RU2686064C1 - Method of producing nanocapsules of dry extract of sweet vetch - Google Patents

Abstract

FIELD: medicine; food industry.SUBSTANCE: invention relates to nanotechnology, medicine, and food industry. Distinctive feature of the proposed method is using as a nucleus of a dry extract of a sweet vetch and a shell of nano capsules of kappa-carrageenan, as well as use of precipitant - 1,2-dichloroethane when producing nanocapsules by physical-chemical non-solvent deposition method.EFFECT: technical task of invention is to simplify and accelerate process of production of nanocapsules and increase mass output.1 cl, 3 ex

Description

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

Previously known methods for producing microcapsules.

Russian Federation published 09.09.2001 In patent No. 17314040 IPC А61К009 / 50, А61К 009/127 a method was proposed for producing organosiliconolipid microcapsules using a rotor-cavitation unit with high shear forces and powerful sonar phenomena of the sound and ultrasonic range for dispersion.

The disadvantage of this method is the use of special equipment - rotary-cavitation installation, which has an ultrasonic effect, which affects the formation of microcapsules and can cause side reactions due to the fact that ultrasound has a destructive effect on protein-type polymers, therefore, the proposed method is applicable to work with polymers of synthetic origin

In pat. 2359662 IPC А61К009 / 56, A61J003 / 07, B01J013 / 02, A23L001 / 00 published on 06/27/2009 The Russian Federation proposed a method for producing sodium chloride microcapsules using spray cooling in a Niro spray cooling tower under the following conditions: 10 ° C air inlet temperature air outlet 28 ° C, the speed of rotation of the spray drum 10,000 rpm / min. 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 (inlet air temperature 10 ° C, air outlet temperature 28 ° C, the speed of rotation of the spray drum 10,000 rpm).

The closest method is the method proposed in Pat.2134967 IPC A01N53 / 00, A01N25 / 28 published 08.27.1999 Russian Federation (1999). A solution of a mixture of natural lipids and a pyrethroid insecticide is dispersed in water in a 2-4: 1 weight ratio in an organic solvent, which leads to a simplification of the method of microencapsulation.

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

The technical task is to simplify and accelerate the process of obtaining nanocapsules, reducing losses when obtaining nanocapsules (increase in mass yield).

The solution of the technical problem is achieved by the method of obtaining nanocapsules, characterized in that kappa-carrageenan is used as a shell of nanocapsules, and dry kopeck extract is used as a core, upon receipt of nanocapsules by a non-solvent precipitation method using 1,2-dichloroethane as a precipitant.

A distinctive feature of the proposed method is the production of nanocapsules by the non-solvent deposition method using 1,2-dichloroethane as a precipitant, as well as the use of kappa-carrageenan as a shell of particles and dry extract of kopechnik as a core.

The result of the proposed method is to obtain nanocapsules of dry kopeck extract.

EXAMPLE 1 Obtaining nanocapsules of dry kopeck extract, core ratio 1: 3

1 g of dry kopeck extract is added to a suspension of 3 g of kappa-carrageenan in butanol in the presence of 0.01 g of E472 s (ester of glycerol with one or two edible fatty acid molecules and one or two citric acid molecules, and citric acid as , can be esterified with other glycerides and as oxoacid with other fatty acids. Free acid groups can be neutralized by sodium) as a surfactant with stirring at 700 rpm. Next, pour 7 ml of 1,2-dichloroethane. The resulting suspension is filtered and dried at room temperature.

Received 4 g of powder nanocapsules. The yield was 100%.

EXAMPLE 2 Obtaining nanocapsules of dry kopeck extract, core: shell ratio 1: 1

1 g of dry kopeck extract is added to a suspension of 1 kappa-carrageenan in butanol in the presence of 0.01 g of E472 s preparation as a surfactant with stirring at 700 rpm. Next, pour 7 ml of 1,2-dichloroethane. The resulting suspension is filtered and dried at room temperature.

Received 2 g of powder nanocapsules. The yield was 100%.

Example 3 Preparation of nanocapsules of dry kopeck extract, core: shell ratio 1: 2

1 g of dry kopeck extract is added to a suspension of 2 g of kappa-carrageenan in butanol in the presence of 0.01 g of E472 s preparation as a surfactant with stirring at 700 rpm. Next, pour 7 ml of 1,2-dichloroethane. The resulting suspension is filtered and dried at room temperature.

Received 3 g of powder nanocapsules. The yield was 100%.

Claims (1)

A method for producing dry capsid nanocapsules, characterized by the fact that dry extract of burdock is added to a suspension of kappa-carrageenan in butanol in the presence of 0.01 g of glycerol ester with one or two edible fatty acid molecules and one or two citric acid molecules as surface the active substance with stirring 700 rpm, then 1,2-dichloroethane is poured, the resulting nanocapsule suspension is filtered and dried at room temperature, while the mass ratio core: shell is 1: 1, 1: 2 or 1: 3.