purpose, you can use a compound from the series: L-cysteine, D-cysteine, D, L-cysteine, cystine, methionine, glycine, L-glutamine, L-proline, 3-hydroxyproline , 4-hydroxyproline, chondroitin-6-sulfate, heparin, 1-thioglycerol, 2-mercaptoethanol, 2-mercaptobenzthiazole, thiourea, 1-dodecantiol, 1,4-dimercaptobutan-2,3-diol, tannin, caffeine, uracil , quercetin, dihydroquercetin, riboxin, succinic anhydride, maleic anhydride, acrylamide, nicotinamide, urea, guanidine, melamine, glyc rin, pentaerythritol, D-glucose, lactose, maltose, sucrose, sorbitol, mannitol, pectin, starch, cellulose, carboxymethylcellulose, polyacrylamide, polyvinyl alcohol; acid from the series: glycolic, lactic, tartaric, citric, malic, linoleic, linolenic, arachidonic, oleic, palmitic, almond, cinnamon, barbituric, succinic, maleic, acrylic, salicylic, acetylsalicylic, nicotinic, cyanuric, thioglycol dimercaptosuccinic, alginic, glucuronic, galacturonic; sodium salt of the acid from the above series.

In particular, the functional additive is L-cysteine and / or thioglycolic acid, or a mixture of L-cysteine, riboxin and lactic acid. In this case, L-cysteine and thioglycolic acid have pronounced antioxidant properties.

The composition can be obtained by mixing the components in the usual manner.

The composition, in particular, can also be obtained under conditions of obtaining a modified cross-linked salt of hyaluronic acid, that is, by additionally introducing the desired functional additive or mixture of additives into the initial reaction composition.

Unlike the known composition, the claimed composition contains retinol modified HA. In addition, in the new composition, HA is in the crosslinked state a, the modifier retinol is chemically bonded to the crosslinked salt.

This made it possible to obtain a new technical result — expanding the assortment and fields of application of the composition, as well as prolonging the action of retinol due to the formation of a strong chemical bond with it and the additional introduction of various antioxidants as a functional additive, which quickly interact with hydroxyl radicals responsible for the destruction processes, there is a significant increase in its effectiveness compared with a composition based on unmodified HA. In addition, the method of obtaining the composition does not require the addition of auxiliary components, such as surfactants, solvents.

The quantitative nature of the product yield depends on the degree of interaction of the glycidyl groups of the crosslinking agents with the hydroxyl groups of the HA salts and the hydroxyl group of retinol. Therefore, the quantitative yield of the target products was judged by the IR Fourier spectral analysis of the starting reagents and reaction products. It has been established that the spectra of these products completely lack characteristic bands of glycidyl groups of crosslinking agents (850-860 and 900-920 cm ^-1 ) and there are additional bands (1090-1120 cm ^-1 ) characteristic of ether groups resulting from the interaction of glycidyl groups groups of crosslinking agents with hydroxyl groups of HA salts and retinol. The yield of crosslinked salts of the modified HA was determined by the extraction of the final reaction products with ethyl alcohol at 50 ° C. The products of the interaction of DEG-1 and DEBD with retinol isolated from alcohol extracts, which did not react with HA salts, accounted for 1-5 wt.%, Of the amount of initial components, which corresponds to almost quantitative (95-99%) yield of salts of modified GK. The presence of retinol was determined by the characteristic bands (960-970, 1100-1120 and 1230-1240 cm ^-1 ) in the IR spectra of the final products. The presence of functional additives in bioactive compositions was determined by the following characteristic bands in the IR spectra: for L-cysteine 1580-1590, 1600-1610 and 3000-3020 cm ^-1 ; for thioglycolic acid 1700-1720 and 2550-2570 cm ^-1 ; for riboxin 1080-1090, 1220-1230, 1590-1600 and 1700-1710 cm ^-1 ; for lactic acid 1130-1135 and 1725-1735 cm ^-1 . The degree of swelling (characterizing the degree of crosslinking of HA) was determined by the standard method [Workshop on high molecular weight compounds. - M .: Chemistry, 1985, p.111]. The resistance to degradation in the presence of hydroxyl radicals was evaluated by the half-life of reducing the viscosity of the hydrogels of the final products, as described by Wong et al. in Inorganic Biochemistry, B.14, P.127 (1981) and in the patent of the Russian Federation No. 2174985. The control value of the half-cycle for reducing the viscosity of a 2% hydrogel composition based on the starting sodium salt of HA was 6 hours (see comparative example 18).

