RU2611368C1 - Method of production of metronidazole nanocapsules in sodium alginate - Google Patents

Abstract

FIELD: nanotechnology.

SUBSTANCE: metronidazole powder is added to sodium alginate suspension in hexane and 0.01 g of E472s then acetone is added, the obtained suspension is filtered and dried. The mass ratio core:shell in nanocapsules is 1:3, 1:1, 1:5 or 5:1.

EFFECT: nanocapsules of metronidazole manufacture process simplification and acceleration and weight yield increase.

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Description

The invention relates to the field of nanotechnology, medicine, pharmacology and veterinary medicine.

Previously known methods for producing microcapsules of drugs. So, in US Pat. 2092155, IPC A61K 047/02, A61K 009/16, published 10/10/1997, the Russian Federation proposed a method of microencapsulation of drugs based on the use of special equipment using ultraviolet radiation.

The disadvantages of this method are the duration of the process and the use of ultraviolet radiation, which can affect the process of formation of microcapsules.

In US Pat. 2095055, IPC A61K 9/52, A61K 9/16, A61K 9/10, Russian Federation, published 10.11.1997, a method for producing solid non-porous microspheres, including melting a pharmaceutically inactive carrier substance, dispersing the pharmaceutically active substance in a melt in an inert atmosphere, spraying the resulting dispersion in the form of fog in a freezing chamber under pressure in an inert atmosphere at a temperature of from -15 to -50 ° C, and dividing the resulting microspheres into fractions. A suspension intended for administration by parenteral injection contains an effective amount of said microspheres distributed in a pharmaceutically acceptable liquid vector, the pharmaceutically active substance of the microsphere being insoluble in said liquid medium.

The disadvantages of the proposed method: the complexity and duration of the process, the use of special equipment.

In US Pat. 2076765, IPC B01D 9/02, Russian Federation, published April 10, 1997. A method for producing dispersed particles of soluble compounds in microcapsules by crystallization from a solution is proposed, characterized in that the solution is dispersed in an inert matrix, cooled, and dispersed particles are obtained by changing the temperature.

The disadvantage of this method is the difficulty of execution: obtaining microcapsules by dispersion with subsequent change in temperature, which slows down the process.

In US Pat. 2139046, IPC A61K 9/50, A61K 49/00, A61K 51/00, Russian Federation, published 10.10.1999, a method for producing microcapsules as follows. An oil-in-water emulsion is prepared from an organic solution containing dissolved mono-, di-, triglyceride, preferably tripalmitin or tristearin, and possibly a therapeutically active substance, and an aqueous solution containing a surfactant, possibly a portion of the solvent is evaporated, a redispersing agent is added the agent and the mixture are freeze dried. The freeze-dried mixture is then redispersed in an aqueous carrier to separate the microcapsules from organic residues, and the hemispherical or spherical microcapsules are dried.

The disadvantages of the proposed method are the complexity and duration of the process of using freeze-drying, which takes a lot of time and slows down the process of obtaining microcapsules.

In the article “Development of microencapsulated and gel-like products and materials for various industries”, Russian Chemical Journal, 2001, vol. XLV, No. 5-6, p. 125-135 describes a method for producing microcapsules of drugs by gas-phase polymerization, since the authors of the article consider the method of chemical coacervation from aqueous media to be microencapsulated as unsuitable because most of them are water-soluble. The microencapsulation process using the gas-phase polymerization method using n-xylylene includes the following main stages: evaporation of the n-xylylene dimer (170 ° C), its thermal decomposition in a pyrolysis furnace (650 ° C at a residual pressure of 0.5 mm Hg), transfer of reaction products to the “cold” polymerization chamber (20 ° C, residual pressure 0.1 mm Hg), deposition and polymerization on the surface of the protected object. The polymerization chamber is made in the form of a rotating drum, the optimum speed for coating the powder is 30 rpm. The thickness of the shell is regulated by the time of coating. This method is suitable for encapsulation of any solids (with the exception of prone to intense sublimation). The resulting poly-i-xylylene highly crystalline polymer, characterized by high orientation and tight packaging, provides a conformal coating.

The disadvantages of the proposed method are the complexity and duration of the process, the use of gas phase polymerization, which makes the method inapplicable for producing microcapsules of drugs in polymers of protein nature due to denaturation of proteins at high temperatures.

In the article “Development of micro- and nanosystems for drug delivery”, Russian Chemical Journal, 2008, vol. LII, No. 1, p. 48-57, a method for producing microcapsules with incorporated proteins is presented, which does not significantly reduce their biological activity, carried out by the process of interfacial crosslinking of soluble starch or hydroxyethyl starch and bovine serum albumin (BSA) using terephthaloyl chloride. The proteinase inhibitor aprotinin, either native or with a protected active center, was microencapsulated when it was introduced into the aqueous phase. The flattened form of lyophilized particles indicates the preparation of microcapsules or particles of a reservoir type. Thus prepared microcapsules were not damaged after lyophilization and easily restored their spherical shape after rehydration in a buffer medium. The pH of the aqueous phase was decisive in the preparation of durable microcapsules in high yield.