The invention can be illustrated by the following examples:

Obtaining modified cross-linked salts of HA

Example 1. 160.0 mg (4 · 10 ^-4 mol) of powdered sodium salt of HA, 11.4 mg (4 · 10 ^-5 mol) of retinol and 27.0 mg (8 · 10 ^-5 mol) of diethylene glycol diglycidyl ether ( DEG-1) is homogenized in a mill at 20 ° C for 10-15 minutes. Then, a homogeneous powder mixture is placed on the Bridgman lower anvil (diameter of the working surface = 3 cm), covered with an upper anvil, put the anvils under a press and subjected to a pressure of 700 MPa at 20 ° C, with an angle of rotation of the lower anvil of 250 ° for 1 min. Then relieve pressure, remove the anvil from the press. The yield of modified crosslinked sodium salt of HA is 194.0 mg (98.0%), the degree of swelling in water reaches 6 ml / g. 4 mg of the reaction products of retinol and DEG-1 were isolated from the alcoholic extract of the final product. The magnitude of the half-cycle of reducing the hydrogel viscosity of the final product is 120 hours.

Example 2. 160.0 mg (4 · 10 ^-4 mol) of powdered sodium salt of HA, 11.4 mg (4 · 10 ^-5 mol) of retinol and 17.0 mg (8 · 10 ^-5 mol) of diglycidyl ether 1, 4-butanediol (DEBD) is homogenized in a mill at 50 ° C for 10-15 minutes. Then a homogeneous powder mixture is placed on the Bridgman lower anvil (diameter of the working surface = 3 cm), covered with an upper anvil, put the anvils under a press and subjected to a pressure of 1000 MPa at 20 ° C, with an angle of rotation of the lower anvil of 200 ° for 50 sec. Then relieve pressure, remove the anvil from the press. The yield of the modified crosslinked sodium salt of HA is 184.0 mg (98.0%), the degree of swelling in water reaches 5 ml / g. 4 mg of the reaction products of retinol and DEBD were isolated from the alcoholic extract of the final product. The magnitude of the half-cycle of reducing the viscosity of the hydrogel of the final product is 125 hours.

Example 3. Performed analogously to example 1, however, in contrast to it, retinol is taken in an amount of 1.1 mg (4 · 10 ^-6 mol), and DEG-1 is taken in an amount of 13.5 mg (4 · 10 ^-5 mol). The yield of modified crosslinked sodium salt of HA is 174.6 mg (100%), the degree of swelling in water reaches 4 ml / g.

Example 4. Performed similarly to example 2, however, in contrast to it, instead of the sodium salt of HA, a mixed sodium-calcium salt was taken with a molar ratio of sodium: calcium = 2: 1. The yield of the modified crosslinked mixed HA salt is 184.0 mg (98.0%); the degree of swelling in water reaches 5 ml / g.

Example 5. Performed similarly to example 1, however, in contrast to it, instead of the sodium salt of HA, a mixed sodium-aluminum salt was taken with a molar ratio of sodium: aluminum = 3: 1. The yield of the modified crosslinked mixed HA salt is 187.0 mg (98.0%); the degree of swelling in water reaches 5 ml / g.

Example 6. Performed similarly to example 2, however, in contrast to it, instead of the sodium salt of HA, a mixed sodium-zinc salt was taken with a molar ratio of sodium: zinc = 2: 1. The yield of the modified crosslinked mixed HA salt is 183.0 mg (97.0%); the degree of swelling in water reaches 6 ml / g.

Example 7. Performed similarly to example 2, however, in contrast to it, instead of the sodium salt of HA, a mixed sodium-copper salt was taken with a molar ratio of sodium: copper = 2: 1. The yield of the modified crosslinked mixed HA salt is 181.0 mg (96.0%); the degree of swelling in water reaches 6 ml / g.

Example 8. Performed similarly to example 2, however, in contrast to it, the angle of rotation of the lower anvil is 350 degrees, and the exposure time is 1.4 minutes. The yield of the modified crosslinked HA salt is 186.0 mg (99.0%); the degree of swelling in water reaches 8 ml / g.

Example 9. Performed similarly to example 2, however, in contrast to it, instead of the sodium salt of HA, a mixed sodium-gold salt was taken with a molar ratio of sodium: gold = 3: 1. The angle of rotation of the lower anvil is 50 degrees, and the exposure time is 0.1 min. The yield of the modified crosslinked mixed HA salt is 193.0 mg (98.0%); the degree of swelling in water reaches 5 ml / g.