The disadvantage of the proposed method for producing microcapsules is the complexity of the process, and hence the floating output of the target capsules.

In US Pat. 2359662 IPC A61K 009/56, A61J 003/07, B01J 013/02, A23L 001/00, published June 27, 2009. The Russian Federation proposes a method for producing microcapsules using spray cooling in a Niro spray cooling tower under the following conditions: inlet air temperature 10 ° C, outlet air temperature 28 ° C, spray drum rotation speed 10,000 rpm. The microcapsules of the invention have improved stability and provide controlled and / or prolonged release of the active ingredient.

The disadvantages of the proposed method are the duration of the process and the use of special equipment, a set of certain conditions (air temperature at the inlet 10 ° C, air temperature at the outlet 28 ° C, rotation speed of the spray drum 10,000 rpm).

In US Pat. WO / 2010/076360 ES, IPC B01J 13/00; A61K 9/14; A61K 9/10; A61K 9/12, published July 8, 2010. A new method is proposed for producing solid micro- and nanoparticles with a homogeneous structure with a particle size of less than 10 μm, where the treated solid compounds have a natural crystalline, amorphous, polymorphic and other states associated with the starting compound. The method allows one to obtain solid micro- and nanoparticles with substantially spheroidal morphology.

The disadvantage of the proposed method is the complexity and duration of the process.

In US Pat. WO / 2010/119041 EP IPC A23L 1/00 published October 21, 2010 provides a method for producing beads containing an active component encapsulated in a gel matrix of whey protein, including denatured protein, serum and active components. The invention relates to a method for producing beads that contain components such as probiotic bacteria. A method for producing microspheres includes the stage of production of microspheres in accordance with the method of the invention and the subsequent curing of the microspheres in a solution of an anionic polysaccharide with a pH of 4.6 or lower for at least 10, 30, 60, 90, 120, 180 minutes. Examples of suitable anionic polysaccharides: pectins, alginates, carrageenans. Ideally, whey protein is heat denaturing, although other denaturation methods are also applicable, for example, pressure-induced denaturation. In a preferred embodiment, the whey protein is denatured at a temperature of from 75 ° C to 80 ° C, appropriately for from 30 minutes to 50 minutes. As a rule, whey protein is mixed with heat denaturation. Accordingly, the concentration of whey protein is from 5 to 15%, preferably from 7 to 12%, and ideally from 9 to 11% (weight / volume). As a rule, the product is subject to filtration, which is carried out through many filters with a gradual decrease in pore size. Ideally, a fine filter has submicron pore sizes, for example from 0.1 to 0.9 microns. A preferred method for producing beads is a method using vibratory encapsulators (Inotech, Switzerland) and machines manufactured by Nisco Engineering AG ,. As a rule, nozzles have openings of 100 and 600 microns, and ideally about 150 microns.

The disadvantage of the proposed method is the use of centrifugation to separate from the process fluid, the duration of the process, as well as the use of this method not in the pharmaceutical industry.

In US Pat. 20110223314, IPC B05D 7/00 20060101, B05D 007/00, B05C 3/02 20060101, B05C 003/02; B05C 11/00 20060101, B05C 011/00; B05D 1/18 20060101, B05D 001/18; B05D 3/02 20060101, B05D 003/02; B05D 3/06 20060101, B05D 003/06 dated 03/10/2011 US describes a method for producing microcapsules by suspension polymerization, which belongs to the group of chemical methods using a new device and ultraviolet radiation.

The disadvantage of this method is the complexity and duration of the process, the use of special equipment, the use of ultraviolet radiation.

In US Pat. WO / 2011/150138 US, IPC C11D 3/37; B01J 13/08; C11D 17/00, published December 1, 2011 describes a method for producing microcapsules of solid water-soluble agents by polymerization.

The disadvantages of this method are the complexity of execution and the duration of the process.

In US Pat. WO / 2011/160733 EP, IPC B01J 13/16, published December 29, 2011 describes a method for producing microcapsules that contain shells and cores of water-insoluble materials. An aqueous solution of a protective colloid and a solution of a mixture of at least two structurally different bifunctional diisocyanates (A) and (B) insoluble in water are collected together until an emulsion is formed, then added to a mixture of bifunctional amines and heated to a temperature of at least 60 ° C until microcapsules are formed.

The disadvantages of the proposed method are the complexity, duration of the process, the use as shells of microcapsules of polymers of synthetic origin and their mixtures.

The closest method is the method proposed in US Pat. 2134967 IPC A01N 53/00, A01N 25/28 published on 08.27.1999 Russian Federation (1999). A solution of a mixture of natural lipids and a pyrethroid insecticide in a weight ratio of 2-4: 1 in an organic solvent is dispersed in water, which simplifies the microencapsulation method.

The disadvantage of this method is dispersion in an aqueous medium, which makes the proposed method inapplicable for producing microcapsules of water-soluble preparations in water-soluble polymers.

The technical task is to simplify and accelerate the process of obtaining metronidazole nanocapsules in sodium alginate, to reduce losses in the production of nanocapsules (increase in mass yield).

The solution of the technical problem is achieved by the method of producing nanocapsules of metronidazole, characterized in that sodium alginate is used as the shell of the nanocapsules, as well as the preparation of nanocapsules by the physicochemical method of precipitation with a non-solvent using a precipitant, acetone.

A distinctive feature of the proposed method is the use of metronidazole sodium alginate as a nanocapsule shell, as well as the preparation of nanocapsules by a physicochemical precipitation method with a non-solvent using a precipitant, acetone.

The result of the proposed method is the preparation of metronidazole nanocapsules in sodium alginate at 25 ° C for 15 minutes. The yield of nanocapsules is 100%.

Figure 1 shows the particle size distribution in the sample of metronidazole nanocapsules in sodium alginate (core: shell ratio 1: 1).

EXAMPLE 1. Obtaining nanocapsules of metronidazole in sodium alginate, the ratio of core: shell 1: 3

To a suspension of 1.5 g of sodium alginate in hexane and 0.01 g of the preparation E472 s (glycerol ester with one or two molecules of food fatty acids and one or two molecules of citric acid, moreover, citric acid, as a tribasic, can be esterified with other glycerides and as an acid, with other fatty acids. Free acid groups can be neutralized with sodium) 0.5 g of metronidazole powder is added in small portions as a surfactant. Then, 10 ml of acetone is added dropwise. The resulting suspension of nanocapsules is filtered and dried.

Received 2 g of a white powder. The yield was 100%.

EXAMPLE 2. Obtaining nanocapsules of metronidazole in sodium alginate, the ratio of core: shell 1: 1

To a suspension of 1.5 g of sodium alginate in hexane and 0.01 g of the preparation, 1.5 g of metronidazole powder is added as a surfactant. Then, 10 ml of acetone is added dropwise. The resulting suspension of nanocapsules is filtered and dried.

Received 3 g of a white powder. The yield was 100%.

EXAMPLE 3. Obtaining nanocapsules of metronidazole in sodium alginate, the ratio of the core shell 1: 5

0.3 g of metronidazole powder is added to a suspension of 1.5 g of sodium alginate in hexane and 0.01 g of the preparation as a surfactant. Then, 10 ml of acetone is added dropwise. The resulting suspension of nanocapsules is filtered and dried.

Received 1.8 g of a white powder. The yield was 100%.

EXAMPLE 4. Obtaining nanocapsules of metronidazole in sodium alginate, the ratio of the core: shell 5: 1

2.5 g of metronidazole powder is added to a suspension of 0.5 g of sodium alginate in hexane and 0.01 g of the preparation E472 c as a surfactant. Then 5 ml of acetone is added dropwise. The resulting suspension of nanocapsules is filtered and dried.

Received 3 g of a white powder. The yield was 100%.

EXAMPLE 5. Determination of the size of nanocapsules by the NTA method.

The measurements were carried out on a Nanosight LM0 multiparameter nanoparticle analyzer manufactured by Nanosight Ltd (Great Britain) in the HS-BF configuration (Andor Luca high-sensitivity video camera, 405 nm semiconductor laser with a power of 45 mW).

The device is based on the method of analysis of trajectories of nanoparticles (Nanoparticle Tracking Analysis, NTA) described by bASTM E2834.

The optimal dilution for dilution was 1: 100. For the measurement, the device parameters were selected: Camera Level = 16, Detection Threshold = 10 (multi), Min Track Length: Auto, Min Expected Size: Auto. The duration of a single measurement is 215s, the use of a syringe pump.

Metronidazole (lat. Metronidazolum, active ingredient: 1- (b-hydroxyethyl) -2-methyl-5-nitroimidazole), an antiprotozoal and antimicrobial drug. Metronidazole is on the list of vital and essential drugs.

Claims (1)

A method of producing metronidazole nanocapsules in sodium alginate, characterized in that metronidazole powder is added to a suspension of sodium alginate in hexane and 0.01 g of E472c, then acetone is added, the resulting suspension of nanocapsules is filtered and dried, while the mass ratio of the core: shell in nanocapsules is 1: 3, 1: 1, 1: 5 or 5: 1.

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