Example 10. Performed similarly to example 1, however, in contrast to it, retinol was taken in an amount of 1.1 mg (4 · 10 ^-6 mol), and DEG-1 was taken in an amount of 2.7 mg (8 · 10 ^-6 mol). The yield of modified crosslinked sodium salt of HA is 163.8 mg (100%), the degree of swelling in water reaches 12 ml / g.

Example 11. Performed similarly to example 2, however, in contrast to it, instead of the sodium salt of HA, a sodium salt was taken with a molar ratio of sodium: hydrogen = 1: 1. The yield of modified crosslinked hydrosalt HA is 180.0 mg (98.0%), the degree of swelling in water reaches 6 ml / g.

Example 12. Performed analogously to example 10, however, in contrast, carried out without retinol. The yield of crosslinked sodium salt of HA is 162.7 mg (100%), the degree of swelling in water reaches 15 ml / g. Then, retinol and DEG-1 are added to the obtained crosslinked HA salt in an amount as described in Example 1, and then the synthesis is carried out analogously to Example 1. The yield of the modified crosslinked sodium salt of HA is 196.0 mg (97.0%), the degree of swelling in water reaches 7 ml / g. 6 mg of the reaction products of retinol and DEG-1 were isolated from the alcoholic extract of the final product. The magnitude of the half-cycle of reducing the viscosity of the hydrogel of the final product is 115 hours.

Example 13. A mixture of 400.0 g (1 mol) of sodium salt of HA, 28.6 g (0.1 mol) of retinol and 84 g (0.4 mol) (DEBD) is subjected to simultaneous pressure and shear deformation at 50 ° C and a pressure of 5 MPa in a twin-screw extruder with unidirectional rotation of the screws for 10 minutes The yield of the modified crosslinked sodium salt of HA is 487.6 g (95.0%), the degree of swelling in water reaches 6 ml / g. 25 g of the reaction products of retinol and DEG-1 were isolated from the alcoholic extract of the final product. The magnitude of the half-cycle of reducing the viscosity of the hydrogel of the final product is 110 hours.

Obtaining a composition based on a modified crosslinked salt of HA

Example 14. Performed similarly to example 2, however, in contrast to it, 48 mg (4 · 10 ^-4 mol) of L-cysteine was added to the initial reaction mixture. Yield 236.4 mg (100%) of a composition containing a crosslinked sodium salt of HA modified with retinol and L-cysteine. The magnitude of the half-cycle of reducing the viscosity of the hydrogel of the final product is 135 hours.

Example 15. Performed similarly to example 1, however, in contrast to it, 0.37 mg (4 · 10 ^-6 mol) of thioglycolic acid was added to the initial reaction mixture. Yield 198.8 mg (100%) of a composition containing a crosslinked sodium salt of HA modified with retinol and thioglycolic acid. The magnitude of the half-cycle of reducing the viscosity of the hydrogel of the final product is 125 hours.

Example 16. Performed similarly to example 14, but in contrast to it, 3.7 mg (4 · 10 ^-5 mol) of thioglycolic acid were added to the initial reaction mixture. Yield 240 mg (100%) of a composition containing a crosslinked sodium salt of HA modified with retinol, L-cysteine, and thioglycolic acid. The magnitude of the half-cycle of reducing the viscosity of the hydrogel of the final product is 150 hours.

Example 17. 5.13 g (0.01 mol) of a crosslinked sodium salt of HA modified with retinol obtained in Example 13, 1.21 g (0.01 mol) of L-cysteine, 268 mg (0.001 mol) of riboxin and 90 mg (0.001 mol) of lactic acid are homogenized in a mill at 50 ° C for 10 minutes. The yield of the composition is 6.7 g (100%). The magnitude of the half-cycle of reducing the viscosity of the hydrogel of the final product is 102 hours.

Example 18 - Comparative example. Analogously to example 17, but instead of the modified crosslinked HA salt, 4.0 g (0.01 mol) of the sodium salt of HA and 0.286 g (0.001 mol) of retinol are introduced into the composition. The yield of the composition is 5.854 g (100%). The control value of the half-cycle for reducing the viscosity of a 2% hydrogel of this composition was 6 hours.

The above examples convincingly show that a universal ecologically safe method has been created that allows one to obtain a number of new cross-linked salts of HA modified with retinol in a single-stage technological mode in the absence of a liquid medium, with the target products in high yield. The method does not require large energy, labor and water costs, allows you to use as source reagents the most diverse, including water-insoluble salts of HA. Also created a new bioactive composition based on a new modified crosslinked HA salt obtained by the above method, including a modified crosslinked HA salt and at least one functional additive, for example, an antioxidant. A significant increase in the effectiveness of the composition was achieved, in particular, the resistance to destruction in the presence of hydroxyl radicals was increased by 17–25 times compared to the control value for the half-period for reducing the viscosity of a 2% hydrogel of the composition based on the initial HA salt.

Claims (19)

1. A method of obtaining a crosslinked salt of hyaluronic acid modified with retinol, which consists in the fact that they carry out the chemical interaction of the salts of hyaluronic acid, retinol with at least one crosslinking agent, subjecting the starting reagents to a simultaneous pressure in the range from 5 to 1000 MPa and shear strain in a mechanochemical reactor at a temperature of from 20 to 50 ° C. 2. The method according to claim 1, characterized in that the salt of hyaluronic acid is a salt from the series: tetraalkylammonium, lithium, sodium, potassium, calcium, magnesium, barium, zinc, aluminum, copper, gold, or a mixed salt of hyaluronic acid from the above series , or hyaluronic acid hydrosalt. 3. The method according to claim 2, characterized in that the salt of hyaluronic acid is a sodium salt. 4. The method according to claim 2, characterized in that the salt of hyaluronic acid is a mixed salt. 5. The method according to claim 2, characterized in that the salt of hyaluronic acid is a sodium salt. 6. The method according to claim 1, characterized in that the crosslinking agent is at least one ether from the series: ethylene glycol diglycidyl ether, diethylene glycol diglycidyl ether, triethylene glycol diglycidyl ether, polyethylene glycol diglycidyl ether, 1,4-butylene glycol diglycidyl ether, diglycidyl ether diglycidyl ether 1,6-hexanediol. 7. The method according to claim 1, characterized in that the molar ratio of the salt of hyaluronic acid to the crosslinking agent or to the sum of the crosslinking agents is from 50: 1 to 5: 1. 8. The method according to claim 1, characterized in that the molar ratio of the salt of hyaluronic acid to retinol is from 100: 1 to 10: 1. 9. The method according to claim 1, characterized in that the molar ratio of retinol to crosslinking agent or to the sum of crosslinking agents is in the range from 1:10 to 1: 2. 10. The method according to claim 1, characterized in that the duration of the pressure and shear strain is from 0.1 to 10 minutes 11. The method according to claim 1, characterized in that the Bridgman anvils or auger type apparatus are a mechanochemical reactor. 12. The method according to claim 11, characterized in that the Bridgman anvils are a mechanochemical reactor, and shear deformation is carried out by changing the angle of rotation of the lower anvil. 13. The method according to p. 12, characterized in that the angle of rotation of the Bridgman anvil is in the range from 50 to 350 °. 14. The method according to item 13, wherein the initial reagents are pre-homogenized in a mixer at a temperature of from 20 to 50 ° C. To obtain a homogeneous powder mixture. 15. The method according to 14, characterized in that the mixer is a mill or a screw type mixer, for example, a twin screw extruder. 16. The method according to claim 11, characterized in that the mechanochemical reactor is a screw type apparatus. 17. The method according to p. 16, characterized in that the apparatus is selected from the series: twin-screw extruder with unidirectional rotation of the screws, twin-screw extruder with oppositely directed rotation of the screws, twin-screw extruder with a set of cams of various types, for example, transport, locking, grinding. 18. The method according to claim 1, characterized in that the hyaluronic acid salt is first chemically reacted together with a crosslinking agent, after which the resulting crosslinked hyaluronic acid salt is reacted with retinol together with a crosslinking agent added to the reaction mixture. 19. The method according to p. 18, characterized in that the molar ratio of the salt of hyaluronic acid to a crosslinking agent or to the sum of the crosslinking agents is in the range from 50: 1 to 5: 1, and the ratio of retinol to the resulting crosslinked salt of hyaluronic acid based on the starting material the amount of hyaluronic acid and to at least one cross-linking agent or to the sum of cross-linking agents additionally added to the reaction mixture is in the range from 1: 100 to 1:10 and from 1:10 to 1: 2, respectively.